/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * sunpm.c builds sunpm.o "power management framework" * kernel-resident power management code. Implements power management * policy * Assumes: all backwards compat. device components wake up on & * the pm_info pointer in dev_info is initially NULL * * PM - (device) Power Management * * Each device may have 0 or more components. If a device has no components, * then it can't be power managed. Each component has 2 or more * power states. * * "Backwards Compatible" (bc) devices: * There are two different types of devices from the point of view of this * code. The original type, left over from the original PM implementation on * the voyager platform are known in this code as "backwards compatible" * devices (PM_ISBC(dip) returns true). * They are recognized by the pm code by the lack of a pm-components property * and a call made by the driver to pm_create_components(9F). * For these devices, component 0 is special, and represents the power state * of the device. If component 0 is to be set to power level 0 (off), then * the framework must first call into the driver's detach(9E) routine with * DDI_PM_SUSPEND, to get the driver to save the hardware state of the device. * After setting component 0 from 0 to a non-zero power level, a call must be * made into the driver's attach(9E) routine with DDI_PM_RESUME. * * Currently, the only way to get a bc device power managed is via a set of * ioctls (PM_DIRECT_PM, PM_SET_CURRENT_POWER) issued to /dev/pm. * * For non-bc devices, the driver describes the components by exporting a * pm-components(9P) property that tells how many components there are, * tells what each component's power state values are, and provides human * readable strings (currently unused) for each component name and power state. * Devices which export pm-components(9P) are automatically power managed * whenever autopm is enabled (via PM_START_PM ioctl issued by pmconfig(1M) * after parsing power.conf(4)). The exception to this rule is that power * manageable CPU devices may be automatically managed independently of autopm * by either enabling or disabling (via PM_START_CPUPM and PM_STOP_CPUPM * ioctls) cpupm. If the CPU devices are not managed independently, then they * are managed by autopm. In either case, for automatically power managed * devices, all components are considered independent of each other, and it is * up to the driver to decide when a transition requires saving or restoring * hardware state. * * Each device component also has a threshold time associated with each power * transition (see power.conf(4)), and a busy/idle state maintained by the * driver calling pm_idle_component(9F) and pm_busy_component(9F). * Components are created idle. * * The PM framework provides several functions: * -implement PM policy as described in power.conf(4) * Policy is set by pmconfig(1M) issuing pm ioctls based on power.conf(4). * Policies consist of: * -set threshold values (defaults if none provided by pmconfig) * -set dependencies among devices * -enable/disable autopm * -enable/disable cpupm * -turn down idle components based on thresholds (if autopm or cpupm is * enabled) (aka scanning) * -maintain power states based on dependencies among devices * -upon request, or when the frame buffer powers off, attempt to turn off * all components that are idle or become idle over the next (10 sec) * period in an attempt to get down to an EnergyStar compliant state * -prevent powering off of a device which exported the * pm-no-involuntary-power-cycles property without active involvement of * the device's driver (so no removing power when the device driver is * not attached) * -provide a mechanism for a device driver to request that a device's component * be brought back to the power level necessary for the use of the device * -allow a process to directly control the power levels of device components * (via ioctls issued to /dev/pm--see usr/src/uts/common/io/pm.c) * -ensure that the console frame buffer is powered up before being referenced * via prom_printf() or other prom calls that might generate console output * -maintain implicit dependencies (e.g. parent must be powered up if child is) * -provide "backwards compatible" behavior for devices without pm-components * property * * Scanning: * Whenever autopm or cpupm is enabled, the framework attempts to bring each * component of each managed device to its lowest power based on the threshold * of idleness associated with each transition and the busy/idle state of the * component. * * The actual work of this is done by pm_scan_dev(), which cycles through each * component of a device, checking its idleness against its current threshold, * and calling pm_set_power() as appropriate to change the power level. * This function also indicates when it would next be profitable to scan the * device again, and a new scan is scheduled after that time. * * Dependencies: * It is possible to establish a dependency between the power states of two * otherwise unrelated devices. This is currently done to ensure that the * cdrom is always up whenever the console framebuffer is up, so that the user * can insert a cdrom and see a popup as a result. * * The dependency terminology used in power.conf(4) is not easy to understand, * so we've adopted a different terminology in the implementation. We write * of a "keeps up" and a "kept up" device. A relationship can be established * where one device keeps up another. That means that if the keepsup device * has any component that is at a non-zero power level, all components of the * "kept up" device must be brought to full power. This relationship is * asynchronous. When the keeping device is powered up, a request is queued * to a worker thread to bring up the kept device. The caller does not wait. * Scan will not turn down a kept up device. * * Direct PM: * A device may be directly power managed by a process. If a device is * directly pm'd, then it will not be scanned, and dependencies will not be * enforced. * If a directly pm'd device's driver requests a power change (via * pm_raise_power(9F)), then the request is blocked and notification is sent * to the controlling process, which must issue the requested power change for * the driver to proceed. * */ #include #include #include /* callback registration during CPR */ #include /* driver flags and functions */ #include /* OTYP_CHR definition */ #include /* S_IFCHR definition */ #include /* name -> dev_info xlation */ #include /* dev_info node fields */ #include /* memory alloc stuff */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * PM LOCKING * The list of locks: * Global pm mutex locks. * * pm_scan_lock: * It protects the timeout id of the scan thread, and the value * of autopm_enabled and cpupm. This lock is not held * concurrently with any other PM locks. * * pm_clone_lock: Protects the clone list and count of poll events * pending for the pm driver. * Lock ordering: * pm_clone_lock -> pm_pscc_interest_rwlock, * pm_clone_lock -> pm_pscc_direct_rwlock. * * pm_rsvp_lock: * Used to synchronize the data structures used for processes * to rendezvous with state change information when doing * direct PM. * Lock ordering: * pm_rsvp_lock -> pm_pscc_interest_rwlock, * pm_rsvp_lock -> pm_pscc_direct_rwlock, * pm_rsvp_lock -> pm_clone_lock. * * ppm_lock: protects the list of registered ppm drivers * Lock ordering: * ppm_lock -> ppm driver unit_lock * * pm_compcnt_lock: * Protects count of components that are not at their lowest * power level. * Lock ordering: * pm_compcnt_lock -> ppm_lock. * * pm_dep_thread_lock: * Protects work list for pm_dep_thread. Not taken concurrently * with any other pm lock. * * pm_remdrv_lock: * Serializes the operation of removing noinvol data structure * entries for a branch of the tree when a driver has been * removed from the system (modctl_rem_major). * Lock ordering: * pm_remdrv_lock -> pm_noinvol_rwlock. * * pm_cfb_lock: (High level spin lock) * Protects the count of how many components of the console * frame buffer are off (so we know if we have to bring up the * console as a result of a prom_printf, etc. * No other locks are taken while holding this lock. * * pm_loan_lock: * Protects the lock_loan list. List is used to record that one * thread has acquired a power lock but has launched another thread * to complete its processing. An entry in the list indicates that * the worker thread can borrow the lock held by the other thread, * which must block on the completion of the worker. Use is * specific to module loading. * No other locks are taken while holding this lock. * * Global PM rwlocks * * pm_thresh_rwlock: * Protects the list of thresholds recorded for future use (when * devices attach). * Lock ordering: * pm_thresh_rwlock -> devi_pm_lock * * pm_noinvol_rwlock: * Protects list of detached nodes that had noinvol registered. * No other PM locks are taken while holding pm_noinvol_rwlock. * * pm_pscc_direct_rwlock: * Protects the list that maps devices being directly power * managed to the processes that manage them. * Lock ordering: * pm_pscc_direct_rwlock -> psce_lock * * pm_pscc_interest_rwlock; * Protects the list that maps state change events to processes * that want to know about them. * Lock ordering: * pm_pscc_interest_rwlock -> psce_lock * * per-dip locks: * * Each node has these per-dip locks, which are only used if the device is * a candidate for power management (e.g. has pm components) * * devi_pm_lock: * Protects all power management state of the node except for * power level, which is protected by ndi_devi_enter(). * Encapsulated in macros PM_LOCK_DIP()/PM_UNLOCK_DIP(). * Lock ordering: * devi_pm_lock -> pm_rsvp_lock, * devi_pm_lock -> pm_dep_thread_lock, * devi_pm_lock -> pm_noinvol_rwlock, * devi_pm_lock -> power lock * * power lock (ndi_devi_enter()): * Since changing power level is possibly a slow operation (30 * seconds to spin up a disk drive), this is locked separately. * Since a call into the driver to change the power level of one * component may result in a call back into the framework to change * the power level of another, this lock allows re-entrancy by * the same thread (ndi_devi_enter is used for this because * the USB framework uses ndi_devi_enter in its power entry point, * and use of any other lock would produce a deadlock. * * devi_pm_busy_lock: * This lock protects the integrity of the busy count. It is * only taken by pm_busy_component() and pm_idle_component and * some code that adjust the busy time after the timer gets set * up or after a CPR operation. It is per-dip to keep from * single-threading all the disk drivers on a system. * It could be per component instead, but most devices have * only one component. * No other PM locks are taken while holding this lock. * */ static int stdout_is_framebuffer; static kmutex_t e_pm_power_lock; static kmutex_t pm_loan_lock; kmutex_t pm_scan_lock; callb_id_t pm_cpr_cb_id; callb_id_t pm_panic_cb_id; callb_id_t pm_halt_cb_id; int pm_comps_notlowest; /* no. of comps not at lowest power */ int pm_powering_down; /* cpr is source of DDI_SUSPEND calls */ clock_t pm_min_scan = PM_MIN_SCAN; clock_t pm_id_ticks = 5; /* ticks to wait before scan during idle-down */ static int pm_busop_set_power(dev_info_t *, void *, pm_bus_power_op_t, void *, void *); static int pm_busop_match_request(dev_info_t *, void *); static int pm_all_to_normal_nexus(dev_info_t *, pm_canblock_t); /* * Dependency Processing is done thru a seperate thread. */ kmutex_t pm_dep_thread_lock; kcondvar_t pm_dep_thread_cv; pm_dep_wk_t *pm_dep_thread_workq = NULL; pm_dep_wk_t *pm_dep_thread_tail = NULL; /* * Autopm must be turned on by a PM_START_PM ioctl, so we don't end up * power managing things in single user mode that have been suppressed via * power.conf entries. Protected by pm_scan_lock. */ int autopm_enabled; /* * cpupm is turned on and off, by the PM_START_CPUPM and PM_STOP_CPUPM ioctls, * to define the power management behavior of CPU devices separate from * autopm. Protected by pm_scan_lock. */ pm_cpupm_t cpupm = PM_CPUPM_NOTSET; /* * This flag is true while processes are stopped for a checkpoint/resume. * Controlling processes of direct pm'd devices are not available to * participate in power level changes, so we bypass them when this is set. */ static int pm_processes_stopped; #ifdef DEBUG /* * see common/sys/epm.h for PMD_* values */ uint_t pm_debug = 0; /* * If pm_divertdebug is set, then no prom_printf calls will be made by * PMD(), which will prevent debug output from bringing up the console * frame buffer. Clearing this variable before setting pm_debug will result * in PMD output going to the console. * * pm_divertdebug is incremented in pm_set_power() if dip == cfb_dip to avoid * deadlocks and decremented at the end of pm_set_power() */ uint_t pm_divertdebug = 1; kmutex_t pm_debug_lock; /* protects pm_divertdebug */ void prdeps(char *); #endif /* Globals */ /* * List of recorded thresholds and dependencies */ pm_thresh_rec_t *pm_thresh_head; krwlock_t pm_thresh_rwlock; pm_pdr_t *pm_dep_head; static int pm_unresolved_deps = 0; static int pm_prop_deps = 0; /* * List of devices that exported no-involuntary-power-cycles property */ pm_noinvol_t *pm_noinvol_head; /* * Locks used in noinvol processing */ krwlock_t pm_noinvol_rwlock; kmutex_t pm_remdrv_lock; int pm_default_idle_threshold = PM_DEFAULT_SYS_IDLENESS; int pm_system_idle_threshold; int pm_cpu_idle_threshold; /* * By default nexus has 0 threshold, and depends on its children to keep it up */ int pm_default_nexus_threshold = 0; /* * Data structures shared with common/io/pm.c */ kmutex_t pm_clone_lock; kcondvar_t pm_clones_cv[PM_MAX_CLONE]; uint_t pm_poll_cnt[PM_MAX_CLONE]; /* count of events for poll */ unsigned char pm_interest[PM_MAX_CLONE]; struct pollhead pm_pollhead; extern int hz; extern char *platform_module_list[]; /* * Wrappers for use in ddi_walk_devs */ static int pm_set_dev_thr_walk(dev_info_t *, void *); static int pm_restore_direct_lvl_walk(dev_info_t *, void *); static int pm_save_direct_lvl_walk(dev_info_t *, void *); static int pm_discard_dep_walk(dev_info_t *, void *); #ifdef DEBUG static int pm_desc_pwrchk_walk(dev_info_t *, void *); #endif /* * Routines for managing noinvol devices */ int pm_noinvol_update(int, int, int, char *, dev_info_t *); void pm_noinvol_update_node(dev_info_t *, pm_bp_noinvol_t *req); kmutex_t pm_rsvp_lock; kmutex_t pm_compcnt_lock; krwlock_t pm_pscc_direct_rwlock; krwlock_t pm_pscc_interest_rwlock; #define PSC_INTEREST 0 /* belongs to interest psc list */ #define PSC_DIRECT 1 /* belongs to direct psc list */ pscc_t *pm_pscc_interest; pscc_t *pm_pscc_direct; #define PM_MAJOR(dip) ddi_name_to_major(ddi_binding_name(dip)) #define PM_IS_NEXUS(dip) NEXUS_DRV(devopsp[PM_MAJOR(dip)]) #define POWERING_ON(old, new) ((old) == 0 && (new) != 0) #define POWERING_OFF(old, new) ((old) != 0 && (new) == 0) #define PPM(dip) ((dev_info_t *)DEVI(dip)->devi_pm_ppm) #define PM_INCR_NOTLOWEST(dip) { \ mutex_enter(&pm_compcnt_lock); \ if (!PM_IS_NEXUS(dip) || \ (DEVI(dip)->devi_pm_flags & (PMC_DEV_THRESH|PMC_COMP_THRESH))) {\ if (pm_comps_notlowest == 0) \ pm_ppm_notify_all_lowest(dip, PM_NOT_ALL_LOWEST);\ pm_comps_notlowest++; \ PMD(PMD_LEVEL, ("%s: %s@%s(%s#%d) incr notlowest->%d\n",\ pmf, PM_DEVICE(dip), pm_comps_notlowest)) \ } \ mutex_exit(&pm_compcnt_lock); \ } #define PM_DECR_NOTLOWEST(dip) { \ mutex_enter(&pm_compcnt_lock); \ if (!PM_IS_NEXUS(dip) || \ (DEVI(dip)->devi_pm_flags & (PMC_DEV_THRESH|PMC_COMP_THRESH))) {\ ASSERT(pm_comps_notlowest); \ pm_comps_notlowest--; \ PMD(PMD_LEVEL, ("%s: %s@%s(%s#%d) decr notlowest to " \ "%d\n", pmf, PM_DEVICE(dip), pm_comps_notlowest))\ if (pm_comps_notlowest == 0) \ pm_ppm_notify_all_lowest(dip, PM_ALL_LOWEST); \ } \ mutex_exit(&pm_compcnt_lock); \ } /* * console frame-buffer power-management is not enabled when * debugging services are present. to override, set pm_cfb_override * to non-zero. */ uint_t pm_cfb_comps_off = 0; /* PM_LEVEL_UNKNOWN is considered on */ kmutex_t pm_cfb_lock; int pm_cfb_enabled = 1; /* non-zero allows pm of console frame buffer */ #ifdef DEBUG int pm_cfb_override = 1; /* non-zero allows pm of cfb with debuggers */ #else int pm_cfb_override = 0; /* non-zero allows pm of cfb with debuggers */ #endif static dev_info_t *cfb_dip = 0; static dev_info_t *cfb_dip_detaching = 0; uint_t cfb_inuse = 0; static ddi_softintr_t pm_soft_id; static clock_t pm_soft_pending; int pm_scans_disabled = 0; /* * A structure to record the fact that one thread has borrowed a lock held * by another thread. The context requires that the lender block on the * completion of the borrower. */ typedef struct lock_loan { struct lock_loan *pmlk_next; kthread_t *pmlk_borrower; kthread_t *pmlk_lender; dev_info_t *pmlk_dip; } lock_loan_t; static lock_loan_t lock_loan_head; /* list head is a dummy element */ #ifdef DEBUG #define PMD_FUNC(func, name) char *(func) = (name); #else #define PMD_FUNC(func, name) #endif /* * Must be called before first device (including pseudo) attach */ void pm_init_locks(void) { mutex_init(&pm_scan_lock, NULL, MUTEX_DRIVER, NULL); mutex_init(&pm_rsvp_lock, NULL, MUTEX_DRIVER, NULL); mutex_init(&pm_compcnt_lock, NULL, MUTEX_DRIVER, NULL); mutex_init(&pm_dep_thread_lock, NULL, MUTEX_DRIVER, NULL); mutex_init(&pm_remdrv_lock, NULL, MUTEX_DRIVER, NULL); mutex_init(&pm_loan_lock, NULL, MUTEX_DRIVER, NULL); rw_init(&pm_thresh_rwlock, NULL, RW_DEFAULT, NULL); rw_init(&pm_noinvol_rwlock, NULL, RW_DEFAULT, NULL); cv_init(&pm_dep_thread_cv, NULL, CV_DEFAULT, NULL); } static boolean_t pm_cpr_callb(void *arg, int code) { _NOTE(ARGUNUSED(arg)) static int auto_save; static pm_cpupm_t cpupm_save; static int pm_reset_timestamps(dev_info_t *, void *); switch (code) { case CB_CODE_CPR_CHKPT: /* * Cancel scan or wait for scan in progress to finish * Other threads may be trying to restart the scan, so we * have to keep at it unil it sticks */ mutex_enter(&pm_scan_lock); ASSERT(!pm_scans_disabled); pm_scans_disabled = 1; auto_save = autopm_enabled; autopm_enabled = 0; cpupm_save = cpupm; cpupm = PM_CPUPM_NOTSET; mutex_exit(&pm_scan_lock); ddi_walk_devs(ddi_root_node(), pm_scan_stop_walk, NULL); break; case CB_CODE_CPR_RESUME: ASSERT(!autopm_enabled); ASSERT(cpupm == PM_CPUPM_NOTSET); ASSERT(pm_scans_disabled); pm_scans_disabled = 0; /* * Call pm_reset_timestamps to reset timestamps of each * device to the time when the system is resumed so that their * idleness can be re-calculated. That's to avoid devices from * being powered down right after resume if the system was in * suspended mode long enough. */ ddi_walk_devs(ddi_root_node(), pm_reset_timestamps, NULL); autopm_enabled = auto_save; cpupm = cpupm_save; /* * If there is any auto-pm device, get the scanning * going. Otherwise don't bother. */ ddi_walk_devs(ddi_root_node(), pm_rescan_walk, NULL); break; } return (B_TRUE); } /* * This callback routine is called when there is a system panic. This function * exists for prototype matching. */ static boolean_t pm_panic_callb(void *arg, int code) { _NOTE(ARGUNUSED(arg, code)) void pm_cfb_check_and_powerup(void); PMD(PMD_CFB, ("pm_panic_callb\n")) pm_cfb_check_and_powerup(); return (B_TRUE); } static boolean_t pm_halt_callb(void *arg, int code) { _NOTE(ARGUNUSED(arg, code)) return (B_TRUE); /* XXX for now */ } /* * This needs to be called after the root and platform drivers are loaded * and be single-threaded with respect to driver attach/detach */ void pm_init(void) { PMD_FUNC(pmf, "pm_init") char **mod; extern pri_t minclsyspri; static void pm_dep_thread(void); pm_comps_notlowest = 0; pm_system_idle_threshold = pm_default_idle_threshold; pm_cpu_idle_threshold = 0; pm_cpr_cb_id = callb_add(pm_cpr_callb, (void *)NULL, CB_CL_CPR_PM, "pm_cpr"); pm_panic_cb_id = callb_add(pm_panic_callb, (void *)NULL, CB_CL_PANIC, "pm_panic"); pm_halt_cb_id = callb_add(pm_halt_callb, (void *)NULL, CB_CL_HALT, "pm_halt"); /* * Create a thread to do dependency processing. */ (void) thread_create(NULL, 0, (void (*)())pm_dep_thread, NULL, 0, &p0, TS_RUN, minclsyspri); /* * loadrootmodules already loaded these ppm drivers, now get them * attached so they can claim the root drivers as they attach */ for (mod = platform_module_list; *mod; mod++) { if (i_ddi_attach_hw_nodes(*mod) != DDI_SUCCESS) { cmn_err(CE_WARN, "!cannot load platform pm driver %s\n", *mod); } else { PMD(PMD_DHR, ("%s: %s (%s)\n", pmf, *mod, ddi_major_to_name(ddi_name_to_major(*mod)))) } } } /* * pm_scan_init - create pm scan data structure. Called (if autopm or cpupm * enabled) when device becomes power managed or after a failed detach and * when autopm is started via PM_START_PM or PM_START_CPUPM ioctls, and after * a CPR resume to get all the devices scanning again. */ void pm_scan_init(dev_info_t *dip) { PMD_FUNC(pmf, "scan_init") pm_scan_t *scanp; ASSERT(!PM_ISBC(dip)); PM_LOCK_DIP(dip); scanp = PM_GET_PM_SCAN(dip); if (!scanp) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): create scan data\n", pmf, PM_DEVICE(dip))) scanp = kmem_zalloc(sizeof (pm_scan_t), KM_SLEEP); DEVI(dip)->devi_pm_scan = scanp; } else if (scanp->ps_scan_flags & PM_SCAN_STOP) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): " "clear PM_SCAN_STOP flag\n", pmf, PM_DEVICE(dip))) scanp->ps_scan_flags &= ~PM_SCAN_STOP; } PM_UNLOCK_DIP(dip); } /* * pm_scan_fini - remove pm scan data structure when stopping pm on the device */ void pm_scan_fini(dev_info_t *dip) { PMD_FUNC(pmf, "scan_fini") pm_scan_t *scanp; PMD(PMD_SCAN, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) ASSERT(!PM_ISBC(dip)); PM_LOCK_DIP(dip); scanp = PM_GET_PM_SCAN(dip); if (!scanp) { PM_UNLOCK_DIP(dip); return; } ASSERT(!scanp->ps_scan_id && !(scanp->ps_scan_flags & (PM_SCANNING | PM_SCAN_DISPATCHED | PM_SCAN_AGAIN))); kmem_free(scanp, sizeof (pm_scan_t)); DEVI(dip)->devi_pm_scan = NULL; PM_UNLOCK_DIP(dip); } /* * Given a pointer to a component struct, return the current power level * (struct contains index unless it is a continuous level). * Located here in hopes of getting both this and dev_is_needed into the * cache together */ static int cur_power(pm_component_t *cp) { if (cp->pmc_cur_pwr == PM_LEVEL_UNKNOWN) return (cp->pmc_cur_pwr); return (cp->pmc_comp.pmc_lvals[cp->pmc_cur_pwr]); } static char * pm_decode_direction(int direction) { switch (direction) { case PM_LEVEL_UPONLY: return ("up"); case PM_LEVEL_EXACT: return ("exact"); case PM_LEVEL_DOWNONLY: return ("down"); default: return ("INVALID DIRECTION"); } } char * pm_decode_op(pm_bus_power_op_t op) { switch (op) { case BUS_POWER_CHILD_PWRCHG: return ("CHILD_PWRCHG"); case BUS_POWER_NEXUS_PWRUP: return ("NEXUS_PWRUP"); case BUS_POWER_PRE_NOTIFICATION: return ("PRE_NOTIFICATION"); case BUS_POWER_POST_NOTIFICATION: return ("POST_NOTIFICATION"); case BUS_POWER_HAS_CHANGED: return ("HAS_CHANGED"); case BUS_POWER_NOINVOL: return ("NOINVOL"); default: return ("UNKNOWN OP"); } } /* * Returns true if level is a possible (valid) power level for component */ int e_pm_valid_power(dev_info_t *dip, int cmpt, int level) { PMD_FUNC(pmf, "e_pm_valid_power") pm_component_t *cp = PM_CP(dip, cmpt); int i; int *ip = cp->pmc_comp.pmc_lvals; int limit = cp->pmc_comp.pmc_numlevels; if (level < 0) return (0); for (i = 0; i < limit; i++) { if (level == *ip++) return (1); } #ifdef DEBUG if (pm_debug & PMD_FAIL) { ip = cp->pmc_comp.pmc_lvals; for (i = 0; i < limit; i++) PMD(PMD_FAIL, ("%s: index=%d, level=%d\n", pmf, i, *ip++)) } #endif return (0); } /* * Returns true if device is pm'd (after calling pm_start if need be) */ int e_pm_valid_info(dev_info_t *dip, pm_info_t **infop) { pm_info_t *info; static int pm_start(dev_info_t *dip); /* * Check if the device is power managed if not. * To make the common case (device is power managed already) * fast, we check without the lock. If device is not already * power managed, then we take the lock and the long route through * go get it managed. Devices never go unmanaged until they * detach. */ info = PM_GET_PM_INFO(dip); if (!info) { if (!DEVI_IS_ATTACHING(dip)) { return (0); } if (pm_start(dip) != DDI_SUCCESS) { return (0); } info = PM_GET_PM_INFO(dip); } ASSERT(info); if (infop != NULL) *infop = info; return (1); } int e_pm_valid_comp(dev_info_t *dip, int cmpt, pm_component_t **cpp) { if (cmpt >= 0 && cmpt < PM_NUMCMPTS(dip)) { if (cpp != NULL) *cpp = PM_CP(dip, cmpt); return (1); } else { return (0); } } /* * Internal guts of ddi_dev_is_needed and pm_raise/lower_power */ static int dev_is_needed(dev_info_t *dip, int cmpt, int level, int direction) { PMD_FUNC(pmf, "din") pm_component_t *cp; char *pathbuf; int result; ASSERT(direction == PM_LEVEL_UPONLY || direction == PM_LEVEL_DOWNONLY); if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, cmpt, &cp) || !e_pm_valid_power(dip, cmpt, level)) return (DDI_FAILURE); PMD(PMD_DIN, ("%s: %s@%s(%s#%d) cmpt=%d, dir=%s, new=%d, cur=%d\n", pmf, PM_DEVICE(dip), cmpt, pm_decode_direction(direction), level, cur_power(cp))) if (pm_set_power(dip, cmpt, level, direction, PM_CANBLOCK_BLOCK, 0, &result) != DDI_SUCCESS) { if (direction == PM_LEVEL_UPONLY) { pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); cmn_err(CE_WARN, "Device %s failed to power up.", pathbuf); kmem_free(pathbuf, MAXPATHLEN); } PMD(PMD_DIN | PMD_FAIL, ("%s: %s@%s(%s#%d) [%d] %s->%d failed, " "errno %d\n", pmf, PM_DEVICE(dip), cmpt, pm_decode_direction(direction), level, result)) return (DDI_FAILURE); } PMD(PMD_RESCAN | PMD_DIN, ("%s: pm_rescan %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) pm_rescan(dip); return (DDI_SUCCESS); } /* * We can get multiple pm_rescan() threads, if one of them discovers * that no scan is running at the moment, it kicks it into action. * Otherwise, it tells the current scanning thread to scan again when * it is done by asserting the PM_SCAN_AGAIN flag. The PM_SCANNING and * PM_SCAN_AGAIN flags are used to regulate scan, to make sure only one * thread at a time runs the pm_scan_dev() code. */ void pm_rescan(void *arg) { PMD_FUNC(pmf, "rescan") dev_info_t *dip = (dev_info_t *)arg; pm_info_t *info; pm_scan_t *scanp; timeout_id_t scanid; PMD(PMD_SCAN, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) PM_LOCK_DIP(dip); info = PM_GET_PM_INFO(dip); scanp = PM_GET_PM_SCAN(dip); if (pm_scans_disabled || !PM_SCANABLE(dip) || !info || !scanp || (scanp->ps_scan_flags & PM_SCAN_STOP)) { PM_UNLOCK_DIP(dip); return; } if (scanp->ps_scan_flags & PM_SCANNING) { scanp->ps_scan_flags |= PM_SCAN_AGAIN; PM_UNLOCK_DIP(dip); return; } else if (scanp->ps_scan_id) { scanid = scanp->ps_scan_id; scanp->ps_scan_id = 0; PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): cancel timeout scanid %lx\n", pmf, PM_DEVICE(dip), (ulong_t)scanid)) PM_UNLOCK_DIP(dip); (void) untimeout(scanid); PM_LOCK_DIP(dip); } /* * Dispatching pm_scan during attach time is risky due to the fact that * attach might soon fail and dip dissolved, and panic may happen while * attempting to stop scan. So schedule a pm_rescan instead. * (Note that if either of the first two terms are true, taskq_dispatch * will not be invoked). * * Multiple pm_scan dispatching is unecessary and costly to keep track * of. The PM_SCAN_DISPATCHED flag is used between pm_rescan and pm_scan * to regulate the dispatching. * * Scan is stopped before the device is detached (in pm_detaching()) * but it may get re-started during the post_detach processing if the * driver fails to detach. */ if (DEVI_IS_ATTACHING(dip) || (scanp->ps_scan_flags & PM_SCAN_DISPATCHED) || !taskq_dispatch(system_taskq, pm_scan, (void *)dip, TQ_NOSLEEP)) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): attaching, pm_scan already " "dispatched or dispatching failed\n", pmf, PM_DEVICE(dip))) if (scanp->ps_scan_id) { scanid = scanp->ps_scan_id; scanp->ps_scan_id = 0; PM_UNLOCK_DIP(dip); (void) untimeout(scanid); PM_LOCK_DIP(dip); if (scanp->ps_scan_id) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): a competing " "thread scheduled pm_rescan, scanid %lx\n", pmf, PM_DEVICE(dip), (ulong_t)scanp->ps_scan_id)) PM_UNLOCK_DIP(dip); return; } } scanp->ps_scan_id = timeout(pm_rescan, (void *)dip, (scanp->ps_idle_down ? pm_id_ticks : (pm_min_scan * hz))); PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): scheduled next pm_rescan, " "scanid %lx\n", pmf, PM_DEVICE(dip), (ulong_t)scanp->ps_scan_id)) } else { PMD(PMD_SCAN, ("%s: dispatched pm_scan for %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) scanp->ps_scan_flags |= PM_SCAN_DISPATCHED; } PM_UNLOCK_DIP(dip); } void pm_scan(void *arg) { PMD_FUNC(pmf, "scan") dev_info_t *dip = (dev_info_t *)arg; pm_scan_t *scanp; time_t nextscan; PMD(PMD_SCAN, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) PM_LOCK_DIP(dip); scanp = PM_GET_PM_SCAN(dip); ASSERT(scanp && PM_GET_PM_INFO(dip)); if (pm_scans_disabled || !PM_SCANABLE(dip) || (scanp->ps_scan_flags & PM_SCAN_STOP)) { scanp->ps_scan_flags &= ~(PM_SCAN_AGAIN | PM_SCAN_DISPATCHED); PM_UNLOCK_DIP(dip); return; } if (scanp->ps_idle_down) { /* * make sure we remember idledown was in affect until * we've completed the scan */ PMID_SET_SCANS(scanp->ps_idle_down) PMD(PMD_IDLEDOWN, ("%s: %s@%s(%s#%d): idledown starts " "(pmid %x)\n", pmf, PM_DEVICE(dip), scanp->ps_idle_down)) } /* possible having two threads running pm_scan() */ if (scanp->ps_scan_flags & PM_SCANNING) { scanp->ps_scan_flags |= PM_SCAN_AGAIN; PMD(PMD_SCAN, ("%s: scanning, will scan %s@%s(%s#%d) again\n", pmf, PM_DEVICE(dip))) scanp->ps_scan_flags &= ~PM_SCAN_DISPATCHED; PM_UNLOCK_DIP(dip); return; } scanp->ps_scan_flags |= PM_SCANNING; scanp->ps_scan_flags &= ~PM_SCAN_DISPATCHED; do { scanp->ps_scan_flags &= ~PM_SCAN_AGAIN; PM_UNLOCK_DIP(dip); nextscan = pm_scan_dev(dip); PM_LOCK_DIP(dip); } while (scanp->ps_scan_flags & PM_SCAN_AGAIN); ASSERT(scanp->ps_scan_flags & PM_SCANNING); scanp->ps_scan_flags &= ~PM_SCANNING; if (scanp->ps_idle_down) { scanp->ps_idle_down &= ~PMID_SCANS; PMD(PMD_IDLEDOWN, ("%s: %s@%s(%s#%d): idledown ends " "(pmid %x)\n", pmf, PM_DEVICE(dip), scanp->ps_idle_down)) } /* schedule for next idle check */ if (nextscan != LONG_MAX) { if (nextscan > (LONG_MAX / hz)) nextscan = (LONG_MAX - 1) / hz; if (scanp->ps_scan_id) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): while scanning " "another rescan scheduled scanid(%lx)\n", pmf, PM_DEVICE(dip), (ulong_t)scanp->ps_scan_id)) PM_UNLOCK_DIP(dip); return; } else if (!(scanp->ps_scan_flags & PM_SCAN_STOP)) { scanp->ps_scan_id = timeout(pm_rescan, (void *)dip, (clock_t)(nextscan * hz)); PMD(PMD_SCAN, ("%s: nextscan for %s@%s(%s#%d) in " "%lx sec, scanid(%lx) \n", pmf, PM_DEVICE(dip), (ulong_t)nextscan, (ulong_t)scanp->ps_scan_id)) } } PM_UNLOCK_DIP(dip); } void pm_get_timestamps(dev_info_t *dip, time_t *valuep) { int components = PM_NUMCMPTS(dip); int i; ASSERT(components > 0); PM_LOCK_BUSY(dip); /* so we get a consistent view */ for (i = 0; i < components; i++) { valuep[i] = PM_CP(dip, i)->pmc_timestamp; } PM_UNLOCK_BUSY(dip); } /* * Returns true if device needs to be kept up because it exported the * "no-involuntary-power-cycles" property or we're pretending it did (console * fb case) or it is an ancestor of such a device and has used up the "one * free cycle" allowed when all such leaf nodes have voluntarily powered down * upon detach */ int pm_noinvol(dev_info_t *dip) { PMD_FUNC(pmf, "noinvol") /* * This doesn't change over the life of a driver, so no locking needed */ if (PM_IS_CFB(dip)) { PMD(PMD_NOINVOL | PMD_CFB, ("%s: inhibits CFB %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) return (1); } /* * Not an issue if no such kids */ if (DEVI(dip)->devi_pm_noinvolpm == 0) { #ifdef DEBUG if (DEVI(dip)->devi_pm_volpmd != 0) { dev_info_t *pdip = dip; do { PMD(PMD_NOINVOL, ("%s: %s@%s(%s#%d) noinvol %d " "volpmd %d\n", pmf, PM_DEVICE(pdip), DEVI(pdip)->devi_pm_noinvolpm, DEVI(pdip)->devi_pm_volpmd)) pdip = ddi_get_parent(pdip); } while (pdip); } #endif ASSERT(DEVI(dip)->devi_pm_volpmd == 0); return (0); } /* * Since we now maintain the counts correct at every node, we no longer * need to look up the tree. An ancestor cannot use up the free cycle * without the children getting their counts adjusted. */ #ifdef DEBUG if (DEVI(dip)->devi_pm_noinvolpm != DEVI(dip)->devi_pm_volpmd) PMD(PMD_NOINVOL, ("%s: (%d != %d) inhibits %s@%s(%s#%d)\n", pmf, DEVI(dip)->devi_pm_noinvolpm, DEVI(dip)->devi_pm_volpmd, PM_DEVICE(dip))) #endif return (DEVI(dip)->devi_pm_noinvolpm != DEVI(dip)->devi_pm_volpmd); } /* * This function performs the actual scanning of the device. * It attempts to power off the indicated device's components if they have * been idle and other restrictions are met. * pm_scan_dev calculates and returns when the next scan should happen for * this device. */ time_t pm_scan_dev(dev_info_t *dip) { PMD_FUNC(pmf, "scan_dev") pm_scan_t *scanp; time_t *timestamp, idletime, now, thresh; time_t timeleft = 0; int i, nxtpwr, curpwr, pwrndx, unused; size_t size; pm_component_t *cp; dev_info_t *pdip = ddi_get_parent(dip); int circ; static int cur_threshold(dev_info_t *, int); static int pm_next_lower_power(pm_component_t *, int); /* * skip attaching device */ if (DEVI_IS_ATTACHING(dip)) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) is attaching, timeleft(%lx)\n", pmf, PM_DEVICE(dip), pm_min_scan)) return (pm_min_scan); } PM_LOCK_DIP(dip); scanp = PM_GET_PM_SCAN(dip); ASSERT(scanp && PM_GET_PM_INFO(dip)); PMD(PMD_SCAN, ("%s: [BEGIN %s@%s(%s#%d)]\n", pmf, PM_DEVICE(dip))) PMD(PMD_SCAN, ("%s: %s@%s(%s#%d): kuc is %d\n", pmf, PM_DEVICE(dip), PM_KUC(dip))) /* no scan under the following conditions */ if (pm_scans_disabled || !PM_SCANABLE(dip) || (scanp->ps_scan_flags & PM_SCAN_STOP) || (PM_KUC(dip) != 0) || PM_ISDIRECT(dip) || pm_noinvol(dip)) { PM_UNLOCK_DIP(dip); PMD(PMD_SCAN, ("%s: [END, %s@%s(%s#%d)] no scan, " "scan_disabled(%d), apm_enabled(%d), cpupm(%d), " "kuc(%d), %s directpm, %s pm_noinvol\n", pmf, PM_DEVICE(dip), pm_scans_disabled, autopm_enabled, cpupm, PM_KUC(dip), PM_ISDIRECT(dip) ? "is" : "is not", pm_noinvol(dip) ? "is" : "is not")) return (LONG_MAX); } PM_UNLOCK_DIP(dip); if (!ndi_devi_tryenter(pdip, &circ)) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) can't hold pdip", pmf, PM_DEVICE(pdip))) return ((time_t)1); } now = gethrestime_sec(); size = PM_NUMCMPTS(dip) * sizeof (time_t); timestamp = kmem_alloc(size, KM_SLEEP); pm_get_timestamps(dip, timestamp); /* * Since we removed support for backwards compatible devices, * (see big comment at top of file) * it is no longer required to deal with component 0 last. */ for (i = 0; i < PM_NUMCMPTS(dip); i++) { /* * If already off (an optimization, perhaps) */ cp = PM_CP(dip, i); pwrndx = cp->pmc_cur_pwr; curpwr = (pwrndx == PM_LEVEL_UNKNOWN) ? PM_LEVEL_UNKNOWN : cp->pmc_comp.pmc_lvals[pwrndx]; if (pwrndx == 0) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d off or " "lowest\n", pmf, PM_DEVICE(dip), i)) /* skip device if off or at its lowest */ continue; } thresh = cur_threshold(dip, i); /* comp i threshold */ if ((timestamp[i] == 0) || (cp->pmc_busycount > 0)) { /* were busy or newly became busy by another thread */ if (timeleft == 0) timeleft = max(thresh, pm_min_scan); else timeleft = min( timeleft, max(thresh, pm_min_scan)); continue; } idletime = now - timestamp[i]; /* idle time */ PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d idle time %lx\n", pmf, PM_DEVICE(dip), i, idletime)) if (idletime >= thresh || PM_IS_PID(dip)) { nxtpwr = pm_next_lower_power(cp, pwrndx); PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d, %d->%d\n", pmf, PM_DEVICE(dip), i, curpwr, nxtpwr)) if (pm_set_power(dip, i, nxtpwr, PM_LEVEL_DOWNONLY, PM_CANBLOCK_FAIL, 1, &unused) != DDI_SUCCESS && PM_CURPOWER(dip, i) != nxtpwr) { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d, " "%d->%d Failed\n", pmf, PM_DEVICE(dip), i, curpwr, nxtpwr)) timeleft = pm_min_scan; continue; } else { PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d, " "%d->%d, GOOD curpwr %d\n", pmf, PM_DEVICE(dip), i, curpwr, nxtpwr, cur_power(cp))) if (nxtpwr == 0) /* component went off */ continue; /* * scan to next lower level */ if (timeleft == 0) timeleft = max( 1, cur_threshold(dip, i)); else timeleft = min(timeleft, max(1, cur_threshold(dip, i))); PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d, " "timeleft(%lx)\n", pmf, PM_DEVICE(dip), i, timeleft)) } } else { /* comp not idle long enough */ if (timeleft == 0) timeleft = thresh - idletime; else timeleft = min(timeleft, (thresh - idletime)); PMD(PMD_SCAN, ("%s: %s@%s(%s#%d) comp %d, timeleft=" "%lx\n", pmf, PM_DEVICE(dip), i, timeleft)) } } ndi_devi_exit(pdip, circ); kmem_free(timestamp, size); PMD(PMD_SCAN, ("%s: [END %s@%s(%s#%d)] timeleft(%lx)\n", pmf, PM_DEVICE(dip), timeleft)) /* * if components are already at lowest level, timeleft is left 0 */ return ((timeleft == 0) ? LONG_MAX : timeleft); } /* * pm_scan_stop - cancel scheduled pm_rescan, * wait for termination of dispatched pm_scan thread * and active pm_scan_dev thread. */ void pm_scan_stop(dev_info_t *dip) { PMD_FUNC(pmf, "scan_stop") pm_scan_t *scanp; timeout_id_t scanid; PMD(PMD_SCAN, ("%s: [BEGIN %s@%s(%s#%d)]\n", pmf, PM_DEVICE(dip))) PM_LOCK_DIP(dip); scanp = PM_GET_PM_SCAN(dip); if (!scanp) { PMD(PMD_SCAN, ("%s: [END %s@%s(%s#%d)] scan not initialized\n", pmf, PM_DEVICE(dip))) PM_UNLOCK_DIP(dip); return; } scanp->ps_scan_flags |= PM_SCAN_STOP; /* cancel scheduled scan taskq */ while (scanp->ps_scan_id) { scanid = scanp->ps_scan_id; scanp->ps_scan_id = 0; PM_UNLOCK_DIP(dip); (void) untimeout(scanid); PM_LOCK_DIP(dip); } while (scanp->ps_scan_flags & (PM_SCANNING | PM_SCAN_DISPATCHED)) { PM_UNLOCK_DIP(dip); delay(1); PM_LOCK_DIP(dip); } PM_UNLOCK_DIP(dip); PMD(PMD_SCAN, ("%s: [END %s@%s(%s#%d)]\n", pmf, PM_DEVICE(dip))) } int pm_scan_stop_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) if (!PM_GET_PM_SCAN(dip)) return (DDI_WALK_CONTINUE); ASSERT(!PM_ISBC(dip)); pm_scan_stop(dip); return (DDI_WALK_CONTINUE); } /* * Converts a power level value to its index */ static int power_val_to_index(pm_component_t *cp, int val) { int limit, i, *ip; ASSERT(val != PM_LEVEL_UPONLY && val != PM_LEVEL_DOWNONLY && val != PM_LEVEL_EXACT); /* convert power value into index (i) */ limit = cp->pmc_comp.pmc_numlevels; ip = cp->pmc_comp.pmc_lvals; for (i = 0; i < limit; i++) if (val == *ip++) return (i); return (-1); } /* * Converts a numeric power level to a printable string */ static char * power_val_to_string(pm_component_t *cp, int val) { int index; if (val == PM_LEVEL_UPONLY) return (""); if (val == PM_LEVEL_UNKNOWN || (index = power_val_to_index(cp, val)) == -1) return (""); return (cp->pmc_comp.pmc_lnames[index]); } /* * Return true if this node has been claimed by a ppm. */ static int pm_ppm_claimed(dev_info_t *dip) { return (PPM(dip) != NULL); } /* * A node which was voluntarily power managed has just used up its "free cycle" * and need is volpmd field cleared, and the same done to all its descendents */ static void pm_clear_volpm_dip(dev_info_t *dip) { PMD_FUNC(pmf, "clear_volpm_dip") if (dip == NULL) return; PMD(PMD_NOINVOL, ("%s: clear volpm from %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) DEVI(dip)->devi_pm_volpmd = 0; for (dip = ddi_get_child(dip); dip; dip = ddi_get_next_sibling(dip)) { pm_clear_volpm_dip(dip); } } /* * A node which was voluntarily power managed has used up the "free cycles" * for the subtree that it is the root of. Scan through the list of detached * nodes and adjust the counts of any that are descendents of the node. */ static void pm_clear_volpm_list(dev_info_t *dip) { PMD_FUNC(pmf, "clear_volpm_list") char *pathbuf; size_t len; pm_noinvol_t *ip; pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); len = strlen(pathbuf); PMD(PMD_NOINVOL, ("%s: clear volpm list %s\n", pmf, pathbuf)) rw_enter(&pm_noinvol_rwlock, RW_WRITER); for (ip = pm_noinvol_head; ip; ip = ip->ni_next) { PMD(PMD_NOINVOL, ("%s: clear volpm: ni_path %s\n", pmf, ip->ni_path)) if (strncmp(pathbuf, ip->ni_path, len) == 0 && ip->ni_path[len] == '/') { PMD(PMD_NOINVOL, ("%s: clear volpm: %s\n", pmf, ip->ni_path)) ip->ni_volpmd = 0; ip->ni_wasvolpmd = 0; } } kmem_free(pathbuf, MAXPATHLEN); rw_exit(&pm_noinvol_rwlock); } /* * Powers a device, suspending or resuming the driver if it is a backward * compatible device, calling into ppm to change power level. * Called with the component's power lock held. */ static int power_dev(dev_info_t *dip, int comp, int level, int old_level, pm_canblock_t canblock, pm_ppm_devlist_t **devlist) { PMD_FUNC(pmf, "power_dev") power_req_t power_req; int power_op_ret; /* DDI_SUCCESS or DDI_FAILURE */ int resume_needed = 0; int suspended = 0; int result; struct pm_component *cp = PM_CP(dip, comp); int bc = PM_ISBC(dip); int pm_all_components_off(dev_info_t *); int clearvolpmd = 0; char pathbuf[MAXNAMELEN]; #ifdef DEBUG char *ppmname, *ppmaddr; #endif /* * If this is comp 0 of a backwards compat device and we are * going to take the power away, we need to detach it with * DDI_PM_SUSPEND command. */ if (bc && comp == 0 && POWERING_OFF(old_level, level)) { if (devi_detach(dip, DDI_PM_SUSPEND) != DDI_SUCCESS) { /* We could not suspend before turning cmpt zero off */ PMD(PMD_ERROR, ("%s: could not suspend %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) return (DDI_FAILURE); } else { DEVI(dip)->devi_pm_flags |= PMC_SUSPENDED; suspended++; } } power_req.request_type = PMR_PPM_SET_POWER; power_req.req.ppm_set_power_req.who = dip; power_req.req.ppm_set_power_req.cmpt = comp; power_req.req.ppm_set_power_req.old_level = old_level; power_req.req.ppm_set_power_req.new_level = level; power_req.req.ppm_set_power_req.canblock = canblock; power_req.req.ppm_set_power_req.cookie = NULL; #ifdef DEBUG if (pm_ppm_claimed(dip)) { ppmname = PM_NAME(PPM(dip)); ppmaddr = PM_ADDR(PPM(dip)); } else { ppmname = "noppm"; ppmaddr = "0"; } PMD(PMD_PPM, ("%s: %s@%s(%s#%d):%s[%d] %s (%d) -> %s (%d) via %s@%s\n", pmf, PM_DEVICE(dip), cp->pmc_comp.pmc_name, comp, power_val_to_string(cp, old_level), old_level, power_val_to_string(cp, level), level, ppmname, ppmaddr)) #endif /* * If non-bc noinvolpm device is turning first comp on, or noinvolpm * bc device comp 0 is powering on, then we count it as a power cycle * against its voluntary count. */ if (DEVI(dip)->devi_pm_volpmd && (!bc && pm_all_components_off(dip) && level != 0) || (bc && comp == 0 && POWERING_ON(old_level, level))) clearvolpmd = 1; if ((power_op_ret = pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result)) == DDI_SUCCESS) { /* * Now do involuntary pm accounting; If we've just cycled power * on a voluntarily pm'd node, and by inference on its entire * subtree, we need to set the subtree (including those nodes * already detached) volpmd counts to 0, and subtract out the * value of the current node's volpmd count from the ancestors */ if (clearvolpmd) { int volpmd = DEVI(dip)->devi_pm_volpmd; pm_clear_volpm_dip(dip); pm_clear_volpm_list(dip); if (volpmd) { (void) ddi_pathname(dip, pathbuf); (void) pm_noinvol_update(PM_BP_NOINVOL_POWER, volpmd, 0, pathbuf, dip); } } } else { PMD(PMD_FAIL, ("%s: can't set comp %d (%s) of %s@%s(%s#%d) " "to level %d (%s)\n", pmf, comp, cp->pmc_comp.pmc_name, PM_DEVICE(dip), level, power_val_to_string(cp, level))) } /* * If some other devices were also powered up (e.g. other cpus in * the same domain) return a pointer to that list */ if (devlist) { *devlist = (pm_ppm_devlist_t *) power_req.req.ppm_set_power_req.cookie; } /* * We will have to resume the device if the device is backwards compat * device and either of the following is true: * -This is comp 0 and we have successfully powered it up * -This is comp 0 and we have failed to power it down. Resume is * needed because we have suspended it above */ if (bc && comp == 0) { ASSERT(PM_ISDIRECT(dip) || DEVI_IS_DETACHING(dip)); if (power_op_ret == DDI_SUCCESS) { if (POWERING_ON(old_level, level)) { /* * It must be either suspended or resumed * via pm_power_has_changed path */ ASSERT((DEVI(dip)->devi_pm_flags & PMC_SUSPENDED) || (PM_CP(dip, comp)->pmc_flags & PM_PHC_WHILE_SET_POWER)); resume_needed = suspended; } } else { if (POWERING_OFF(old_level, level)) { /* * It must be either suspended or resumed * via pm_power_has_changed path */ ASSERT((DEVI(dip)->devi_pm_flags & PMC_SUSPENDED) || (PM_CP(dip, comp)->pmc_flags & PM_PHC_WHILE_SET_POWER)); resume_needed = suspended; } } } if (resume_needed) { ASSERT(DEVI(dip)->devi_pm_flags & PMC_SUSPENDED); /* ppm is not interested in DDI_PM_RESUME */ if ((power_op_ret = devi_attach(dip, DDI_PM_RESUME)) == DDI_SUCCESS) { DEVI(dip)->devi_pm_flags &= ~PMC_SUSPENDED; } else cmn_err(CE_WARN, "!pm: Can't resume %s@%s(%s#%d)", PM_DEVICE(dip)); } return (power_op_ret); } /* * Return true if we are the owner or a borrower of the devi lock. See * pm_lock_power_single() about borrowing the lock. */ static int pm_devi_lock_held(dev_info_t *dip) { lock_loan_t *cur; if (DEVI_BUSY_OWNED(dip)) return (1); /* return false if no locks borrowed */ if (lock_loan_head.pmlk_next == NULL) return (0); mutex_enter(&pm_loan_lock); /* see if our thread is registered as a lock borrower. */ for (cur = lock_loan_head.pmlk_next; cur; cur = cur->pmlk_next) if (cur->pmlk_borrower == curthread) break; mutex_exit(&pm_loan_lock); return (cur != NULL && cur->pmlk_lender == DEVI(dip)->devi_busy_thread); } /* * pm_set_power: adjusts power level of device. Assumes device is power * manageable & component exists. * * Cases which require us to bring up devices we keep up ("wekeepups") for * backwards compatible devices: * component 0 is off and we're bringing it up from 0 * bring up wekeepup first * and recursively when component 0 is off and we bring some other * component up from 0 * For devices which are not backward compatible, our dependency notion is much * simpler. Unless all components are off, then wekeeps must be on. * We don't treat component 0 differently. * Canblock tells how to deal with a direct pm'd device. * Scan arg tells us if we were called from scan, in which case we don't need * to go back to the root node and walk down to change power. */ int pm_set_power(dev_info_t *dip, int comp, int level, int direction, pm_canblock_t canblock, int scan, int *retp) { PMD_FUNC(pmf, "set_power") char *pathbuf; pm_bp_child_pwrchg_t bpc; pm_sp_misc_t pspm; int ret = DDI_SUCCESS; int unused = DDI_SUCCESS; dev_info_t *pdip = ddi_get_parent(dip); #ifdef DEBUG int diverted = 0; /* * This prevents operations on the console from calling prom_printf and * either deadlocking or bringing up the console because of debug * output */ if (dip == cfb_dip) { diverted++; mutex_enter(&pm_debug_lock); pm_divertdebug++; mutex_exit(&pm_debug_lock); } #endif ASSERT(direction == PM_LEVEL_UPONLY || direction == PM_LEVEL_DOWNONLY || direction == PM_LEVEL_EXACT); PMD(PMD_SET, ("%s: %s@%s(%s#%d), comp=%d, dir=%s, new=%d\n", pmf, PM_DEVICE(dip), comp, pm_decode_direction(direction), level)) pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); bpc.bpc_dip = dip; bpc.bpc_path = pathbuf; bpc.bpc_comp = comp; bpc.bpc_olevel = PM_CURPOWER(dip, comp); bpc.bpc_nlevel = level; pspm.pspm_direction = direction; pspm.pspm_errnop = retp; pspm.pspm_canblock = canblock; pspm.pspm_scan = scan; bpc.bpc_private = &pspm; /* * If a config operation is being done (we've locked the parent) or * we already hold the power lock (we've locked the node) * then we can operate directly on the node because we have already * brought up all the ancestors, otherwise, we have to go back to the * top of the tree. */ if (pm_devi_lock_held(pdip) || pm_devi_lock_held(dip)) ret = pm_busop_set_power(dip, NULL, BUS_POWER_CHILD_PWRCHG, (void *)&bpc, (void *)&unused); else ret = pm_busop_bus_power(ddi_root_node(), NULL, BUS_POWER_CHILD_PWRCHG, (void *)&bpc, (void *)&unused); #ifdef DEBUG if (ret != DDI_SUCCESS || *retp != DDI_SUCCESS) { PMD(PMD_ERROR, ("%s: %s@%s(%s#%d) can't change power, ret=%d, " "errno=%d\n", pmf, PM_DEVICE(dip), ret, *retp)) } if (diverted) { mutex_enter(&pm_debug_lock); pm_divertdebug--; mutex_exit(&pm_debug_lock); } #endif kmem_free(pathbuf, MAXPATHLEN); return (ret); } /* * If holddip is set, then if a dip is found we return with the node held. * * This code uses the same locking scheme as e_ddi_hold_devi_by_path * (resolve_pathname), but it does not drive attach. */ dev_info_t * pm_name_to_dip(char *pathname, int holddip) { struct pathname pn; char *component; dev_info_t *parent, *child; int circ; if ((pathname == NULL) || (*pathname != '/')) return (NULL); /* setup pathname and allocate component */ if (pn_get(pathname, UIO_SYSSPACE, &pn)) return (NULL); component = kmem_alloc(MAXNAMELEN, KM_SLEEP); /* start at top, process '/' component */ parent = child = ddi_root_node(); ndi_hold_devi(parent); pn_skipslash(&pn); ASSERT(i_ddi_devi_attached(parent)); /* process components of pathname */ while (pn_pathleft(&pn)) { (void) pn_getcomponent(&pn, component); /* enter parent and search for component child */ ndi_devi_enter(parent, &circ); child = ndi_devi_findchild(parent, component); if ((child == NULL) || !i_ddi_devi_attached(child)) { child = NULL; ndi_devi_exit(parent, circ); ndi_rele_devi(parent); goto out; } /* attached child found, hold child and release parent */ ndi_hold_devi(child); ndi_devi_exit(parent, circ); ndi_rele_devi(parent); /* child becomes parent, and process next component */ parent = child; pn_skipslash(&pn); /* loop with active ndi_devi_hold of child->parent */ } out: pn_free(&pn); kmem_free(component, MAXNAMELEN); /* if we are not asked to return with hold, drop current hold */ if (child && !holddip) ndi_rele_devi(child); return (child); } /* * Search for a dependency and mark it unsatisfied */ static void pm_unsatisfy(char *keeper, char *kept) { PMD_FUNC(pmf, "unsatisfy") pm_pdr_t *dp; PMD(PMD_KEEPS, ("%s: keeper=%s, kept=%s\n", pmf, keeper, kept)) for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (!dp->pdr_isprop) { if (strcmp(dp->pdr_keeper, keeper) == 0 && (dp->pdr_kept_count > 0) && strcmp(dp->pdr_kept_paths[0], kept) == 0) { if (dp->pdr_satisfied) { dp->pdr_satisfied = 0; pm_unresolved_deps++; PMD(PMD_KEEPS, ("%s: clear satisfied, " "pm_unresolved_deps now %d\n", pmf, pm_unresolved_deps)) } } } } } /* * Device dip is being un power managed, it keeps up count other devices. * We need to release any hold we have on the kept devices, and also * mark the dependency no longer satisfied. */ static void pm_unkeeps(int count, char *keeper, char **keptpaths, int pwr) { PMD_FUNC(pmf, "unkeeps") int i, j; dev_info_t *kept; dev_info_t *dip; struct pm_component *cp; int keeper_on = 0, circ; PMD(PMD_KEEPS, ("%s: count=%d, keeper=%s, keptpaths=%p\n", pmf, count, keeper, (void *)keptpaths)) /* * Try to grab keeper. Keeper may have gone away by now, * in this case, used the passed in value pwr */ dip = pm_name_to_dip(keeper, 1); for (i = 0; i < count; i++) { /* Release power hold */ kept = pm_name_to_dip(keptpaths[i], 1); if (kept) { PMD(PMD_KEEPS, ("%s: %s@%s(%s#%d)[%d]\n", pmf, PM_DEVICE(kept), i)) /* * We need to check if we skipped a bringup here * because we could have failed the bringup * (ie DIRECT PM device) and have * not increment the count. */ if ((dip != NULL) && (PM_GET_PM_INFO(dip) != NULL)) { keeper_on = 0; PM_LOCK_POWER(dip, &circ); for (j = 0; j < PM_NUMCMPTS(dip); j++) { cp = &DEVI(dip)->devi_pm_components[j]; if (cur_power(cp)) { keeper_on++; break; } } if (keeper_on && (PM_SKBU(kept) == 0)) { pm_rele_power(kept); DEVI(kept)->devi_pm_flags &= ~PMC_SKIP_BRINGUP; } PM_UNLOCK_POWER(dip, circ); } else if (pwr) { if (PM_SKBU(kept) == 0) { pm_rele_power(kept); DEVI(kept)->devi_pm_flags &= ~PMC_SKIP_BRINGUP; } } ddi_release_devi(kept); } /* * mark this dependency not satisfied */ pm_unsatisfy(keeper, keptpaths[i]); } if (dip) ddi_release_devi(dip); } /* * Device kept is being un power managed, it is kept up by keeper. * We need to mark the dependency no longer satisfied. */ static void pm_unkepts(char *kept, char *keeper) { PMD_FUNC(pmf, "unkepts") PMD(PMD_KEEPS, ("%s: kept=%s, keeper=%s\n", pmf, kept, keeper)) ASSERT(keeper != NULL); /* * mark this dependency not satisfied */ pm_unsatisfy(keeper, kept); } /* * Removes dependency information and hold on the kepts, if the path is a * path of a keeper. */ static void pm_free_keeper(char *path, int pwr) { pm_pdr_t *dp; int i; size_t length; for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (strcmp(dp->pdr_keeper, path) != 0) continue; /* * Remove all our kept holds and the dependency records, * then free up the kept lists. */ pm_unkeeps(dp->pdr_kept_count, path, dp->pdr_kept_paths, pwr); if (dp->pdr_kept_count) { for (i = 0; i < dp->pdr_kept_count; i++) { length = strlen(dp->pdr_kept_paths[i]); kmem_free(dp->pdr_kept_paths[i], length + 1); } kmem_free(dp->pdr_kept_paths, dp->pdr_kept_count * sizeof (char **)); dp->pdr_kept_paths = NULL; dp->pdr_kept_count = 0; } } } /* * Removes the device represented by path from the list of kepts, if the * path is a path of a kept */ static void pm_free_kept(char *path) { pm_pdr_t *dp; int i; int j, count; size_t length; char **paths; for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (dp->pdr_kept_count == 0) continue; count = dp->pdr_kept_count; /* Remove this device from the kept path lists */ for (i = 0; i < count; i++) { if (strcmp(dp->pdr_kept_paths[i], path) == 0) { pm_unkepts(path, dp->pdr_keeper); length = strlen(dp->pdr_kept_paths[i]) + 1; kmem_free(dp->pdr_kept_paths[i], length); dp->pdr_kept_paths[i] = NULL; dp->pdr_kept_count--; } } /* Compact the kept paths array */ if (dp->pdr_kept_count) { length = dp->pdr_kept_count * sizeof (char **); paths = kmem_zalloc(length, KM_SLEEP); j = 0; for (i = 0; i < count; i++) { if (dp->pdr_kept_paths[i] != NULL) { paths[j] = dp->pdr_kept_paths[i]; j++; } } ASSERT(j == dp->pdr_kept_count); } /* Now free the old array and point to the new one */ kmem_free(dp->pdr_kept_paths, count * sizeof (char **)); if (dp->pdr_kept_count) dp->pdr_kept_paths = paths; else dp->pdr_kept_paths = NULL; } } /* * Free the dependency information for a device. */ void pm_free_keeps(char *path, int pwr) { PMD_FUNC(pmf, "free_keeps") #ifdef DEBUG int doprdeps = 0; void prdeps(char *); PMD(PMD_KEEPS, ("%s: %s\n", pmf, path)) if (pm_debug & PMD_KEEPS) { doprdeps = 1; prdeps("pm_free_keeps before"); } #endif /* * First assume we are a keeper and remove all our kepts. */ pm_free_keeper(path, pwr); /* * Now assume we a kept device, and remove all our records. */ pm_free_kept(path); #ifdef DEBUG if (doprdeps) { prdeps("pm_free_keeps after"); } #endif } static int pm_is_kept(char *path) { pm_pdr_t *dp; int i; for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (dp->pdr_kept_count == 0) continue; for (i = 0; i < dp->pdr_kept_count; i++) { if (strcmp(dp->pdr_kept_paths[i], path) == 0) return (1); } } return (0); } static void e_pm_hold_rele_power(dev_info_t *dip, int cnt) { PMD_FUNC(pmf, "hold_rele_power") int circ; if ((dip == NULL) || (PM_GET_PM_INFO(dip) == NULL) || PM_ISBC(dip)) return; PM_LOCK_POWER(dip, &circ); ASSERT(cnt >= 0 && PM_KUC(dip) >= 0 || cnt < 0 && PM_KUC(dip) > 0); PMD(PMD_KIDSUP, ("%s: kidsupcnt for %s@%s(%s#%d) %d->%d\n", pmf, PM_DEVICE(dip), PM_KUC(dip), (PM_KUC(dip) + cnt))) PM_KUC(dip) += cnt; ASSERT(PM_KUC(dip) >= 0); PM_UNLOCK_POWER(dip, circ); if (cnt < 0 && PM_KUC(dip) == 0) pm_rescan(dip); } #define MAX_PPM_HANDLERS 4 kmutex_t ppm_lock; /* in case we ever do multi-threaded startup */ struct ppm_callbacks { int (*ppmc_func)(dev_info_t *); dev_info_t *ppmc_dip; } ppm_callbacks[MAX_PPM_HANDLERS + 1]; /* * This routine calls into all the registered ppms to notify them * that either all components of power-managed devices are at their * lowest levels or no longer all are at their lowest levels. */ static void pm_ppm_notify_all_lowest(dev_info_t *dip, int mode) { struct ppm_callbacks *ppmcp; power_req_t power_req; int result = 0; power_req.request_type = PMR_PPM_ALL_LOWEST; power_req.req.ppm_all_lowest_req.mode = mode; mutex_enter(&ppm_lock); for (ppmcp = ppm_callbacks; ppmcp->ppmc_func; ppmcp++) (void) pm_ctlops((dev_info_t *)ppmcp->ppmc_dip, dip, DDI_CTLOPS_POWER, &power_req, &result); mutex_exit(&ppm_lock); } static void pm_set_pm_info(dev_info_t *dip, void *value) { DEVI(dip)->devi_pm_info = value; } pm_rsvp_t *pm_blocked_list; /* * Look up an entry in the blocked list by dip and component */ static pm_rsvp_t * pm_rsvp_lookup(dev_info_t *dip, int comp) { pm_rsvp_t *p; ASSERT(MUTEX_HELD(&pm_rsvp_lock)); for (p = pm_blocked_list; p; p = p->pr_next) if (p->pr_dip == dip && p->pr_comp == comp) { return (p); } return (NULL); } /* * Called when a device which is direct power managed (or the parent or * dependent of such a device) changes power, or when a pm clone is closed * that was direct power managing a device. This call results in pm_blocked() * (below) returning. */ void pm_proceed(dev_info_t *dip, int cmd, int comp, int newlevel) { PMD_FUNC(pmf, "proceed") pm_rsvp_t *found = NULL; pm_rsvp_t *p; mutex_enter(&pm_rsvp_lock); switch (cmd) { /* * we're giving up control, let any pending op continue */ case PMP_RELEASE: for (p = pm_blocked_list; p; p = p->pr_next) { if (dip == p->pr_dip) { p->pr_retval = PMP_RELEASE; PMD(PMD_DPM, ("%s: RELEASE %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) cv_signal(&p->pr_cv); } } break; /* * process has done PM_SET_CURRENT_POWER; let a matching request * succeed and a non-matching request for the same device fail */ case PMP_SETPOWER: found = pm_rsvp_lookup(dip, comp); if (!found) /* if driver not waiting */ break; /* * This cannot be pm_lower_power, since that can only happen * during detach or probe */ if (found->pr_newlevel <= newlevel) { found->pr_retval = PMP_SUCCEED; PMD(PMD_DPM, ("%s: SUCCEED %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) } else { found->pr_retval = PMP_FAIL; PMD(PMD_DPM, ("%s: FAIL %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) } cv_signal(&found->pr_cv); break; default: panic("pm_proceed unknown cmd %d", cmd); } mutex_exit(&pm_rsvp_lock); } /* * This routine dispatches new work to the dependency thread. Caller must * be prepared to block for memory if necessary. */ void pm_dispatch_to_dep_thread(int cmd, char *keeper, char *kept, int wait, int *res, int cached_pwr) { pm_dep_wk_t *new_work; new_work = kmem_zalloc(sizeof (pm_dep_wk_t), KM_SLEEP); new_work->pdw_type = cmd; new_work->pdw_wait = wait; new_work->pdw_done = 0; new_work->pdw_ret = 0; new_work->pdw_pwr = cached_pwr; cv_init(&new_work->pdw_cv, NULL, CV_DEFAULT, NULL); if (keeper != NULL) { new_work->pdw_keeper = kmem_zalloc(strlen(keeper) + 1, KM_SLEEP); (void) strcpy(new_work->pdw_keeper, keeper); } if (kept != NULL) { new_work->pdw_kept = kmem_zalloc(strlen(kept) + 1, KM_SLEEP); (void) strcpy(new_work->pdw_kept, kept); } mutex_enter(&pm_dep_thread_lock); if (pm_dep_thread_workq == NULL) { pm_dep_thread_workq = new_work; pm_dep_thread_tail = new_work; new_work->pdw_next = NULL; } else { pm_dep_thread_tail->pdw_next = new_work; pm_dep_thread_tail = new_work; new_work->pdw_next = NULL; } cv_signal(&pm_dep_thread_cv); /* If caller asked for it, wait till it is done. */ if (wait) { while (!new_work->pdw_done) cv_wait(&new_work->pdw_cv, &pm_dep_thread_lock); /* * Pass return status, if any, back. */ if (res != NULL) *res = new_work->pdw_ret; /* * If we asked to wait, it is our job to free the request * structure. */ if (new_work->pdw_keeper) kmem_free(new_work->pdw_keeper, strlen(new_work->pdw_keeper) + 1); if (new_work->pdw_kept) kmem_free(new_work->pdw_kept, strlen(new_work->pdw_kept) + 1); kmem_free(new_work, sizeof (pm_dep_wk_t)); } mutex_exit(&pm_dep_thread_lock); } /* * Release the pm resource for this device. */ void pm_rem_info(dev_info_t *dip) { PMD_FUNC(pmf, "rem_info") int i, count = 0; pm_info_t *info = PM_GET_PM_INFO(dip); dev_info_t *pdip = ddi_get_parent(dip); char *pathbuf; int work_type = PM_DEP_WK_DETACH; ASSERT(info); ASSERT(!PM_IAM_LOCKING_DIP(dip)); if (PM_ISDIRECT(dip)) { info->pmi_dev_pm_state &= ~PM_DIRECT; ASSERT(info->pmi_clone); info->pmi_clone = 0; pm_proceed(dip, PMP_RELEASE, -1, -1); } ASSERT(!PM_GET_PM_SCAN(dip)); /* * Now adjust parent's kidsupcnt. BC nodes we check only comp 0, * Others we check all components. BC node that has already * called pm_destroy_components() has zero component count. * Parents that get notification are not adjusted because their * kidsupcnt is always 0 (or 1 during configuration). */ PMD(PMD_KEEPS, ("%s: %s@%s(%s#%d) has %d components\n", pmf, PM_DEVICE(dip), PM_NUMCMPTS(dip))) /* node is detached, so we can examine power without locking */ if (PM_ISBC(dip)) { count = (PM_CURPOWER(dip, 0) != 0); } else { for (i = 0; i < PM_NUMCMPTS(dip); i++) count += (PM_CURPOWER(dip, i) != 0); } if (PM_NUMCMPTS(dip) && pdip && !PM_WANTS_NOTIFICATION(pdip)) e_pm_hold_rele_power(pdip, -count); /* Schedule a request to clean up dependency records */ pathbuf = kmem_zalloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); pm_dispatch_to_dep_thread(work_type, pathbuf, pathbuf, PM_DEP_NOWAIT, NULL, (count > 0)); kmem_free(pathbuf, MAXPATHLEN); /* * Adjust the pm_comps_notlowest count since this device is * not being power-managed anymore. */ for (i = 0; i < PM_NUMCMPTS(dip); i++) { if (PM_CURPOWER(dip, i) != 0) PM_DECR_NOTLOWEST(dip); } /* * Once we clear the info pointer, it looks like it is not power * managed to everybody else. */ pm_set_pm_info(dip, NULL); kmem_free(info, sizeof (pm_info_t)); } int pm_get_norm_pwrs(dev_info_t *dip, int **valuep, size_t *length) { int components = PM_NUMCMPTS(dip); int *bufp; size_t size; int i; if (components <= 0) { cmn_err(CE_NOTE, "!pm: %s@%s(%s#%d) has no components, " "can't get normal power values\n", PM_DEVICE(dip)); return (DDI_FAILURE); } else { size = components * sizeof (int); bufp = kmem_alloc(size, KM_SLEEP); for (i = 0; i < components; i++) { bufp[i] = pm_get_normal_power(dip, i); } } *length = size; *valuep = bufp; return (DDI_SUCCESS); } static int pm_reset_timestamps(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) int components; int i; if (!PM_GET_PM_INFO(dip)) return (DDI_WALK_CONTINUE); components = PM_NUMCMPTS(dip); ASSERT(components > 0); PM_LOCK_BUSY(dip); for (i = 0; i < components; i++) { struct pm_component *cp; /* * If the component was not marked as busy, * reset its timestamp to now. */ cp = PM_CP(dip, i); if (cp->pmc_timestamp) cp->pmc_timestamp = gethrestime_sec(); } PM_UNLOCK_BUSY(dip); return (DDI_WALK_CONTINUE); } /* * Convert a power level to an index into the levels array (or * just PM_LEVEL_UNKNOWN in that special case). */ static int pm_level_to_index(dev_info_t *dip, pm_component_t *cp, int level) { PMD_FUNC(pmf, "level_to_index") int i; int limit = cp->pmc_comp.pmc_numlevels; int *ip = cp->pmc_comp.pmc_lvals; if (level == PM_LEVEL_UNKNOWN) return (level); for (i = 0; i < limit; i++) { if (level == *ip++) { PMD(PMD_LEVEL, ("%s: %s@%s(%s#%d)[%d] to %x\n", pmf, PM_DEVICE(dip), (int)(cp - DEVI(dip)->devi_pm_components), level)) return (i); } } panic("pm_level_to_index: level %d not found for device " "%s@%s(%s#%d)", level, PM_DEVICE(dip)); /*NOTREACHED*/ } /* * Internal function to set current power level */ static void e_pm_set_cur_pwr(dev_info_t *dip, pm_component_t *cp, int level) { PMD_FUNC(pmf, "set_cur_pwr") int curpwr = (cp->pmc_flags & PM_PHC_WHILE_SET_POWER ? cp->pmc_phc_pwr : cp->pmc_cur_pwr); /* * Nothing to adjust if current & new levels are the same. */ if (curpwr != PM_LEVEL_UNKNOWN && level == cp->pmc_comp.pmc_lvals[curpwr]) return; /* * Keep the count for comps doing transition to/from lowest * level. */ if (curpwr == 0) { PM_INCR_NOTLOWEST(dip); } else if (level == cp->pmc_comp.pmc_lvals[0]) { PM_DECR_NOTLOWEST(dip); } cp->pmc_phc_pwr = PM_LEVEL_UNKNOWN; cp->pmc_cur_pwr = pm_level_to_index(dip, cp, level); } /* * This is the default method of setting the power of a device if no ppm * driver has claimed it. */ int pm_power(dev_info_t *dip, int comp, int level) { PMD_FUNC(pmf, "power") struct dev_ops *ops; int (*fn)(dev_info_t *, int, int); struct pm_component *cp = PM_CP(dip, comp); int retval; pm_info_t *info = PM_GET_PM_INFO(dip); static int pm_phc_impl(dev_info_t *, int, int, int); PMD(PMD_KIDSUP, ("%s: %s@%s(%s#%d), comp=%d, level=%d\n", pmf, PM_DEVICE(dip), comp, level)) if (!(ops = ddi_get_driver(dip))) { PMD(PMD_FAIL, ("%s: %s@%s(%s#%d) has no ops\n", pmf, PM_DEVICE(dip))) return (DDI_FAILURE); } if ((ops->devo_rev < 2) || !(fn = ops->devo_power)) { PMD(PMD_FAIL, ("%s: %s%s\n", pmf, (ops->devo_rev < 2 ? " wrong devo_rev" : ""), (!fn ? " devo_power NULL" : ""))) return (DDI_FAILURE); } cp->pmc_flags |= PM_POWER_OP; retval = (*fn)(dip, comp, level); cp->pmc_flags &= ~PM_POWER_OP; if (retval == DDI_SUCCESS) { e_pm_set_cur_pwr(dip, PM_CP(dip, comp), level); return (DDI_SUCCESS); } /* * If pm_power_has_changed() detected a deadlock with pm_power() it * updated only the power level of the component. If our attempt to * set the device new to a power level above has failed we sync the * total power state via phc code now. */ if (cp->pmc_flags & PM_PHC_WHILE_SET_POWER) { int phc_lvl = cp->pmc_comp.pmc_lvals[cp->pmc_cur_pwr]; ASSERT(info); (void) pm_phc_impl(dip, comp, phc_lvl, 0); PMD(PMD_PHC, ("%s: phc %s@%s(%s#%d) comp=%d level=%d\n", pmf, PM_DEVICE(dip), comp, phc_lvl)) } PMD(PMD_FAIL, ("%s: can't set comp=%d (%s) of %s@%s(%s#%d) to " "level=%d (%s)\n", pmf, comp, cp->pmc_comp.pmc_name, PM_DEVICE(dip), level, power_val_to_string(cp, level))); return (DDI_FAILURE); } int pm_unmanage(dev_info_t *dip) { PMD_FUNC(pmf, "unmanage") power_req_t power_req; int result, retval = 0; ASSERT(!PM_IAM_LOCKING_DIP(dip)); PMD(PMD_REMDEV | PMD_KIDSUP, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) power_req.request_type = PMR_PPM_UNMANAGE; power_req.req.ppm_config_req.who = dip; if (pm_ppm_claimed(dip)) retval = pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); #ifdef DEBUG else retval = pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); #endif ASSERT(retval == DDI_SUCCESS); pm_rem_info(dip); return (retval); } int pm_raise_power(dev_info_t *dip, int comp, int level) { if (level < 0) return (DDI_FAILURE); if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, comp, NULL) || !e_pm_valid_power(dip, comp, level)) return (DDI_FAILURE); return (dev_is_needed(dip, comp, level, PM_LEVEL_UPONLY)); } int pm_lower_power(dev_info_t *dip, int comp, int level) { PMD_FUNC(pmf, "pm_lower_power") if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, comp, NULL) || !e_pm_valid_power(dip, comp, level)) { PMD(PMD_FAIL, ("%s: validation checks failed for %s@%s(%s#%d) " "comp=%d level=%d\n", pmf, PM_DEVICE(dip), comp, level)) return (DDI_FAILURE); } if (!DEVI_IS_DETACHING(dip)) { PMD(PMD_FAIL, ("%s: %s@%s(%s#%d) not detaching\n", pmf, PM_DEVICE(dip))) return (DDI_FAILURE); } /* * If we don't care about saving power, or we're treating this node * specially, then this is a no-op */ if (!PM_SCANABLE(dip) || pm_noinvol(dip)) { PMD(PMD_FAIL, ("%s: %s@%s(%s#%d) %s%s%s%s\n", pmf, PM_DEVICE(dip), !autopm_enabled ? "!autopm_enabled " : "", !PM_CPUPM_ENABLED ? "!cpupm_enabled " : "", PM_CPUPM_DISABLED ? "cpupm_disabled " : "", pm_noinvol(dip) ? "pm_noinvol()" : "")) return (DDI_SUCCESS); } if (dev_is_needed(dip, comp, level, PM_LEVEL_DOWNONLY) != DDI_SUCCESS) { PMD(PMD_FAIL, ("%s: %s@%s(%s#%d) dev_is_needed failed\n", pmf, PM_DEVICE(dip))) return (DDI_FAILURE); } return (DDI_SUCCESS); } /* * Find the entries struct for a given dip in the blocked list, return it locked */ static psce_t * pm_psc_dip_to_direct(dev_info_t *dip, pscc_t **psccp) { pscc_t *p; psce_t *psce; rw_enter(&pm_pscc_direct_rwlock, RW_READER); for (p = pm_pscc_direct; p; p = p->pscc_next) { if (p->pscc_dip == dip) { *psccp = p; psce = p->pscc_entries; mutex_enter(&psce->psce_lock); ASSERT(psce); rw_exit(&pm_pscc_direct_rwlock); return (psce); } } rw_exit(&pm_pscc_direct_rwlock); panic("sunpm: no entry for dip %p in direct list", (void *)dip); /*NOTREACHED*/ } /* * Write an entry indicating a power level change (to be passed to a process * later) in the given psce. * If we were called in the path that brings up the console fb in the * case of entering the prom, we don't want to sleep. If the alloc fails, then * we create a record that has a size of -1, a physaddr of NULL, and that * has the overflow flag set. */ static int psc_entry(ushort_t event, psce_t *psce, dev_info_t *dip, int comp, int new, int old, int which, pm_canblock_t canblock) { char buf[MAXNAMELEN]; pm_state_change_t *p; size_t size; caddr_t physpath = NULL; int overrun = 0; ASSERT(MUTEX_HELD(&psce->psce_lock)); (void) ddi_pathname(dip, buf); size = strlen(buf) + 1; p = psce->psce_in; if (canblock == PM_CANBLOCK_BYPASS) { physpath = kmem_alloc(size, KM_NOSLEEP); if (physpath == NULL) { /* * mark current entry as overrun */ p->flags |= PSC_EVENT_LOST; size = (size_t)-1; } } else physpath = kmem_alloc(size, KM_SLEEP); if (p->size) { /* overflow; mark the next entry */ if (p->size != (size_t)-1) kmem_free(p->physpath, p->size); ASSERT(psce->psce_out == p); if (p == psce->psce_last) { psce->psce_first->flags |= PSC_EVENT_LOST; psce->psce_out = psce->psce_first; } else { (p + 1)->flags |= PSC_EVENT_LOST; psce->psce_out = (p + 1); } overrun++; } else if (physpath == NULL) { /* alloc failed, mark this entry */ p->flags |= PSC_EVENT_LOST; p->size = 0; p->physpath = NULL; } if (which == PSC_INTEREST) { mutex_enter(&pm_compcnt_lock); if (pm_comps_notlowest == 0) p->flags |= PSC_ALL_LOWEST; else p->flags &= ~PSC_ALL_LOWEST; mutex_exit(&pm_compcnt_lock); } p->event = event; p->timestamp = gethrestime_sec(); p->component = comp; p->old_level = old; p->new_level = new; p->physpath = physpath; p->size = size; if (physpath != NULL) (void) strcpy(p->physpath, buf); if (p == psce->psce_last) psce->psce_in = psce->psce_first; else psce->psce_in = ++p; mutex_exit(&psce->psce_lock); return (overrun); } /* * Find the next entry on the interest list. We keep a pointer to the item we * last returned in the user's cooke. Returns a locked entries struct. */ static psce_t * psc_interest(void **cookie, pscc_t **psccp) { pscc_t *pscc; pscc_t **cookiep = (pscc_t **)cookie; if (*cookiep == NULL) pscc = pm_pscc_interest; else pscc = (*cookiep)->pscc_next; if (pscc) { *cookiep = pscc; *psccp = pscc; mutex_enter(&pscc->pscc_entries->psce_lock); return (pscc->pscc_entries); } else { return (NULL); } } /* * Create an entry for a process to pick up indicating a power level change. */ static void pm_enqueue_notify(ushort_t cmd, dev_info_t *dip, int comp, int newlevel, int oldlevel, pm_canblock_t canblock) { PMD_FUNC(pmf, "enqueue_notify") pscc_t *pscc; psce_t *psce; void *cookie = NULL; int overrun; ASSERT(MUTEX_HELD(&pm_rsvp_lock)); switch (cmd) { case PSC_PENDING_CHANGE: /* only for controlling process */ PMD(PMD_DPM, ("%s: PENDING %s@%s(%s#%d), comp %d, %d -> %d\n", pmf, PM_DEVICE(dip), comp, oldlevel, newlevel)) psce = pm_psc_dip_to_direct(dip, &pscc); ASSERT(psce); PMD(PMD_IOCTL, ("%s: PENDING: %s@%s(%s#%d) pm_poll_cnt[%d] " "%d\n", pmf, PM_DEVICE(dip), pscc->pscc_clone, pm_poll_cnt[pscc->pscc_clone])) overrun = psc_entry(cmd, psce, dip, comp, newlevel, oldlevel, PSC_DIRECT, canblock); PMD(PMD_DPM, ("%s: sig %d\n", pmf, pscc->pscc_clone)) mutex_enter(&pm_clone_lock); if (!overrun) pm_poll_cnt[pscc->pscc_clone]++; cv_signal(&pm_clones_cv[pscc->pscc_clone]); pollwakeup(&pm_pollhead, (POLLRDNORM | POLLIN)); mutex_exit(&pm_clone_lock); break; case PSC_HAS_CHANGED: PMD(PMD_DPM, ("%s: HAS %s@%s(%s#%d), comp %d, %d -> %d\n", pmf, PM_DEVICE(dip), comp, oldlevel, newlevel)) if (PM_ISDIRECT(dip) && canblock != PM_CANBLOCK_BYPASS) { psce = pm_psc_dip_to_direct(dip, &pscc); PMD(PMD_IOCTL, ("%s: HAS: %s@%s(%s#%d) pm_poll_cnt[%d] " "%d\n", pmf, PM_DEVICE(dip), pscc->pscc_clone, pm_poll_cnt[pscc->pscc_clone])) overrun = psc_entry(cmd, psce, dip, comp, newlevel, oldlevel, PSC_DIRECT, canblock); PMD(PMD_DPM, ("%s: sig %d\n", pmf, pscc->pscc_clone)) mutex_enter(&pm_clone_lock); if (!overrun) pm_poll_cnt[pscc->pscc_clone]++; cv_signal(&pm_clones_cv[pscc->pscc_clone]); pollwakeup(&pm_pollhead, (POLLRDNORM | POLLIN)); mutex_exit(&pm_clone_lock); } mutex_enter(&pm_clone_lock); rw_enter(&pm_pscc_interest_rwlock, RW_READER); while ((psce = psc_interest(&cookie, &pscc)) != NULL) { (void) psc_entry(cmd, psce, dip, comp, newlevel, oldlevel, PSC_INTEREST, canblock); cv_signal(&pm_clones_cv[pscc->pscc_clone]); } rw_exit(&pm_pscc_interest_rwlock); mutex_exit(&pm_clone_lock); break; #ifdef DEBUG default: ASSERT(0); #endif } } static void pm_enqueue_notify_others(pm_ppm_devlist_t **listp, pm_canblock_t canblock) { if (listp) { pm_ppm_devlist_t *p, *next = NULL; for (p = *listp; p; p = next) { next = p->ppd_next; pm_enqueue_notify(PSC_HAS_CHANGED, p->ppd_who, p->ppd_cmpt, p->ppd_new_level, p->ppd_old_level, canblock); kmem_free(p, sizeof (pm_ppm_devlist_t)); } *listp = NULL; } } /* * Try to get the power locks of the parent node and target (child) * node. Return true if successful (with both locks held) or false * (with no locks held). */ static int pm_try_parent_child_locks(dev_info_t *pdip, dev_info_t *dip, int *pcircp, int *circp) { if (ndi_devi_tryenter(pdip, pcircp)) if (PM_TRY_LOCK_POWER(dip, circp)) { return (1); } else { ndi_devi_exit(pdip, *pcircp); } return (0); } /* * Determine if the power lock owner is blocked by current thread. * returns : * 1 - If the thread owning the effective power lock (the first lock on * which a thread blocks when it does PM_LOCK_POWER) is blocked by * a mutex held by the current thread. * * 0 - otherwise * * Note : This function is called by pm_power_has_changed to determine whether * it is executing in parallel with pm_set_power. */ static int pm_blocked_by_us(dev_info_t *dip) { power_req_t power_req; kthread_t *owner; int result; kmutex_t *mp; dev_info_t *ppm = (dev_info_t *)DEVI(dip)->devi_pm_ppm; power_req.request_type = PMR_PPM_POWER_LOCK_OWNER; power_req.req.ppm_power_lock_owner_req.who = dip; if (pm_ctlops(ppm, dip, DDI_CTLOPS_POWER, &power_req, &result) != DDI_SUCCESS) { /* * It is assumed that if the device is claimed by ppm, ppm * will always implement this request type and it'll always * return success. We panic here, if it fails. */ panic("pm: Can't determine power lock owner of %s@%s(%s#%d)\n", PM_DEVICE(dip)); /*NOTREACHED*/ } if ((owner = power_req.req.ppm_power_lock_owner_req.owner) != NULL && owner->t_state == TS_SLEEP && owner->t_sobj_ops && SOBJ_TYPE(owner->t_sobj_ops) == SOBJ_MUTEX && (mp = (kmutex_t *)owner->t_wchan) && mutex_owner(mp) == curthread) return (1); return (0); } /* * Notify parent which wants to hear about a child's power changes. */ static void pm_notify_parent(dev_info_t *dip, dev_info_t *pdip, int comp, int old_level, int level) { pm_bp_has_changed_t bphc; pm_sp_misc_t pspm; char *pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); int result = DDI_SUCCESS; bphc.bphc_dip = dip; bphc.bphc_path = ddi_pathname(dip, pathbuf); bphc.bphc_comp = comp; bphc.bphc_olevel = old_level; bphc.bphc_nlevel = level; pspm.pspm_canblock = PM_CANBLOCK_BLOCK; pspm.pspm_scan = 0; bphc.bphc_private = &pspm; (void) (*PM_BUS_POWER_FUNC(pdip))(pdip, NULL, BUS_POWER_HAS_CHANGED, (void *)&bphc, (void *)&result); kmem_free(pathbuf, MAXPATHLEN); } /* * Check if we need to resume a BC device, and make the attach call as required. */ static int pm_check_and_resume(dev_info_t *dip, int comp, int old_level, int level) { int ret = DDI_SUCCESS; if (PM_ISBC(dip) && comp == 0 && old_level == 0 && level != 0) { ASSERT(DEVI(dip)->devi_pm_flags & PMC_SUSPENDED); /* ppm is not interested in DDI_PM_RESUME */ if ((ret = devi_attach(dip, DDI_PM_RESUME)) != DDI_SUCCESS) /* XXX Should we mark it resumed, */ /* even though it failed? */ cmn_err(CE_WARN, "!pm: Can't resume %s@%s", PM_NAME(dip), PM_ADDR(dip)); DEVI(dip)->devi_pm_flags &= ~PMC_SUSPENDED; } return (ret); } /* * Tests outside the lock to see if we should bother to enqueue an entry * for any watching process. If yes, then caller will take the lock and * do the full protocol */ static int pm_watchers() { if (pm_processes_stopped) return (0); return (pm_pscc_direct || pm_pscc_interest); } /* * A driver is reporting that the power of one of its device's components * has changed. Update the power state accordingly. */ int pm_power_has_changed(dev_info_t *dip, int comp, int level) { PMD_FUNC(pmf, "pm_power_has_changed") int ret; dev_info_t *pdip = ddi_get_parent(dip); struct pm_component *cp; int blocked, circ, pcirc, old_level; static int pm_phc_impl(dev_info_t *, int, int, int); if (level < 0) { PMD(PMD_FAIL, ("%s: %s@%s(%s#%d): bad level=%d\n", pmf, PM_DEVICE(dip), level)) return (DDI_FAILURE); } PMD(PMD_KIDSUP | PMD_DEP, ("%s: %s@%s(%s#%d), comp=%d, level=%d\n", pmf, PM_DEVICE(dip), comp, level)) if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, comp, &cp) || !e_pm_valid_power(dip, comp, level)) return (DDI_FAILURE); /* * A driver thread calling pm_power_has_changed and another thread * calling pm_set_power can deadlock. The problem is not resolvable * by changing lock order, so we use pm_blocked_by_us() to detect * this specific deadlock. If we can't get the lock immediately * and we are deadlocked, just update the component's level, do * notifications, and return. We intend to update the total power * state later (if the other thread fails to set power to the * desired level). If we were called because of a power change on a * component that isn't involved in a set_power op, update all state * immediately. */ cp = PM_CP(dip, comp); while (!pm_try_parent_child_locks(pdip, dip, &pcirc, &circ)) { if (((blocked = pm_blocked_by_us(dip)) != 0) && (cp->pmc_flags & PM_POWER_OP)) { if (pm_watchers()) { mutex_enter(&pm_rsvp_lock); pm_enqueue_notify(PSC_HAS_CHANGED, dip, comp, level, cur_power(cp), PM_CANBLOCK_BLOCK); mutex_exit(&pm_rsvp_lock); } if (pdip && PM_WANTS_NOTIFICATION(pdip)) pm_notify_parent(dip, pdip, comp, cur_power(cp), level); (void) pm_check_and_resume(dip, comp, cur_power(cp), level); /* * Stash the old power index, update curpwr, and flag * that the total power state needs to be synched. */ cp->pmc_flags |= PM_PHC_WHILE_SET_POWER; /* * Several pm_power_has_changed calls could arrive * while the set power path remains blocked. Keep the * oldest old power and the newest new power of any * sequence of phc calls which arrive during deadlock. */ if (cp->pmc_phc_pwr == PM_LEVEL_UNKNOWN) cp->pmc_phc_pwr = cp->pmc_cur_pwr; cp->pmc_cur_pwr = pm_level_to_index(dip, cp, level); PMD(PMD_PHC, ("%s: deadlock for %s@%s(%s#%d), comp=%d, " "level=%d\n", pmf, PM_DEVICE(dip), comp, level)) return (DDI_SUCCESS); } else if (blocked) { /* blocked, but different cmpt? */ if (!ndi_devi_tryenter(pdip, &pcirc)) { cmn_err(CE_NOTE, "!pm: parent kuc not updated due " "to possible deadlock.\n"); return (pm_phc_impl(dip, comp, level, 1)); } old_level = cur_power(cp); if (pdip && !PM_WANTS_NOTIFICATION(pdip) && (!PM_ISBC(dip) || comp == 0) && POWERING_ON(old_level, level)) pm_hold_power(pdip); ret = pm_phc_impl(dip, comp, level, 1); if (pdip && !PM_WANTS_NOTIFICATION(pdip)) { if ((!PM_ISBC(dip) || comp == 0) && level == 0 && old_level != PM_LEVEL_UNKNOWN) pm_rele_power(pdip); } ndi_devi_exit(pdip, pcirc); /* child lock not held: deadlock */ return (ret); } delay(1); PMD(PMD_PHC, ("%s: try lock again\n", pmf)) } /* non-deadlock case */ old_level = cur_power(cp); if (pdip && !PM_WANTS_NOTIFICATION(pdip) && (!PM_ISBC(dip) || comp == 0) && POWERING_ON(old_level, level)) pm_hold_power(pdip); ret = pm_phc_impl(dip, comp, level, 1); if (pdip && !PM_WANTS_NOTIFICATION(pdip)) { if ((!PM_ISBC(dip) || comp == 0) && level == 0 && old_level != PM_LEVEL_UNKNOWN) pm_rele_power(pdip); } PM_UNLOCK_POWER(dip, circ); ndi_devi_exit(pdip, pcirc); return (ret); } /* * Account for power changes to a component of the the console frame buffer. * If lowering power from full (or "unkown", which is treatd as full) * we will increment the "components off" count of the fb device. * Subsequent lowering of the same component doesn't affect the count. If * raising a component back to full power, we will decrement the count. * * Return: the increment value for pm_cfb_comps_off (-1, 0, or 1) */ static int calc_cfb_comps_incr(dev_info_t *dip, int cmpt, int old, int new) { struct pm_component *cp = PM_CP(dip, cmpt); int on = (old == PM_LEVEL_UNKNOWN || old == cp->pmc_norm_pwr); int want_normal = (new == cp->pmc_norm_pwr); int incr = 0; if (on && !want_normal) incr = 1; else if (!on && want_normal) incr = -1; return (incr); } /* * Adjust the count of console frame buffer components < full power. */ static void update_comps_off(int incr, dev_info_t *dip) { mutex_enter(&pm_cfb_lock); pm_cfb_comps_off += incr; ASSERT(pm_cfb_comps_off <= PM_NUMCMPTS(dip)); mutex_exit(&pm_cfb_lock); } /* * Update the power state in the framework (via the ppm). The 'notify' * argument tells whether to notify watchers. Power lock is already held. */ static int pm_phc_impl(dev_info_t *dip, int comp, int level, int notify) { PMD_FUNC(pmf, "phc_impl") power_req_t power_req; int i, dodeps = 0; dev_info_t *pdip = ddi_get_parent(dip); int result; int old_level; struct pm_component *cp; int incr = 0; dev_info_t *ppm = (dev_info_t *)DEVI(dip)->devi_pm_ppm; int work_type = 0; char *pathbuf; /* Must use "official" power level for this test. */ cp = PM_CP(dip, comp); old_level = (cp->pmc_flags & PM_PHC_WHILE_SET_POWER ? cp->pmc_phc_pwr : cp->pmc_cur_pwr); if (old_level != PM_LEVEL_UNKNOWN) old_level = cp->pmc_comp.pmc_lvals[old_level]; if (level == old_level) { PMD(PMD_SET, ("%s: %s@%s(%s#%d), comp=%d is already at " "level=%d\n", pmf, PM_DEVICE(dip), comp, level)) return (DDI_SUCCESS); } /* * Tell ppm about this. */ power_req.request_type = PMR_PPM_POWER_CHANGE_NOTIFY; power_req.req.ppm_notify_level_req.who = dip; power_req.req.ppm_notify_level_req.cmpt = comp; power_req.req.ppm_notify_level_req.new_level = level; power_req.req.ppm_notify_level_req.old_level = old_level; if (pm_ctlops(ppm, dip, DDI_CTLOPS_POWER, &power_req, &result) == DDI_FAILURE) { PMD(PMD_FAIL, ("%s: pm_ctlops %s@%s(%s#%d) to %d failed\n", pmf, PM_DEVICE(dip), level)) return (DDI_FAILURE); } if (PM_IS_CFB(dip)) { incr = calc_cfb_comps_incr(dip, comp, old_level, level); if (incr) { update_comps_off(incr, dip); PMD(PMD_CFB, ("%s: %s@%s(%s#%d) comp=%d %d->%d " "cfb_comps_off->%d\n", pmf, PM_DEVICE(dip), comp, old_level, level, pm_cfb_comps_off)) } } e_pm_set_cur_pwr(dip, PM_CP(dip, comp), level); result = DDI_SUCCESS; if (notify) { if (pdip && PM_WANTS_NOTIFICATION(pdip)) pm_notify_parent(dip, pdip, comp, old_level, level); (void) pm_check_and_resume(dip, comp, old_level, level); } /* * Decrement the dependency kidsup count if we turn a device * off. */ if (POWERING_OFF(old_level, level)) { dodeps = 1; for (i = 0; i < PM_NUMCMPTS(dip); i++) { cp = PM_CP(dip, i); if (cur_power(cp)) { dodeps = 0; break; } } if (dodeps) work_type = PM_DEP_WK_POWER_OFF; } /* * Increment if we turn it on. Check to see * if other comps are already on, if so, * dont increment. */ if (POWERING_ON(old_level, level)) { dodeps = 1; for (i = 0; i < PM_NUMCMPTS(dip); i++) { cp = PM_CP(dip, i); if (comp == i) continue; /* -1 also treated as 0 in this case */ if (cur_power(cp) > 0) { dodeps = 0; break; } } if (dodeps) work_type = PM_DEP_WK_POWER_ON; } if (dodeps) { pathbuf = kmem_zalloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); pm_dispatch_to_dep_thread(work_type, pathbuf, NULL, PM_DEP_NOWAIT, NULL, 0); kmem_free(pathbuf, MAXPATHLEN); } if (notify && (level != old_level) && pm_watchers()) { mutex_enter(&pm_rsvp_lock); pm_enqueue_notify(PSC_HAS_CHANGED, dip, comp, level, old_level, PM_CANBLOCK_BLOCK); mutex_exit(&pm_rsvp_lock); } PMD(PMD_RESCAN, ("%s: %s@%s(%s#%d): pm_rescan\n", pmf, PM_DEVICE(dip))) pm_rescan(dip); return (DDI_SUCCESS); } /* * This function is called at startup time to notify pm of the existence * of any platform power managers for this platform. As a result of * this registration, each function provided will be called each time * a device node is attached, until one returns true, and it must claim the * device node (by returning non-zero) if it wants to be involved in the * node's power management. If it does claim the node, then it will * subsequently be notified of attach and detach events. * */ int pm_register_ppm(int (*func)(dev_info_t *), dev_info_t *dip) { PMD_FUNC(pmf, "register_ppm") struct ppm_callbacks *ppmcp; pm_component_t *cp; int i, pwr, result, circ; power_req_t power_req; struct ppm_notify_level_req *p = &power_req.req.ppm_notify_level_req; void pm_ppm_claim(dev_info_t *); mutex_enter(&ppm_lock); ppmcp = ppm_callbacks; for (i = 0; i < MAX_PPM_HANDLERS; i++, ppmcp++) { if (ppmcp->ppmc_func == NULL) { ppmcp->ppmc_func = func; ppmcp->ppmc_dip = dip; break; } } mutex_exit(&ppm_lock); if (i >= MAX_PPM_HANDLERS) return (DDI_FAILURE); while ((dip = ddi_get_parent(dip)) != NULL) { if (PM_GET_PM_INFO(dip) == NULL) continue; pm_ppm_claim(dip); if (pm_ppm_claimed(dip)) { /* * Tell ppm about this. */ power_req.request_type = PMR_PPM_POWER_CHANGE_NOTIFY; p->old_level = PM_LEVEL_UNKNOWN; p->who = dip; PM_LOCK_POWER(dip, &circ); for (i = 0; i < PM_NUMCMPTS(dip); i++) { cp = PM_CP(dip, i); pwr = cp->pmc_cur_pwr; if (pwr != PM_LEVEL_UNKNOWN) { p->cmpt = i; p->new_level = cur_power(cp); p->old_level = PM_LEVEL_UNKNOWN; if (pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result) == DDI_FAILURE) { PMD(PMD_FAIL, ("%s: pc " "%s@%s(%s#%d) to %d " "fails\n", pmf, PM_DEVICE(dip), pwr)) } } } PM_UNLOCK_POWER(dip, circ); } } return (DDI_SUCCESS); } /* * Call the ppm's that have registered and adjust the devinfo struct as * appropriate. First one to claim it gets it. The sets of devices claimed * by each ppm are assumed to be disjoint. */ void pm_ppm_claim(dev_info_t *dip) { struct ppm_callbacks *ppmcp; if (PPM(dip)) { return; } mutex_enter(&ppm_lock); for (ppmcp = ppm_callbacks; ppmcp->ppmc_func; ppmcp++) { if ((*ppmcp->ppmc_func)(dip)) { DEVI(dip)->devi_pm_ppm = (struct dev_info *)ppmcp->ppmc_dip; mutex_exit(&ppm_lock); return; } } mutex_exit(&ppm_lock); } /* * Node is being detached so stop autopm until we see if it succeeds, in which * case pm_stop will be called. For backwards compatible devices we bring the * device up to full power on the assumption the detach will succeed. */ void pm_detaching(dev_info_t *dip) { PMD_FUNC(pmf, "detaching") pm_info_t *info = PM_GET_PM_INFO(dip); int iscons; PMD(PMD_REMDEV, ("%s: %s@%s(%s#%d), %d comps\n", pmf, PM_DEVICE(dip), PM_NUMCMPTS(dip))) if (info == NULL) return; ASSERT(DEVI_IS_DETACHING(dip)); PM_LOCK_DIP(dip); info->pmi_dev_pm_state |= PM_DETACHING; PM_UNLOCK_DIP(dip); if (!PM_ISBC(dip)) pm_scan_stop(dip); /* * console and old-style devices get brought up when detaching. */ iscons = PM_IS_CFB(dip); if (iscons || PM_ISBC(dip)) { (void) pm_all_to_normal(dip, PM_CANBLOCK_BYPASS); if (iscons) { mutex_enter(&pm_cfb_lock); while (cfb_inuse) { mutex_exit(&pm_cfb_lock); PMD(PMD_CFB, ("%s: delay; cfb_inuse\n", pmf)) delay(1); mutex_enter(&pm_cfb_lock); } ASSERT(cfb_dip_detaching == NULL); ASSERT(cfb_dip); cfb_dip_detaching = cfb_dip; /* case detach fails */ cfb_dip = NULL; mutex_exit(&pm_cfb_lock); } } } /* * Node failed to detach. If it used to be autopm'd, make it so again. */ void pm_detach_failed(dev_info_t *dip) { PMD_FUNC(pmf, "detach_failed") pm_info_t *info = PM_GET_PM_INFO(dip); int pm_all_at_normal(dev_info_t *); if (info == NULL) return; ASSERT(DEVI_IS_DETACHING(dip)); if (info->pmi_dev_pm_state & PM_DETACHING) { info->pmi_dev_pm_state &= ~PM_DETACHING; if (info->pmi_dev_pm_state & PM_ALLNORM_DEFERRED) { /* Make sure the operation is still needed */ if (!pm_all_at_normal(dip)) { if (pm_all_to_normal(dip, PM_CANBLOCK_FAIL) != DDI_SUCCESS) { PMD(PMD_ERROR, ("%s: could not bring " "%s@%s(%s#%d) to normal\n", pmf, PM_DEVICE(dip))) } } info->pmi_dev_pm_state &= ~PM_ALLNORM_DEFERRED; } } if (!PM_ISBC(dip)) { mutex_enter(&pm_scan_lock); if (PM_SCANABLE(dip)) pm_scan_init(dip); mutex_exit(&pm_scan_lock); pm_rescan(dip); } } /* generic Backwards Compatible component */ static char *bc_names[] = {"off", "on"}; static pm_comp_t bc_comp = {"unknown", 2, NULL, NULL, &bc_names[0]}; static void e_pm_default_levels(dev_info_t *dip, pm_component_t *cp, int norm) { pm_comp_t *pmc; pmc = &cp->pmc_comp; pmc->pmc_numlevels = 2; pmc->pmc_lvals[0] = 0; pmc->pmc_lvals[1] = norm; e_pm_set_cur_pwr(dip, cp, norm); } static void e_pm_default_components(dev_info_t *dip, int cmpts) { int i; pm_component_t *p = DEVI(dip)->devi_pm_components; p = DEVI(dip)->devi_pm_components; for (i = 0; i < cmpts; i++, p++) { p->pmc_comp = bc_comp; /* struct assignment */ p->pmc_comp.pmc_lvals = kmem_zalloc(2 * sizeof (int), KM_SLEEP); p->pmc_comp.pmc_thresh = kmem_alloc(2 * sizeof (int), KM_SLEEP); p->pmc_comp.pmc_numlevels = 2; p->pmc_comp.pmc_thresh[0] = INT_MAX; p->pmc_comp.pmc_thresh[1] = INT_MAX; } } /* * Called from functions that require components to exist already to allow * for their creation by parsing the pm-components property. * Device will not be power managed as a result of this call * No locking needed because we're single threaded by the ndi_devi_enter * done while attaching, and the device isn't visible until after it has * attached */ int pm_premanage(dev_info_t *dip, int style) { PMD_FUNC(pmf, "premanage") pm_comp_t *pcp, *compp; int cmpts, i, norm, error; pm_component_t *p = DEVI(dip)->devi_pm_components; pm_comp_t *pm_autoconfig(dev_info_t *, int *); ASSERT(!PM_IAM_LOCKING_DIP(dip)); /* * If this dip has already been processed, don't mess with it */ if (DEVI(dip)->devi_pm_flags & PMC_COMPONENTS_DONE) return (DDI_SUCCESS); if (DEVI(dip)->devi_pm_flags & PMC_COMPONENTS_FAILED) { return (DDI_FAILURE); } /* * Look up pm-components property and create components accordingly * If that fails, fall back to backwards compatibility */ if ((compp = pm_autoconfig(dip, &error)) == NULL) { /* * If error is set, the property existed but was not well formed */ if (error || (style == PM_STYLE_NEW)) { DEVI(dip)->devi_pm_flags |= PMC_COMPONENTS_FAILED; return (DDI_FAILURE); } /* * If they don't have the pm-components property, then we * want the old "no pm until PM_SET_DEVICE_THRESHOLDS ioctl" * behavior driver must have called pm_create_components, and * we need to flesh out dummy components */ if ((cmpts = PM_NUMCMPTS(dip)) == 0) { /* * Not really failure, but we don't want the * caller to treat it as success */ return (DDI_FAILURE); } DEVI(dip)->devi_pm_flags |= PMC_BC; e_pm_default_components(dip, cmpts); for (i = 0; i < cmpts; i++) { /* * if normal power not set yet, we don't really know * what *ANY* of the power values are. If normal * power is set, then we assume for this backwards * compatible case that the values are 0, normal power. */ norm = pm_get_normal_power(dip, i); if (norm == (uint_t)-1) { PMD(PMD_ERROR, ("%s: %s@%s(%s#%d)[%d]\n", pmf, PM_DEVICE(dip), i)) return (DDI_FAILURE); } /* * Components of BC devices start at their normal power, * so count them to be not at their lowest power. */ PM_INCR_NOTLOWEST(dip); e_pm_default_levels(dip, PM_CP(dip, i), norm); } } else { /* * e_pm_create_components was called from pm_autoconfig(), it * creates components with no descriptions (or known levels) */ cmpts = PM_NUMCMPTS(dip); ASSERT(cmpts != 0); pcp = compp; p = DEVI(dip)->devi_pm_components; for (i = 0; i < cmpts; i++, p++) { p->pmc_comp = *pcp++; /* struct assignment */ ASSERT(PM_CP(dip, i)->pmc_cur_pwr == 0); e_pm_set_cur_pwr(dip, PM_CP(dip, i), PM_LEVEL_UNKNOWN); } if (DEVI(dip)->devi_pm_flags & PMC_CPU_THRESH) pm_set_device_threshold(dip, pm_cpu_idle_threshold, PMC_CPU_THRESH); else pm_set_device_threshold(dip, pm_system_idle_threshold, PMC_DEF_THRESH); kmem_free(compp, cmpts * sizeof (pm_comp_t)); } return (DDI_SUCCESS); } /* * Called from during or after the device's attach to let us know it is ready * to play autopm. Look up the pm model and manage the device accordingly. * Returns system call errno value. * If DDI_ATTACH and DDI_DETACH were in same namespace, this would be * a little cleaner * * Called with dip lock held, return with dip lock unheld. */ int e_pm_manage(dev_info_t *dip, int style) { PMD_FUNC(pmf, "e_manage") pm_info_t *info; dev_info_t *pdip = ddi_get_parent(dip); int pm_thresh_specd(dev_info_t *); int count; char *pathbuf; if (pm_premanage(dip, style) != DDI_SUCCESS) { return (DDI_FAILURE); } PMD(PMD_KIDSUP, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) ASSERT(PM_GET_PM_INFO(dip) == NULL); info = kmem_zalloc(sizeof (pm_info_t), KM_SLEEP); /* * Now set up parent's kidsupcnt. BC nodes are assumed to start * out at their normal power, so they are "up", others start out * unknown, which is effectively "up". Parent which want notification * get kidsupcnt of 0 always. */ count = (PM_ISBC(dip)) ? 1 : PM_NUMCMPTS(dip); if (count && pdip && !PM_WANTS_NOTIFICATION(pdip)) e_pm_hold_rele_power(pdip, count); pm_set_pm_info(dip, info); /* * Apply any recorded thresholds */ (void) pm_thresh_specd(dip); /* * Do dependency processing. */ pathbuf = kmem_zalloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); pm_dispatch_to_dep_thread(PM_DEP_WK_ATTACH, pathbuf, pathbuf, PM_DEP_NOWAIT, NULL, 0); kmem_free(pathbuf, MAXPATHLEN); if (!PM_ISBC(dip)) { mutex_enter(&pm_scan_lock); if (PM_SCANABLE(dip)) { pm_scan_init(dip); mutex_exit(&pm_scan_lock); pm_rescan(dip); } else { mutex_exit(&pm_scan_lock); } } return (0); } /* * This is the obsolete exported interface for a driver to find out its * "normal" (max) power. * We only get components destroyed while no power management is * going on (and the device is detached), so we don't need a mutex here */ int pm_get_normal_power(dev_info_t *dip, int comp) { if (comp >= 0 && comp < PM_NUMCMPTS(dip)) { return (PM_CP(dip, comp)->pmc_norm_pwr); } return (DDI_FAILURE); } /* * Fetches the current power level. Return DDI_SUCCESS or DDI_FAILURE. */ int pm_get_current_power(dev_info_t *dip, int comp, int *levelp) { if (comp >= 0 && comp < PM_NUMCMPTS(dip)) { *levelp = PM_CURPOWER(dip, comp); return (DDI_SUCCESS); } return (DDI_FAILURE); } /* * Returns current threshold of indicated component */ static int cur_threshold(dev_info_t *dip, int comp) { pm_component_t *cp = PM_CP(dip, comp); int pwr; if (PM_ISBC(dip)) { /* * backwards compatible nodes only have one threshold */ return (cp->pmc_comp.pmc_thresh[1]); } pwr = cp->pmc_cur_pwr; if (pwr == PM_LEVEL_UNKNOWN) { int thresh; if (DEVI(dip)->devi_pm_flags & PMC_NEXDEF_THRESH) thresh = pm_default_nexus_threshold; else if (DEVI(dip)->devi_pm_flags & PMC_CPU_THRESH) thresh = pm_cpu_idle_threshold; else thresh = pm_system_idle_threshold; return (thresh); } ASSERT(cp->pmc_comp.pmc_thresh); return (cp->pmc_comp.pmc_thresh[pwr]); } /* * Compute next lower component power level given power index. */ static int pm_next_lower_power(pm_component_t *cp, int pwrndx) { int nxt_pwr; if (pwrndx == PM_LEVEL_UNKNOWN) { nxt_pwr = cp->pmc_comp.pmc_lvals[0]; } else { pwrndx--; ASSERT(pwrndx >= 0); nxt_pwr = cp->pmc_comp.pmc_lvals[pwrndx]; } return (nxt_pwr); } /* * Bring all components of device to normal power */ int pm_all_to_normal(dev_info_t *dip, pm_canblock_t canblock) { PMD_FUNC(pmf, "all_to_normal") int *normal; int i, ncomps, result; size_t size; int changefailed = 0; PMD(PMD_ALLNORM, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) ASSERT(PM_GET_PM_INFO(dip)); if (pm_get_norm_pwrs(dip, &normal, &size) != DDI_SUCCESS) { PMD(PMD_ALLNORM, ("%s: can't get norm pwrs for " "%s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) return (DDI_FAILURE); } ncomps = PM_NUMCMPTS(dip); for (i = 0; i < ncomps; i++) { if (pm_set_power(dip, i, normal[i], PM_LEVEL_UPONLY, canblock, 0, &result) != DDI_SUCCESS) { changefailed++; PMD(PMD_ALLNORM | PMD_FAIL, ("%s: failed to set " "%s@%s(%s#%d)[%d] to %d, errno %d\n", pmf, PM_DEVICE(dip), i, normal[i], result)) } } kmem_free(normal, size); if (changefailed) { PMD(PMD_FAIL, ("%s: failed to set %d comps %s@%s(%s#%d) " "to full power\n", pmf, changefailed, PM_DEVICE(dip))) return (DDI_FAILURE); } return (DDI_SUCCESS); } /* * Returns true if all components of device are at normal power */ int pm_all_at_normal(dev_info_t *dip) { PMD_FUNC(pmf, "all_at_normal") int *normal; int i; size_t size; PMD(PMD_ALLNORM, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) if (pm_get_norm_pwrs(dip, &normal, &size) != DDI_SUCCESS) { PMD(PMD_ALLNORM, ("%s: can't get normal power\n", pmf)) return (DDI_FAILURE); } for (i = 0; i < PM_NUMCMPTS(dip); i++) { int current = PM_CURPOWER(dip, i); if (normal[i] > current) { PMD(PMD_ALLNORM, ("%s: %s@%s(%s#%d) comp=%d, " "norm=%d, cur=%d\n", pmf, PM_DEVICE(dip), i, normal[i], current)) break; } } kmem_free(normal, size); if (i != PM_NUMCMPTS(dip)) { return (0); } return (1); } static void bring_wekeeps_up(char *keeper) { PMD_FUNC(pmf, "bring_wekeeps_up") int i; pm_pdr_t *dp; pm_info_t *wku_info; char *kept_path; dev_info_t *kept; static void bring_pmdep_up(dev_info_t *, int); if (panicstr) { return; } /* * We process the request even if the keeper detaches because * detach processing expects this to increment kidsupcnt of kept. */ PMD(PMD_BRING, ("%s: keeper= %s\n", pmf, keeper)) for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (strcmp(dp->pdr_keeper, keeper) != 0) continue; for (i = 0; i < dp->pdr_kept_count; i++) { kept_path = dp->pdr_kept_paths[i]; if (kept_path == NULL) continue; ASSERT(kept_path[0] != '\0'); if ((kept = pm_name_to_dip(kept_path, 1)) == NULL) continue; wku_info = PM_GET_PM_INFO(kept); if (wku_info == NULL) { if (kept) ddi_release_devi(kept); continue; } /* * Don't mess with it if it is being detached, it isn't * safe to call its power entry point */ if (wku_info->pmi_dev_pm_state & PM_DETACHING) { if (kept) ddi_release_devi(kept); continue; } bring_pmdep_up(kept, 1); ddi_release_devi(kept); } } } /* * Bring up the 'kept' device passed as argument */ static void bring_pmdep_up(dev_info_t *kept_dip, int hold) { PMD_FUNC(pmf, "bring_pmdep_up") int is_all_at_normal = 0; /* * If the kept device has been unmanaged, do nothing. */ if (!PM_GET_PM_INFO(kept_dip)) return; /* Just ignore DIRECT PM device till they are released. */ if (!pm_processes_stopped && PM_ISDIRECT(kept_dip) && !(is_all_at_normal = pm_all_at_normal(kept_dip))) { PMD(PMD_BRING, ("%s: can't bring up PM_DIRECT %s@%s(%s#%d) " "controlling process did something else\n", pmf, PM_DEVICE(kept_dip))) DEVI(kept_dip)->devi_pm_flags |= PMC_SKIP_BRINGUP; return; } /* if we got here the keeper had a transition from OFF->ON */ if (hold) pm_hold_power(kept_dip); if (!is_all_at_normal) (void) pm_all_to_normal(kept_dip, PM_CANBLOCK_FAIL); } /* * A bunch of stuff that belongs only to the next routine (or two) */ static const char namestr[] = "NAME="; static const int nameln = sizeof (namestr) - 1; static const char pmcompstr[] = "pm-components"; struct pm_comp_pkg { pm_comp_t *comp; struct pm_comp_pkg *next; }; #define isdigit(ch) ((ch) >= '0' && (ch) <= '9') #define isxdigit(ch) (isdigit(ch) || ((ch) >= 'a' && (ch) <= 'f') || \ ((ch) >= 'A' && (ch) <= 'F')) /* * Rather than duplicate this code ... * (this code excerpted from the function that follows it) */ #define FINISH_COMP { \ ASSERT(compp); \ compp->pmc_lnames_sz = size; \ tp = compp->pmc_lname_buf = kmem_alloc(size, KM_SLEEP); \ compp->pmc_numlevels = level; \ compp->pmc_lnames = kmem_alloc(level * sizeof (char *), KM_SLEEP); \ compp->pmc_lvals = kmem_alloc(level * sizeof (int), KM_SLEEP); \ compp->pmc_thresh = kmem_alloc(level * sizeof (int), KM_SLEEP); \ /* copy string out of prop array into buffer */ \ for (j = 0; j < level; j++) { \ compp->pmc_thresh[j] = INT_MAX; /* only [0] sticks */ \ compp->pmc_lvals[j] = lvals[j]; \ (void) strcpy(tp, lnames[j]); \ compp->pmc_lnames[j] = tp; \ tp += lszs[j]; \ } \ ASSERT(tp > compp->pmc_lname_buf && tp <= \ compp->pmc_lname_buf + compp->pmc_lnames_sz); \ } /* * Create (empty) component data structures. */ static void e_pm_create_components(dev_info_t *dip, int num_components) { struct pm_component *compp, *ocompp; int i, size = 0; ASSERT(!PM_IAM_LOCKING_DIP(dip)); ASSERT(!DEVI(dip)->devi_pm_components); ASSERT(!(DEVI(dip)->devi_pm_flags & PMC_COMPONENTS_DONE)); size = sizeof (struct pm_component) * num_components; compp = kmem_zalloc(size, KM_SLEEP); ocompp = compp; DEVI(dip)->devi_pm_comp_size = size; DEVI(dip)->devi_pm_num_components = num_components; PM_LOCK_BUSY(dip); for (i = 0; i < num_components; i++) { compp->pmc_timestamp = gethrestime_sec(); compp->pmc_norm_pwr = (uint_t)-1; compp++; } PM_UNLOCK_BUSY(dip); DEVI(dip)->devi_pm_components = ocompp; DEVI(dip)->devi_pm_flags |= PMC_COMPONENTS_DONE; } /* * Parse hex or decimal value from char string */ static char * pm_parsenum(char *cp, int *valp) { int ch, offset; char numbuf[256]; char *np = numbuf; int value = 0; ch = *cp++; if (isdigit(ch)) { if (ch == '0') { if ((ch = *cp++) == 'x' || ch == 'X') { ch = *cp++; while (isxdigit(ch)) { *np++ = (char)ch; ch = *cp++; } *np = 0; cp--; goto hexval; } else { goto digit; } } else { digit: while (isdigit(ch)) { *np++ = (char)ch; ch = *cp++; } *np = 0; cp--; goto decval; } } else return (NULL); hexval: for (np = numbuf; *np; np++) { if (*np >= 'a' && *np <= 'f') offset = 'a' - 10; else if (*np >= 'A' && *np <= 'F') offset = 'A' - 10; else if (*np >= '0' && *np <= '9') offset = '0'; value *= 16; value += *np - offset; } *valp = value; return (cp); decval: offset = '0'; for (np = numbuf; *np; np++) { value *= 10; value += *np - offset; } *valp = value; return (cp); } /* * Set max (previously documented as "normal") power. */ static void e_pm_set_max_power(dev_info_t *dip, int component_number, int level) { PM_CP(dip, component_number)->pmc_norm_pwr = level; } /* * Internal routine for destroying components * It is called even when there might not be any, so it must be forgiving. */ static void e_pm_destroy_components(dev_info_t *dip) { int i; struct pm_component *cp; ASSERT(!PM_IAM_LOCKING_DIP(dip)); if (PM_NUMCMPTS(dip) == 0) return; cp = DEVI(dip)->devi_pm_components; ASSERT(cp); for (i = 0; i < PM_NUMCMPTS(dip); i++, cp++) { int nlevels = cp->pmc_comp.pmc_numlevels; kmem_free(cp->pmc_comp.pmc_lvals, nlevels * sizeof (int)); kmem_free(cp->pmc_comp.pmc_thresh, nlevels * sizeof (int)); /* * For BC nodes, the rest is static in bc_comp, so skip it */ if (PM_ISBC(dip)) continue; kmem_free(cp->pmc_comp.pmc_name, cp->pmc_comp.pmc_name_sz); kmem_free(cp->pmc_comp.pmc_lnames, nlevels * sizeof (char *)); kmem_free(cp->pmc_comp.pmc_lname_buf, cp->pmc_comp.pmc_lnames_sz); } kmem_free(DEVI(dip)->devi_pm_components, DEVI(dip)->devi_pm_comp_size); DEVI(dip)->devi_pm_components = NULL; DEVI(dip)->devi_pm_num_components = 0; DEVI(dip)->devi_pm_flags &= ~(PMC_COMPONENTS_DONE | PMC_COMPONENTS_FAILED); } /* * Read the pm-components property (if there is one) and use it to set up * components. Returns a pointer to an array of component structures if * pm-components found and successfully parsed, else returns NULL. * Sets error return *errp to true to indicate a failure (as opposed to no * property being present). */ pm_comp_t * pm_autoconfig(dev_info_t *dip, int *errp) { PMD_FUNC(pmf, "autoconfig") uint_t nelems; char **pp; pm_comp_t *compp = NULL; int i, j, level, components = 0; size_t size = 0; struct pm_comp_pkg *p, *ptail; struct pm_comp_pkg *phead = NULL; int *lvals = NULL; int *lszs = NULL; int *np = NULL; int npi = 0; char **lnames = NULL; char *cp, *tp; pm_comp_t *ret = NULL; ASSERT(!PM_IAM_LOCKING_DIP(dip)); *errp = 0; /* assume success */ if (ddi_prop_lookup_string_array(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, (char *)pmcompstr, &pp, &nelems) != DDI_PROP_SUCCESS) { return (NULL); } if (nelems < 3) { /* need at least one name and two levels */ goto errout; } /* * pm_create_components is no longer allowed */ if (PM_NUMCMPTS(dip) != 0) { PMD(PMD_ERROR, ("%s: %s@%s(%s#%d) has %d comps\n", pmf, PM_DEVICE(dip), PM_NUMCMPTS(dip))) goto errout; } lvals = kmem_alloc(nelems * sizeof (int), KM_SLEEP); lszs = kmem_alloc(nelems * sizeof (int), KM_SLEEP); lnames = kmem_alloc(nelems * sizeof (char *), KM_SLEEP); np = kmem_alloc(nelems * sizeof (int), KM_SLEEP); level = 0; phead = NULL; for (i = 0; i < nelems; i++) { cp = pp[i]; if (!isdigit(*cp)) { /* must be name */ if (strncmp(cp, namestr, nameln) != 0) { goto errout; } if (i != 0) { if (level == 0) { /* no level spec'd */ PMD(PMD_ERROR, ("%s: no level spec'd\n", pmf)) goto errout; } np[npi++] = lvals[level - 1]; /* finish up previous component levels */ FINISH_COMP; } cp += nameln; if (!*cp) { PMD(PMD_ERROR, ("%s: nsa\n", pmf)) goto errout; } p = kmem_zalloc(sizeof (*phead), KM_SLEEP); if (phead == NULL) { phead = ptail = p; } else { ptail->next = p; ptail = p; } compp = p->comp = kmem_zalloc(sizeof (pm_comp_t), KM_SLEEP); compp->pmc_name_sz = strlen(cp) + 1; compp->pmc_name = kmem_zalloc(compp->pmc_name_sz, KM_SLEEP); (void) strncpy(compp->pmc_name, cp, compp->pmc_name_sz); components++; level = 0; } else { /* better be power level = */ #ifdef DEBUG tp = cp; #endif if (i == 0 || (cp = pm_parsenum(cp, &lvals[level])) == NULL) { PMD(PMD_ERROR, ("%s: parsenum(%s)\n", pmf, tp)) goto errout; } #ifdef DEBUG tp = cp; #endif if (*cp++ != '=' || !*cp) { PMD(PMD_ERROR, ("%s: ex =, got %s\n", pmf, tp)) goto errout; } lszs[level] = strlen(cp) + 1; size += lszs[level]; lnames[level] = cp; /* points into prop string */ level++; } } np[npi++] = lvals[level - 1]; if (level == 0) { /* ended with a name */ PMD(PMD_ERROR, ("%s: ewn\n", pmf)) goto errout; } FINISH_COMP; /* * Now we have a list of components--we have to return instead an * array of them, but we can just copy the top level and leave * the rest as is */ (void) e_pm_create_components(dip, components); for (i = 0; i < components; i++) e_pm_set_max_power(dip, i, np[i]); ret = kmem_zalloc(components * sizeof (pm_comp_t), KM_SLEEP); for (i = 0, p = phead; i < components; i++) { ASSERT(p); /* * Now sanity-check values: levels must be monotonically * increasing */ if (p->comp->pmc_numlevels < 2) { PMD(PMD_ERROR, ("%s: comp %s of %s@%s(%s#%d) only %d " "levels\n", pmf, p->comp->pmc_name, PM_DEVICE(dip), p->comp->pmc_numlevels)) goto errout; } for (j = 0; j < p->comp->pmc_numlevels; j++) { if ((p->comp->pmc_lvals[j] < 0) || ((j > 0) && (p->comp->pmc_lvals[j] <= p->comp->pmc_lvals[j - 1]))) { PMD(PMD_ERROR, ("%s: comp %s of %s@%s(%s#%d) " "not mono. incr, %d follows %d\n", pmf, p->comp->pmc_name, PM_DEVICE(dip), p->comp->pmc_lvals[j], p->comp->pmc_lvals[j - 1])) goto errout; } } ret[i] = *p->comp; /* struct assignment */ for (j = 0; j < i; j++) { /* * Test for unique component names */ if (strcmp(ret[j].pmc_name, ret[i].pmc_name) == 0) { PMD(PMD_ERROR, ("%s: %s of %s@%s(%s#%d) not " "unique\n", pmf, ret[j].pmc_name, PM_DEVICE(dip))) goto errout; } } ptail = p; p = p->next; phead = p; /* errout depends on phead making sense */ kmem_free(ptail->comp, sizeof (*ptail->comp)); kmem_free(ptail, sizeof (*ptail)); } out: ddi_prop_free(pp); if (lvals) kmem_free(lvals, nelems * sizeof (int)); if (lszs) kmem_free(lszs, nelems * sizeof (int)); if (lnames) kmem_free(lnames, nelems * sizeof (char *)); if (np) kmem_free(np, nelems * sizeof (int)); return (ret); errout: e_pm_destroy_components(dip); *errp = 1; /* signal failure */ cmn_err(CE_CONT, "!pm: %s property ", pmcompstr); for (i = 0; i < nelems - 1; i++) cmn_err(CE_CONT, "!'%s', ", pp[i]); if (nelems != 0) cmn_err(CE_CONT, "!'%s'", pp[nelems - 1]); cmn_err(CE_CONT, "! for %s@%s(%s#%d) is ill-formed.\n", PM_DEVICE(dip)); for (p = phead; p; ) { pm_comp_t *pp; int n; ptail = p; /* * Free component data structures */ pp = p->comp; n = pp->pmc_numlevels; if (pp->pmc_name_sz) { kmem_free(pp->pmc_name, pp->pmc_name_sz); } if (pp->pmc_lnames_sz) { kmem_free(pp->pmc_lname_buf, pp->pmc_lnames_sz); } if (pp->pmc_lnames) { kmem_free(pp->pmc_lnames, n * (sizeof (char *))); } if (pp->pmc_thresh) { kmem_free(pp->pmc_thresh, n * (sizeof (int))); } if (pp->pmc_lvals) { kmem_free(pp->pmc_lvals, n * (sizeof (int))); } p = ptail->next; kmem_free(ptail, sizeof (*ptail)); } if (ret != NULL) kmem_free(ret, components * sizeof (pm_comp_t)); ret = NULL; goto out; } /* * Set threshold values for a devices components by dividing the target * threshold (base) by the number of transitions and assign each transition * that threshold. This will get the entire device down in the target time if * all components are idle and even if there are dependencies among components. * * Devices may well get powered all the way down before the target time, but * at least the EPA will be happy. */ void pm_set_device_threshold(dev_info_t *dip, int base, int flag) { PMD_FUNC(pmf, "set_device_threshold") int target_threshold = (base * 95) / 100; int level, comp; /* loop counters */ int transitions = 0; int ncomp = PM_NUMCMPTS(dip); int thresh; int remainder; pm_comp_t *pmc; int i, circ; ASSERT(!PM_IAM_LOCKING_DIP(dip)); PM_LOCK_DIP(dip); /* * First we handle the easy one. If we're setting the default * threshold for a node with children, then we set it to the * default nexus threshold (currently 0) and mark it as default * nexus threshold instead */ if (PM_IS_NEXUS(dip)) { if (flag == PMC_DEF_THRESH) { PMD(PMD_THRESH, ("%s: [%s@%s(%s#%d) NEXDEF]\n", pmf, PM_DEVICE(dip))) thresh = pm_default_nexus_threshold; for (comp = 0; comp < ncomp; comp++) { pmc = &PM_CP(dip, comp)->pmc_comp; for (level = 1; level < pmc->pmc_numlevels; level++) { pmc->pmc_thresh[level] = thresh; } } DEVI(dip)->devi_pm_dev_thresh = pm_default_nexus_threshold; /* * If the nexus node is being reconfigured back to * the default threshold, adjust the notlowest count. */ if (DEVI(dip)->devi_pm_flags & (PMC_DEV_THRESH|PMC_COMP_THRESH)) { PM_LOCK_POWER(dip, &circ); for (i = 0; i < PM_NUMCMPTS(dip); i++) { if (PM_CURPOWER(dip, i) == 0) continue; mutex_enter(&pm_compcnt_lock); ASSERT(pm_comps_notlowest); pm_comps_notlowest--; PMD(PMD_LEVEL, ("%s: %s@%s(%s#%d) decr " "notlowest to %d\n", pmf, PM_DEVICE(dip), pm_comps_notlowest)) if (pm_comps_notlowest == 0) pm_ppm_notify_all_lowest(dip, PM_ALL_LOWEST); mutex_exit(&pm_compcnt_lock); } PM_UNLOCK_POWER(dip, circ); } DEVI(dip)->devi_pm_flags &= PMC_THRESH_NONE; DEVI(dip)->devi_pm_flags |= PMC_NEXDEF_THRESH; PM_UNLOCK_DIP(dip); return; } else if (DEVI(dip)->devi_pm_flags & PMC_NEXDEF_THRESH) { /* * If the nexus node is being configured for a * non-default threshold, include that node in * the notlowest accounting. */ PM_LOCK_POWER(dip, &circ); for (i = 0; i < PM_NUMCMPTS(dip); i++) { if (PM_CURPOWER(dip, i) == 0) continue; mutex_enter(&pm_compcnt_lock); if (pm_comps_notlowest == 0) pm_ppm_notify_all_lowest(dip, PM_NOT_ALL_LOWEST); pm_comps_notlowest++; PMD(PMD_LEVEL, ("%s: %s@%s(%s#%d) incr " "notlowest to %d\n", pmf, PM_DEVICE(dip), pm_comps_notlowest)) mutex_exit(&pm_compcnt_lock); } PM_UNLOCK_POWER(dip, circ); } } /* * Compute the total number of transitions for all components * of the device. Distribute the threshold evenly over them */ for (comp = 0; comp < ncomp; comp++) { pmc = &PM_CP(dip, comp)->pmc_comp; ASSERT(pmc->pmc_numlevels > 1); transitions += pmc->pmc_numlevels - 1; } ASSERT(transitions); thresh = target_threshold / transitions; for (comp = 0; comp < ncomp; comp++) { pmc = &PM_CP(dip, comp)->pmc_comp; for (level = 1; level < pmc->pmc_numlevels; level++) { pmc->pmc_thresh[level] = thresh; } } #ifdef DEBUG for (comp = 0; comp < ncomp; comp++) { pmc = &PM_CP(dip, comp)->pmc_comp; for (level = 1; level < pmc->pmc_numlevels; level++) { PMD(PMD_THRESH, ("%s: thresh before %s@%s(%s#%d) " "comp=%d, level=%d, %d\n", pmf, PM_DEVICE(dip), comp, level, pmc->pmc_thresh[level])) } } #endif /* * Distribute any remainder till they are all gone */ remainder = target_threshold - thresh * transitions; level = 1; #ifdef DEBUG PMD(PMD_THRESH, ("%s: remainder=%d target_threshold=%d thresh=%d " "trans=%d\n", pmf, remainder, target_threshold, thresh, transitions)) #endif while (remainder > 0) { comp = 0; while (remainder && (comp < ncomp)) { pmc = &PM_CP(dip, comp)->pmc_comp; if (level < pmc->pmc_numlevels) { pmc->pmc_thresh[level] += 1; remainder--; } comp++; } level++; } #ifdef DEBUG for (comp = 0; comp < ncomp; comp++) { pmc = &PM_CP(dip, comp)->pmc_comp; for (level = 1; level < pmc->pmc_numlevels; level++) { PMD(PMD_THRESH, ("%s: thresh after %s@%s(%s#%d) " "comp=%d level=%d, %d\n", pmf, PM_DEVICE(dip), comp, level, pmc->pmc_thresh[level])) } } #endif ASSERT(PM_IAM_LOCKING_DIP(dip)); DEVI(dip)->devi_pm_dev_thresh = base; DEVI(dip)->devi_pm_flags &= PMC_THRESH_NONE; DEVI(dip)->devi_pm_flags |= flag; PM_UNLOCK_DIP(dip); } /* * Called when there is no old-style platform power management driver */ static int ddi_no_platform_power(power_req_t *req) { _NOTE(ARGUNUSED(req)) return (DDI_FAILURE); } /* * This function calls the entry point supplied by the platform-specific * pm driver to bring the device component 'pm_cmpt' to power level 'pm_level'. * The use of global for getting the function name from platform-specific * pm driver is not ideal, but it is simple and efficient. * The previous property lookup was being done in the idle loop on swift * systems without pmc chips and hurt deskbench performance as well as * violating scheduler locking rules */ int (*pm_platform_power)(power_req_t *) = ddi_no_platform_power; /* * Old obsolete interface for a device to request a power change (but only * an increase in power) */ int ddi_dev_is_needed(dev_info_t *dip, int cmpt, int level) { return (pm_raise_power(dip, cmpt, level)); } /* * The old obsolete interface to platform power management. Only used by * Gypsy platform and APM on X86. */ int ddi_power(dev_info_t *dip, int pm_cmpt, int pm_level) { power_req_t request; request.request_type = PMR_SET_POWER; request.req.set_power_req.who = dip; request.req.set_power_req.cmpt = pm_cmpt; request.req.set_power_req.level = pm_level; return (ddi_ctlops(dip, dip, DDI_CTLOPS_POWER, &request, NULL)); } /* * A driver can invoke this from its detach routine when DDI_SUSPEND is * passed. Returns true if subsequent processing could result in power being * removed from the device. The arg is not currently used because it is * implicit in the operation of cpr/DR. */ int ddi_removing_power(dev_info_t *dip) { _NOTE(ARGUNUSED(dip)) return (pm_powering_down); } /* * Returns true if a device indicates that its parent handles suspend/resume * processing for it. */ int e_ddi_parental_suspend_resume(dev_info_t *dip) { return (DEVI(dip)->devi_pm_flags & PMC_PARENTAL_SR); } /* * Called for devices which indicate that their parent does suspend/resume * handling for them */ int e_ddi_suspend(dev_info_t *dip, ddi_detach_cmd_t cmd) { power_req_t request; request.request_type = PMR_SUSPEND; request.req.suspend_req.who = dip; request.req.suspend_req.cmd = cmd; return (ddi_ctlops(dip, dip, DDI_CTLOPS_POWER, &request, NULL)); } /* * Called for devices which indicate that their parent does suspend/resume * handling for them */ int e_ddi_resume(dev_info_t *dip, ddi_attach_cmd_t cmd) { power_req_t request; request.request_type = PMR_RESUME; request.req.resume_req.who = dip; request.req.resume_req.cmd = cmd; return (ddi_ctlops(dip, dip, DDI_CTLOPS_POWER, &request, NULL)); } /* * Old obsolete exported interface for drivers to create components. * This is now handled by exporting the pm-components property. */ int pm_create_components(dev_info_t *dip, int num_components) { PMD_FUNC(pmf, "pm_create_components") if (num_components < 1) return (DDI_FAILURE); if (!DEVI_IS_ATTACHING(dip)) { return (DDI_FAILURE); } /* don't need to lock dip because attach is single threaded */ if (DEVI(dip)->devi_pm_components) { PMD(PMD_ERROR, ("%s: %s@%s(%s#%d) already has %d\n", pmf, PM_DEVICE(dip), PM_NUMCMPTS(dip))) return (DDI_FAILURE); } e_pm_create_components(dip, num_components); DEVI(dip)->devi_pm_flags |= PMC_BC; e_pm_default_components(dip, num_components); return (DDI_SUCCESS); } /* * Obsolete interface previously called by drivers to destroy their components * at detach time. This is now done automatically. However, we need to keep * this for the old drivers. */ void pm_destroy_components(dev_info_t *dip) { PMD_FUNC(pmf, "pm_destroy_components") dev_info_t *pdip = ddi_get_parent(dip); PMD(PMD_REMDEV | PMD_KIDSUP, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) ASSERT(DEVI_IS_DETACHING(dip)); #ifdef DEBUG if (!PM_ISBC(dip)) cmn_err(CE_WARN, "!driver exporting pm-components property " "(%s@%s) calls pm_destroy_components", PM_NAME(dip), PM_ADDR(dip)); #endif /* * We ignore this unless this is an old-style driver, except for * printing the message above */ if (PM_NUMCMPTS(dip) == 0 || !PM_ISBC(dip)) { PMD(PMD_REMDEV, ("%s: ignore %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) return; } ASSERT(PM_GET_PM_INFO(dip)); /* * pm_unmanage will clear info pointer later, after dealing with * dependencies */ ASSERT(!PM_GET_PM_SCAN(dip)); /* better be gone already */ /* * Now adjust parent's kidsupcnt. We check only comp 0. * Parents that get notification are not adjusted because their * kidsupcnt is always 0 (or 1 during probe and attach). */ if ((PM_CURPOWER(dip, 0) != 0) && pdip && !PM_WANTS_NOTIFICATION(pdip)) pm_rele_power(pdip); #ifdef DEBUG else { PMD(PMD_KIDSUP, ("%s: kuc stays %s@%s(%s#%d) comps gone\n", pmf, PM_DEVICE(dip))) } #endif e_pm_destroy_components(dip); /* * Forget we ever knew anything about the components of this device */ DEVI(dip)->devi_pm_flags &= ~(PMC_BC | PMC_COMPONENTS_DONE | PMC_COMPONENTS_FAILED); } /* * Exported interface for a driver to set a component busy. */ int pm_busy_component(dev_info_t *dip, int cmpt) { struct pm_component *cp; ASSERT(dip != NULL); if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, cmpt, &cp)) return (DDI_FAILURE); PM_LOCK_BUSY(dip); cp->pmc_busycount++; cp->pmc_timestamp = 0; PM_UNLOCK_BUSY(dip); return (DDI_SUCCESS); } /* * Exported interface for a driver to set a component idle. */ int pm_idle_component(dev_info_t *dip, int cmpt) { PMD_FUNC(pmf, "pm_idle_component") struct pm_component *cp; pm_scan_t *scanp = PM_GET_PM_SCAN(dip); if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, cmpt, &cp)) return (DDI_FAILURE); PM_LOCK_BUSY(dip); if (cp->pmc_busycount) { if (--(cp->pmc_busycount) == 0) cp->pmc_timestamp = gethrestime_sec(); } else { cp->pmc_timestamp = gethrestime_sec(); } PM_UNLOCK_BUSY(dip); /* * if device becomes idle during idle down period, try scan it down */ if (scanp && PM_IS_PID(dip)) { PMD(PMD_IDLEDOWN, ("%s: %s@%s(%s#%d) idle.\n", pmf, PM_DEVICE(dip))) pm_rescan(dip); return (DDI_SUCCESS); } /* * handle scan not running with nexus threshold == 0 */ if (PM_IS_NEXUS(dip) && (cp->pmc_busycount == 0)) { pm_rescan(dip); } return (DDI_SUCCESS); } /* * This is the old obsolete interface called by drivers to set their normal * power. Thus we can't fix its behavior or return a value. * This functionality is replaced by the pm-component property. * We'll only get components destroyed while no power management is * going on (and the device is detached), so we don't need a mutex here */ void pm_set_normal_power(dev_info_t *dip, int comp, int level) { PMD_FUNC(pmf, "set_normal_power") #ifdef DEBUG if (!PM_ISBC(dip)) cmn_err(CE_WARN, "!call to pm_set_normal_power() by %s@%s " "(driver exporting pm-components property) ignored", PM_NAME(dip), PM_ADDR(dip)); #endif if (PM_ISBC(dip)) { PMD(PMD_NORM, ("%s: %s@%s(%s#%d) set normal power comp=%d, " "level=%d\n", pmf, PM_DEVICE(dip), comp, level)) e_pm_set_max_power(dip, comp, level); e_pm_default_levels(dip, PM_CP(dip, comp), level); } } /* * Called on a successfully detached driver to free pm resources */ static void pm_stop(dev_info_t *dip) { PMD_FUNC(pmf, "stop") dev_info_t *pdip = ddi_get_parent(dip); ASSERT(!PM_IAM_LOCKING_DIP(dip)); /* stopping scan, destroy scan data structure */ if (!PM_ISBC(dip)) { pm_scan_stop(dip); pm_scan_fini(dip); } if (PM_GET_PM_INFO(dip) != NULL) { if (pm_unmanage(dip) == DDI_SUCCESS) { /* * Old style driver may have called * pm_destroy_components already, but just in case ... */ e_pm_destroy_components(dip); } else { PMD(PMD_FAIL, ("%s: can't pm_unmanage %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) } } else { if (PM_NUMCMPTS(dip)) e_pm_destroy_components(dip); else { if (DEVI(dip)->devi_pm_flags & PMC_NOPMKID) { DEVI(dip)->devi_pm_flags &= ~PMC_NOPMKID; if (pdip && !PM_WANTS_NOTIFICATION(pdip)) { pm_rele_power(pdip); } else if (pdip && MDI_VHCI(pdip) && MDI_CLIENT(dip)) { (void) mdi_power(pdip, MDI_PM_RELE_POWER, (void *)dip, NULL, 0); } } } } } /* * The node is the subject of a reparse pm props ioctl. Throw away the old * info and start over. */ int e_new_pm_props(dev_info_t *dip) { if (PM_GET_PM_INFO(dip) != NULL) { pm_stop(dip); if (e_pm_manage(dip, PM_STYLE_NEW) != DDI_SUCCESS) { return (DDI_FAILURE); } } e_pm_props(dip); return (DDI_SUCCESS); } /* * Device has been attached, so process its pm properties */ void e_pm_props(dev_info_t *dip) { char *pp; int len; int flags = 0; int propflag = DDI_PROP_DONTPASS|DDI_PROP_CANSLEEP; /* * It doesn't matter if we do this more than once, we should always * get the same answers, and if not, then the last one in is the * best one. */ if (ddi_getlongprop(DDI_DEV_T_ANY, dip, propflag, "pm-hardware-state", (caddr_t)&pp, &len) == DDI_PROP_SUCCESS) { if (strcmp(pp, "needs-suspend-resume") == 0) { flags = PMC_NEEDS_SR; } else if (strcmp(pp, "no-suspend-resume") == 0) { flags = PMC_NO_SR; } else if (strcmp(pp, "parental-suspend-resume") == 0) { flags = PMC_PARENTAL_SR; } else { cmn_err(CE_NOTE, "!device %s@%s has unrecognized " "%s property value '%s'", PM_NAME(dip), PM_ADDR(dip), "pm-hardware-state", pp); } kmem_free(pp, len); } /* * This next segment (PMC_WANTS_NOTIFY) is in * support of nexus drivers which will want to be involved in * (or at least notified of) their child node's power level transitions. * "pm-want-child-notification?" is defined by the parent. */ if (ddi_prop_exists(DDI_DEV_T_ANY, dip, propflag, "pm-want-child-notification?") && PM_HAS_BUS_POWER(dip)) flags |= PMC_WANTS_NOTIFY; ASSERT(PM_HAS_BUS_POWER(dip) || !ddi_prop_exists(DDI_DEV_T_ANY, dip, propflag, "pm-want-child-notification?")); if (ddi_prop_exists(DDI_DEV_T_ANY, dip, propflag, "no-involuntary-power-cycles")) flags |= PMC_NO_INVOL; /* * Is the device a CPU device? */ if (ddi_getlongprop(DDI_DEV_T_ANY, dip, propflag, "pm-class", (caddr_t)&pp, &len) == DDI_PROP_SUCCESS) { if (strcmp(pp, "CPU") == 0) { flags |= PMC_CPU_DEVICE; } else { cmn_err(CE_NOTE, "!device %s@%s has unrecognized " "%s property value '%s'", PM_NAME(dip), PM_ADDR(dip), "pm-class", pp); } kmem_free(pp, len); } /* devfs single threads us */ DEVI(dip)->devi_pm_flags |= flags; } /* * This is the DDI_CTLOPS_POWER handler that is used when there is no ppm * driver which has claimed a node. * Sets old_power in arg struct. */ static int pm_default_ctlops(dev_info_t *dip, dev_info_t *rdip, ddi_ctl_enum_t ctlop, void *arg, void *result) { _NOTE(ARGUNUSED(dip)) PMD_FUNC(pmf, "ctlops") power_req_t *reqp = (power_req_t *)arg; int retval; dev_info_t *target_dip; int new_level, old_level, cmpt; #ifdef DEBUG char *format; #endif /* * The interface for doing the actual power level changes is now * through the DDI_CTLOPS_POWER bus_ctl, so that we can plug in * different platform-specific power control drivers. * * This driver implements the "default" version of this interface. * If no ppm driver has been installed then this interface is called * instead. */ ASSERT(dip == NULL); switch (ctlop) { case DDI_CTLOPS_POWER: switch (reqp->request_type) { case PMR_PPM_SET_POWER: { target_dip = reqp->req.ppm_set_power_req.who; ASSERT(target_dip == rdip); new_level = reqp->req.ppm_set_power_req.new_level; cmpt = reqp->req.ppm_set_power_req.cmpt; /* pass back old power for the PM_LEVEL_UNKNOWN case */ old_level = PM_CURPOWER(target_dip, cmpt); reqp->req.ppm_set_power_req.old_level = old_level; retval = pm_power(target_dip, cmpt, new_level); PMD(PMD_PPM, ("%s: PPM_SET_POWER %s@%s(%s#%d)[%d] %d->" "%d %s\n", pmf, PM_DEVICE(target_dip), cmpt, old_level, new_level, (retval == DDI_SUCCESS ? "chd" : "no chg"))) return (retval); } case PMR_PPM_PRE_DETACH: case PMR_PPM_POST_DETACH: case PMR_PPM_PRE_ATTACH: case PMR_PPM_POST_ATTACH: case PMR_PPM_PRE_PROBE: case PMR_PPM_POST_PROBE: case PMR_PPM_PRE_RESUME: case PMR_PPM_INIT_CHILD: case PMR_PPM_UNINIT_CHILD: #ifdef DEBUG switch (reqp->request_type) { case PMR_PPM_PRE_DETACH: format = "%s: PMR_PPM_PRE_DETACH " "%s@%s(%s#%d)\n"; break; case PMR_PPM_POST_DETACH: format = "%s: PMR_PPM_POST_DETACH " "%s@%s(%s#%d) rets %d\n"; break; case PMR_PPM_PRE_ATTACH: format = "%s: PMR_PPM_PRE_ATTACH " "%s@%s(%s#%d)\n"; break; case PMR_PPM_POST_ATTACH: format = "%s: PMR_PPM_POST_ATTACH " "%s@%s(%s#%d) rets %d\n"; break; case PMR_PPM_PRE_PROBE: format = "%s: PMR_PPM_PRE_PROBE " "%s@%s(%s#%d)\n"; break; case PMR_PPM_POST_PROBE: format = "%s: PMR_PPM_POST_PROBE " "%s@%s(%s#%d) rets %d\n"; break; case PMR_PPM_PRE_RESUME: format = "%s: PMR_PPM_PRE_RESUME " "%s@%s(%s#%d) rets %d\n"; break; case PMR_PPM_INIT_CHILD: format = "%s: PMR_PPM_INIT_CHILD " "%s@%s(%s#%d)\n"; break; case PMR_PPM_UNINIT_CHILD: format = "%s: PMR_PPM_UNINIT_CHILD " "%s@%s(%s#%d)\n"; break; default: break; } PMD(PMD_PPM, (format, pmf, PM_DEVICE(rdip), reqp->req.ppm_config_req.result)) #endif return (DDI_SUCCESS); case PMR_PPM_POWER_CHANGE_NOTIFY: /* * Nothing for us to do */ ASSERT(reqp->req.ppm_notify_level_req.who == rdip); PMD(PMD_PPM, ("%s: PMR_PPM_POWER_CHANGE_NOTIFY " "%s@%s(%s#%d)[%d] %d->%d\n", pmf, PM_DEVICE(reqp->req.ppm_notify_level_req.who), reqp->req.ppm_notify_level_req.cmpt, PM_CURPOWER(reqp->req.ppm_notify_level_req.who, reqp->req.ppm_notify_level_req.cmpt), reqp->req.ppm_notify_level_req.new_level)) return (DDI_SUCCESS); case PMR_PPM_UNMANAGE: PMD(PMD_PPM, ("%s: PMR_PPM_UNMANAGE %s@%s(%s#%d)\n", pmf, PM_DEVICE(rdip))) return (DDI_SUCCESS); case PMR_PPM_LOCK_POWER: pm_lock_power_single(reqp->req.ppm_lock_power_req.who, reqp->req.ppm_lock_power_req.circp); return (DDI_SUCCESS); case PMR_PPM_UNLOCK_POWER: pm_unlock_power_single( reqp->req.ppm_unlock_power_req.who, reqp->req.ppm_unlock_power_req.circ); return (DDI_SUCCESS); case PMR_PPM_TRY_LOCK_POWER: *(int *)result = pm_try_locking_power_single( reqp->req.ppm_lock_power_req.who, reqp->req.ppm_lock_power_req.circp); return (DDI_SUCCESS); case PMR_PPM_POWER_LOCK_OWNER: target_dip = reqp->req.ppm_power_lock_owner_req.who; ASSERT(target_dip == rdip); reqp->req.ppm_power_lock_owner_req.owner = DEVI(rdip)->devi_busy_thread; return (DDI_SUCCESS); default: PMD(PMD_ERROR, ("%s: default!\n", pmf)) return (DDI_FAILURE); } default: PMD(PMD_ERROR, ("%s: unknown\n", pmf)) return (DDI_FAILURE); } } /* * We overload the bus_ctl ops here--perhaps we ought to have a distinct * power_ops struct for this functionality instead? * However, we only ever do this on a ppm driver. */ int pm_ctlops(dev_info_t *d, dev_info_t *r, ddi_ctl_enum_t op, void *a, void *v) { int (*fp)(); /* if no ppm handler, call the default routine */ if (d == NULL) { return (pm_default_ctlops(d, r, op, a, v)); } if (!d || !r) return (DDI_FAILURE); ASSERT(DEVI(d)->devi_ops && DEVI(d)->devi_ops->devo_bus_ops && DEVI(d)->devi_ops->devo_bus_ops->bus_ctl); fp = DEVI(d)->devi_ops->devo_bus_ops->bus_ctl; return ((*fp)(d, r, op, a, v)); } /* * Called on a node when attach completes or the driver makes its first pm * call (whichever comes first). * In the attach case, device may not be power manageable at all. * Don't need to lock the dip because we're single threaded by the devfs code */ static int pm_start(dev_info_t *dip) { PMD_FUNC(pmf, "start") int ret; dev_info_t *pdip = ddi_get_parent(dip); int e_pm_manage(dev_info_t *, int); void pm_noinvol_specd(dev_info_t *dip); e_pm_props(dip); pm_noinvol_specd(dip); /* * If this dip has already been processed, don't mess with it * (but decrement the speculative count we did above, as whatever * code put it under pm already will have dealt with it) */ if (PM_GET_PM_INFO(dip)) { PMD(PMD_KIDSUP, ("%s: pm already done for %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) return (0); } ret = e_pm_manage(dip, PM_STYLE_UNKNOWN); if (PM_GET_PM_INFO(dip) == NULL) { /* * keep the kidsupcount increment as is */ DEVI(dip)->devi_pm_flags |= PMC_NOPMKID; if (pdip && !PM_WANTS_NOTIFICATION(pdip)) { pm_hold_power(pdip); } else if (pdip && MDI_VHCI(pdip) && MDI_CLIENT(dip)) { (void) mdi_power(pdip, MDI_PM_HOLD_POWER, (void *)dip, NULL, 0); } PMD(PMD_KIDSUP, ("%s: pm of %s@%s(%s#%d) failed, parent " "left up\n", pmf, PM_DEVICE(dip))) } return (ret); } /* * Keep a list of recorded thresholds. For now we just keep a list and * search it linearly. We don't expect too many entries. Can always hash it * later if we need to. */ void pm_record_thresh(pm_thresh_rec_t *rp) { pm_thresh_rec_t *pptr, *ptr; ASSERT(*rp->ptr_physpath); rw_enter(&pm_thresh_rwlock, RW_WRITER); for (pptr = NULL, ptr = pm_thresh_head; ptr; pptr = ptr, ptr = ptr->ptr_next) { if (strcmp(rp->ptr_physpath, ptr->ptr_physpath) == 0) { /* replace this one */ rp->ptr_next = ptr->ptr_next; if (pptr) { pptr->ptr_next = rp; } else { pm_thresh_head = rp; } rw_exit(&pm_thresh_rwlock); kmem_free(ptr, ptr->ptr_size); return; } continue; } /* * There was not a match in the list, insert this one in front */ if (pm_thresh_head) { rp->ptr_next = pm_thresh_head; pm_thresh_head = rp; } else { rp->ptr_next = NULL; pm_thresh_head = rp; } rw_exit(&pm_thresh_rwlock); } /* * Create a new dependency record and hang a new dependency entry off of it */ pm_pdr_t * newpdr(char *kept, char *keeps, int isprop) { size_t size = strlen(kept) + strlen(keeps) + 2 + sizeof (pm_pdr_t); pm_pdr_t *p = kmem_zalloc(size, KM_SLEEP); p->pdr_size = size; p->pdr_isprop = isprop; p->pdr_kept_paths = NULL; p->pdr_kept_count = 0; p->pdr_kept = (char *)((intptr_t)p + sizeof (pm_pdr_t)); (void) strcpy(p->pdr_kept, kept); p->pdr_keeper = (char *)((intptr_t)p->pdr_kept + strlen(kept) + 1); (void) strcpy(p->pdr_keeper, keeps); ASSERT((intptr_t)p->pdr_keeper + strlen(p->pdr_keeper) + 1 <= (intptr_t)p + size); ASSERT((intptr_t)p->pdr_kept + strlen(p->pdr_kept) + 1 <= (intptr_t)p + size); return (p); } /* * Keep a list of recorded dependencies. We only keep the * keeper -> kept list for simplification. At this point We do not * care about whether the devices are attached or not yet, * this would be done in pm_keeper() and pm_kept(). * If a PM_RESET_PM happens, then we tear down and forget the dependencies, * and it is up to the user to issue the ioctl again if they want it * (e.g. pmconfig) * Returns true if dependency already exists in the list. */ int pm_record_keeper(char *kept, char *keeper, int isprop) { PMD_FUNC(pmf, "record_keeper") pm_pdr_t *npdr, *ppdr, *pdr; PMD(PMD_KEEPS, ("%s: %s, %s\n", pmf, kept, keeper)) ASSERT(kept && keeper); #ifdef DEBUG if (pm_debug & PMD_KEEPS) prdeps("pm_record_keeper entry"); #endif for (ppdr = NULL, pdr = pm_dep_head; pdr; ppdr = pdr, pdr = pdr->pdr_next) { PMD(PMD_KEEPS, ("%s: check %s, %s\n", pmf, pdr->pdr_kept, pdr->pdr_keeper)) if (strcmp(kept, pdr->pdr_kept) == 0 && strcmp(keeper, pdr->pdr_keeper) == 0) { PMD(PMD_KEEPS, ("%s: match\n", pmf)) return (1); } } /* * We did not find any match, so we have to make an entry */ npdr = newpdr(kept, keeper, isprop); if (ppdr) { ASSERT(ppdr->pdr_next == NULL); ppdr->pdr_next = npdr; } else { ASSERT(pm_dep_head == NULL); pm_dep_head = npdr; } #ifdef DEBUG if (pm_debug & PMD_KEEPS) prdeps("pm_record_keeper after new record"); #endif if (!isprop) pm_unresolved_deps++; else pm_prop_deps++; return (0); } /* * Look up this device in the set of devices we've seen ioctls for * to see if we are holding a threshold spec for it. If so, make it so. * At ioctl time, we were given the physical path of the device. */ int pm_thresh_specd(dev_info_t *dip) { void pm_apply_recorded_thresh(dev_info_t *, pm_thresh_rec_t *); char *path = 0; char pathbuf[MAXNAMELEN]; pm_thresh_rec_t *rp; path = ddi_pathname(dip, pathbuf); rw_enter(&pm_thresh_rwlock, RW_READER); for (rp = pm_thresh_head; rp; rp = rp->ptr_next) { if (strcmp(rp->ptr_physpath, path) != 0) continue; pm_apply_recorded_thresh(dip, rp); rw_exit(&pm_thresh_rwlock); return (1); } rw_exit(&pm_thresh_rwlock); return (0); } static int pm_set_keeping(dev_info_t *keeper, dev_info_t *kept) { PMD_FUNC(pmf, "set_keeping") pm_info_t *kept_info; int j, up = 0, circ; void prdeps(char *); PMD(PMD_KEEPS, ("%s: keeper=%s@%s(%s#%d), kept=%s@%s(%s#%d)\n", pmf, PM_DEVICE(keeper), PM_DEVICE(kept))) #ifdef DEBUG if (pm_debug & PMD_KEEPS) prdeps("Before PAD\n"); #endif ASSERT(keeper != kept); if (PM_GET_PM_INFO(keeper) == NULL) { cmn_err(CE_CONT, "!device %s@%s(%s#%d) keeps up device " "%s@%s(%s#%d), but the latter is not power managed", PM_DEVICE(keeper), PM_DEVICE(kept)); PMD((PMD_FAIL | PMD_KEEPS), ("%s: keeper %s@%s(%s#%d) is not" "power managed\n", pmf, PM_DEVICE(keeper))) return (0); } kept_info = PM_GET_PM_INFO(kept); ASSERT(kept_info); PM_LOCK_POWER(keeper, &circ); for (j = 0; j < PM_NUMCMPTS(keeper); j++) { if (PM_CURPOWER(keeper, j)) { up++; break; } } if (up) { /* Bringup and maintain a hold on the kept */ PMD(PMD_KEEPS, ("%s: place a hold on kept %s@%s(%s#%d)\n", pmf, PM_DEVICE(kept))) bring_pmdep_up(kept, 1); } PM_UNLOCK_POWER(keeper, circ); #ifdef DEBUG if (pm_debug & PMD_KEEPS) prdeps("After PAD\n"); #endif return (1); } /* * Should this device keep up another device? * Look up this device in the set of devices we've seen ioctls for * to see if we are holding a dependency spec for it. If so, make it so. * Because we require the kept device to be attached already in order to * make the list entry (and hold it), we only need to look for keepers. * At ioctl time, we were given the physical path of the device. */ int pm_keeper(char *keeper) { PMD_FUNC(pmf, "keeper") int pm_apply_recorded_dep(dev_info_t *, pm_pdr_t *); dev_info_t *dip; pm_pdr_t *dp; dev_info_t *kept = NULL; int ret = 0; int i; if (!pm_unresolved_deps && !pm_prop_deps) return (0); ASSERT(keeper != NULL); dip = pm_name_to_dip(keeper, 1); if (dip == NULL) return (0); PMD(PMD_KEEPS, ("%s: keeper=%s\n", pmf, keeper)) for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (!dp->pdr_isprop) { if (!pm_unresolved_deps) continue; PMD(PMD_KEEPS, ("%s: keeper %s\n", pmf, dp->pdr_keeper)) if (dp->pdr_satisfied) { PMD(PMD_KEEPS, ("%s: satisfied\n", pmf)) continue; } if (strcmp(dp->pdr_keeper, keeper) == 0) { ret += pm_apply_recorded_dep(dip, dp); } } else { if (strcmp(dp->pdr_keeper, keeper) != 0) continue; for (i = 0; i < dp->pdr_kept_count; i++) { if (dp->pdr_kept_paths[i] == NULL) continue; kept = pm_name_to_dip(dp->pdr_kept_paths[i], 1); if (kept == NULL) continue; ASSERT(ddi_prop_exists(DDI_DEV_T_ANY, kept, DDI_PROP_DONTPASS, dp->pdr_kept)); PMD(PMD_KEEPS, ("%s: keeper=%s@%s(%s#%d), " "kept=%s@%s(%s#%d) keptcnt=%d\n", pmf, PM_DEVICE(dip), PM_DEVICE(kept), dp->pdr_kept_count)) if (kept != dip) { ret += pm_set_keeping(dip, kept); } ddi_release_devi(kept); } } } ddi_release_devi(dip); return (ret); } /* * Should this device be kept up by another device? * Look up all dependency recorded from PM_ADD_DEPENDENT and * PM_ADD_DEPENDENT_PROPERTY ioctls. Record down on the keeper's * kept device lists. */ static int pm_kept(char *keptp) { PMD_FUNC(pmf, "kept") pm_pdr_t *dp; int found = 0; int ret = 0; dev_info_t *keeper; dev_info_t *kept; size_t length; int i; char **paths; char *path; ASSERT(keptp != NULL); kept = pm_name_to_dip(keptp, 1); if (kept == NULL) return (0); PMD(PMD_KEEPS, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(kept))) for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (dp->pdr_isprop) { PMD(PMD_KEEPS, ("%s: property %s\n", pmf, dp->pdr_kept)) if (ddi_prop_exists(DDI_DEV_T_ANY, kept, DDI_PROP_DONTPASS, dp->pdr_kept)) { /* * Dont allow self dependency. */ if (strcmp(dp->pdr_keeper, keptp) == 0) continue; keeper = pm_name_to_dip(dp->pdr_keeper, 1); if (keeper == NULL) continue; PMD(PMD_KEEPS, ("%s: adding to kepts path list " "%p\n", pmf, (void *)kept)) #ifdef DEBUG if (pm_debug & PMD_DEP) prdeps("Before Adding from pm_kept\n"); #endif /* * Add ourselves to the dip list. */ if (dp->pdr_kept_count == 0) { length = strlen(keptp) + 1; path = kmem_alloc(length, KM_SLEEP); paths = kmem_alloc(sizeof (char **), KM_SLEEP); (void) strcpy(path, keptp); paths[0] = path; dp->pdr_kept_paths = paths; dp->pdr_kept_count++; } else { /* Check to see if already on list */ for (i = 0; i < dp->pdr_kept_count; i++) { if (strcmp(keptp, dp->pdr_kept_paths[i]) == 0) { found++; break; } } if (found) { ddi_release_devi(keeper); continue; } length = dp->pdr_kept_count * sizeof (char **); paths = kmem_alloc( length + sizeof (char **), KM_SLEEP); if (dp->pdr_kept_count) { bcopy(dp->pdr_kept_paths, paths, length); kmem_free(dp->pdr_kept_paths, length); } dp->pdr_kept_paths = paths; length = strlen(keptp) + 1; path = kmem_alloc(length, KM_SLEEP); (void) strcpy(path, keptp); dp->pdr_kept_paths[i] = path; dp->pdr_kept_count++; } #ifdef DEBUG if (pm_debug & PMD_DEP) prdeps("After from pm_kept\n"); #endif if (keeper) { ret += pm_set_keeping(keeper, kept); ddi_release_devi(keeper); } } } else { /* * pm_keeper would be called later to do * the actual pm_set_keeping. */ PMD(PMD_KEEPS, ("%s: adding to kepts path list %p\n", pmf, (void *)kept)) #ifdef DEBUG if (pm_debug & PMD_DEP) prdeps("Before Adding from pm_kept\n"); #endif if (strcmp(keptp, dp->pdr_kept) == 0) { if (dp->pdr_kept_paths == NULL) { length = strlen(keptp) + 1; path = kmem_alloc(length, KM_SLEEP); paths = kmem_alloc(sizeof (char **), KM_SLEEP); (void) strcpy(path, keptp); paths[0] = path; dp->pdr_kept_paths = paths; dp->pdr_kept_count++; } } #ifdef DEBUG if (pm_debug & PMD_DEP) prdeps("After from pm_kept\n"); #endif } } ddi_release_devi(kept); return (ret); } /* * Apply a recorded dependency. dp specifies the dependency, and * keeper is already known to be the device that keeps up the other (kept) one. * We have to the whole tree for the "kept" device, then apply * the dependency (which may already be applied). */ int pm_apply_recorded_dep(dev_info_t *keeper, pm_pdr_t *dp) { PMD_FUNC(pmf, "apply_recorded_dep") dev_info_t *kept = NULL; int ret = 0; char *keptp = NULL; /* * Device to Device dependency can only be 1 to 1. */ if (dp->pdr_kept_paths == NULL) return (0); keptp = dp->pdr_kept_paths[0]; if (keptp == NULL) return (0); ASSERT(*keptp != '\0'); kept = pm_name_to_dip(keptp, 1); if (kept == NULL) return (0); if (kept) { PMD(PMD_KEEPS, ("%s: keeper=%s, kept=%s\n", pmf, dp->pdr_keeper, keptp)) if (pm_set_keeping(keeper, kept)) { ASSERT(dp->pdr_satisfied == 0); dp->pdr_satisfied = 1; ASSERT(pm_unresolved_deps); pm_unresolved_deps--; ret++; } } ddi_release_devi(kept); return (ret); } /* * Called from common/io/pm.c */ int pm_cur_power(pm_component_t *cp) { return (cur_power(cp)); } /* * External interface to sanity-check a power level. */ int pm_valid_power(dev_info_t *dip, int comp, int level) { PMD_FUNC(pmf, "valid_power") if (comp >= 0 && comp < PM_NUMCMPTS(dip) && level >= 0) return (e_pm_valid_power(dip, comp, level)); else { PMD(PMD_FAIL, ("%s: comp=%d, ncomp=%d, level=%d\n", pmf, comp, PM_NUMCMPTS(dip), level)) return (0); } } /* * Called when a device that is direct power managed needs to change state. * This routine arranges to block the request until the process managing * the device makes the change (or some other incompatible change) or * the process closes /dev/pm. */ static int pm_block(dev_info_t *dip, int comp, int newpower, int oldpower) { pm_rsvp_t *new = kmem_zalloc(sizeof (*new), KM_SLEEP); int ret = 0; void pm_dequeue_blocked(pm_rsvp_t *); void pm_enqueue_blocked(pm_rsvp_t *); ASSERT(!pm_processes_stopped); ASSERT(PM_IAM_LOCKING_DIP(dip)); new->pr_dip = dip; new->pr_comp = comp; new->pr_newlevel = newpower; new->pr_oldlevel = oldpower; cv_init(&new->pr_cv, NULL, CV_DEFAULT, NULL); mutex_enter(&pm_rsvp_lock); pm_enqueue_blocked(new); pm_enqueue_notify(PSC_PENDING_CHANGE, dip, comp, newpower, oldpower, PM_CANBLOCK_BLOCK); PM_UNLOCK_DIP(dip); /* * truss may make the cv_wait_sig return prematurely */ while (ret == 0) { /* * Normally there will be no user context involved, but if * there is (e.g. we are here via an ioctl call to a driver) * then we should allow the process to abort the request, * or we get an unkillable process if the same thread does * PM_DIRECT_PM and pm_raise_power */ if (cv_wait_sig(&new->pr_cv, &pm_rsvp_lock) == 0) { ret = PMP_FAIL; } else { ret = new->pr_retval; } } pm_dequeue_blocked(new); mutex_exit(&pm_rsvp_lock); cv_destroy(&new->pr_cv); kmem_free(new, sizeof (*new)); return (ret); } /* * Returns true if the process is interested in power level changes (has issued * PM_GET_STATE_CHANGE ioctl). */ int pm_interest_registered(int clone) { ASSERT(clone >= 0 && clone < PM_MAX_CLONE - 1); return (pm_interest[clone]); } /* * Process with clone has just done PM_DIRECT_PM on dip, or has asked to * watch all state transitions (dip == NULL). Set up data * structs to communicate with process about state changes. */ void pm_register_watcher(int clone, dev_info_t *dip) { pscc_t *p; psce_t *psce; static void pm_enqueue_pscc(pscc_t *, pscc_t **); /* * We definitely need a control struct, then we have to search to see * there is already an entries struct (in the dip != NULL case). */ pscc_t *pscc = kmem_zalloc(sizeof (*pscc), KM_SLEEP); pscc->pscc_clone = clone; pscc->pscc_dip = dip; if (dip) { int found = 0; rw_enter(&pm_pscc_direct_rwlock, RW_WRITER); for (p = pm_pscc_direct; p; p = p->pscc_next) { /* * Already an entry for this clone, so just use it * for the new one (for the case where a single * process is watching multiple devices) */ if (p->pscc_clone == clone) { ASSERT(p->pscc_dip != dip); pscc->pscc_entries = p->pscc_entries; pscc->pscc_entries->psce_references++; found++; } } if (!found) { /* create a new one */ psce = kmem_zalloc(sizeof (psce_t), KM_SLEEP); mutex_init(&psce->psce_lock, NULL, MUTEX_DEFAULT, NULL); psce->psce_first = kmem_zalloc(sizeof (pm_state_change_t) * PSCCOUNT, KM_SLEEP); psce->psce_in = psce->psce_out = psce->psce_first; psce->psce_last = &psce->psce_first[PSCCOUNT - 1]; psce->psce_references = 1; pscc->pscc_entries = psce; } pm_enqueue_pscc(pscc, &pm_pscc_direct); rw_exit(&pm_pscc_direct_rwlock); } else { ASSERT(!pm_interest_registered(clone)); rw_enter(&pm_pscc_interest_rwlock, RW_WRITER); #ifdef DEBUG for (p = pm_pscc_interest; p; p = p->pscc_next) { /* * Should not be an entry for this clone! */ ASSERT(p->pscc_clone != clone); } #endif psce = kmem_zalloc(sizeof (psce_t), KM_SLEEP); psce->psce_first = kmem_zalloc(sizeof (pm_state_change_t) * PSCCOUNT, KM_SLEEP); psce->psce_in = psce->psce_out = psce->psce_first; psce->psce_last = &psce->psce_first[PSCCOUNT - 1]; psce->psce_references = 1; pscc->pscc_entries = psce; pm_enqueue_pscc(pscc, &pm_pscc_interest); pm_interest[clone] = 1; rw_exit(&pm_pscc_interest_rwlock); } } /* * Remove the given entry from the blocked list */ void pm_dequeue_blocked(pm_rsvp_t *p) { ASSERT(MUTEX_HELD(&pm_rsvp_lock)); if (pm_blocked_list == p) { ASSERT(p->pr_prev == NULL); if (p->pr_next != NULL) p->pr_next->pr_prev = NULL; pm_blocked_list = p->pr_next; } else { ASSERT(p->pr_prev != NULL); p->pr_prev->pr_next = p->pr_next; if (p->pr_next != NULL) p->pr_next->pr_prev = p->pr_prev; } } /* * Remove the given control struct from the given list */ static void pm_dequeue_pscc(pscc_t *p, pscc_t **list) { if (*list == p) { ASSERT(p->pscc_prev == NULL); if (p->pscc_next != NULL) p->pscc_next->pscc_prev = NULL; *list = p->pscc_next; } else { ASSERT(p->pscc_prev != NULL); p->pscc_prev->pscc_next = p->pscc_next; if (p->pscc_next != NULL) p->pscc_next->pscc_prev = p->pscc_prev; } } /* * Stick the control struct specified on the front of the list */ static void pm_enqueue_pscc(pscc_t *p, pscc_t **list) { pscc_t *h; /* entry at head of list */ if ((h = *list) == NULL) { *list = p; ASSERT(p->pscc_next == NULL); ASSERT(p->pscc_prev == NULL); } else { p->pscc_next = h; ASSERT(h->pscc_prev == NULL); h->pscc_prev = p; ASSERT(p->pscc_prev == NULL); *list = p; } } /* * If dip is NULL, process is closing "clone" clean up all its registrations. * Otherwise only clean up those for dip because process is just giving up * control of a direct device. */ void pm_deregister_watcher(int clone, dev_info_t *dip) { pscc_t *p, *pn; psce_t *psce; int found = 0; if (dip == NULL) { rw_enter(&pm_pscc_interest_rwlock, RW_WRITER); for (p = pm_pscc_interest; p; p = pn) { pn = p->pscc_next; if (p->pscc_clone == clone) { pm_dequeue_pscc(p, &pm_pscc_interest); psce = p->pscc_entries; ASSERT(psce->psce_references == 1); mutex_destroy(&psce->psce_lock); kmem_free(psce->psce_first, sizeof (pm_state_change_t) * PSCCOUNT); kmem_free(psce, sizeof (*psce)); kmem_free(p, sizeof (*p)); } } pm_interest[clone] = 0; rw_exit(&pm_pscc_interest_rwlock); } found = 0; rw_enter(&pm_pscc_direct_rwlock, RW_WRITER); for (p = pm_pscc_direct; p; p = pn) { pn = p->pscc_next; if ((dip && p->pscc_dip == dip) || (dip == NULL && clone == p->pscc_clone)) { ASSERT(clone == p->pscc_clone); found++; /* * Remove from control list */ pm_dequeue_pscc(p, &pm_pscc_direct); /* * If we're the last reference, free the * entries struct. */ psce = p->pscc_entries; ASSERT(psce); if (psce->psce_references == 1) { kmem_free(psce->psce_first, PSCCOUNT * sizeof (pm_state_change_t)); kmem_free(psce, sizeof (*psce)); } else { psce->psce_references--; } kmem_free(p, sizeof (*p)); } } ASSERT(dip == NULL || found); rw_exit(&pm_pscc_direct_rwlock); } /* * Search the indicated list for an entry that matches clone, and return a * pointer to it. To be interesting, the entry must have something ready to * be passed up to the controlling process. * The returned entry will be locked upon return from this call. */ static psce_t * pm_psc_find_clone(int clone, pscc_t **list, krwlock_t *lock) { pscc_t *p; psce_t *psce; rw_enter(lock, RW_READER); for (p = *list; p; p = p->pscc_next) { if (clone == p->pscc_clone) { psce = p->pscc_entries; mutex_enter(&psce->psce_lock); if (psce->psce_out->size) { rw_exit(lock); return (psce); } else { mutex_exit(&psce->psce_lock); } } } rw_exit(lock); return (NULL); } /* * Find an entry for a particular clone in the direct list. */ psce_t * pm_psc_clone_to_direct(int clone) { static psce_t *pm_psc_find_clone(int, pscc_t **, krwlock_t *); return (pm_psc_find_clone(clone, &pm_pscc_direct, &pm_pscc_direct_rwlock)); } /* * Find an entry for a particular clone in the interest list. */ psce_t * pm_psc_clone_to_interest(int clone) { static psce_t *pm_psc_find_clone(int, pscc_t **, krwlock_t *); return (pm_psc_find_clone(clone, &pm_pscc_interest, &pm_pscc_interest_rwlock)); } /* * Put the given entry at the head of the blocked list */ void pm_enqueue_blocked(pm_rsvp_t *p) { ASSERT(MUTEX_HELD(&pm_rsvp_lock)); ASSERT(p->pr_next == NULL); ASSERT(p->pr_prev == NULL); if (pm_blocked_list != NULL) { p->pr_next = pm_blocked_list; ASSERT(pm_blocked_list->pr_prev == NULL); pm_blocked_list->pr_prev = p; pm_blocked_list = p; } else { pm_blocked_list = p; } } /* * Sets every power managed device back to its default threshold */ void pm_all_to_default_thresholds(void) { ddi_walk_devs(ddi_root_node(), pm_set_dev_thr_walk, (void *) &pm_system_idle_threshold); } static int pm_set_dev_thr_walk(dev_info_t *dip, void *arg) { int thr = (int)(*(int *)arg); if (!PM_GET_PM_INFO(dip)) return (DDI_WALK_CONTINUE); pm_set_device_threshold(dip, thr, PMC_DEF_THRESH); return (DDI_WALK_CONTINUE); } /* * Returns the current threshold value (in seconds) for the indicated component */ int pm_current_threshold(dev_info_t *dip, int comp, int *threshp) { if (comp < 0 || comp >= PM_NUMCMPTS(dip)) { return (DDI_FAILURE); } else { *threshp = cur_threshold(dip, comp); return (DDI_SUCCESS); } } /* * To be called when changing the power level of a component of a device. * On some platforms, changing power on one device may require that power * be changed on other, related devices in the same transaction. Thus, we * always pass this request to the platform power manager so that all the * affected devices will be locked. */ void pm_lock_power(dev_info_t *dip, int *circp) { power_req_t power_req; int result; power_req.request_type = PMR_PPM_LOCK_POWER; power_req.req.ppm_lock_power_req.who = dip; power_req.req.ppm_lock_power_req.circp = circp; (void) pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); } /* * Release the lock (or locks) acquired to change the power of a device. * See comments for pm_lock_power. */ void pm_unlock_power(dev_info_t *dip, int circ) { power_req_t power_req; int result; power_req.request_type = PMR_PPM_UNLOCK_POWER; power_req.req.ppm_unlock_power_req.who = dip; power_req.req.ppm_unlock_power_req.circ = circ; (void) pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); } /* * Attempt (without blocking) to acquire the lock(s) needed to change the * power of a component of a device. See comments for pm_lock_power. * * Return: 1 if lock(s) acquired, 0 if not. */ int pm_try_locking_power(dev_info_t *dip, int *circp) { power_req_t power_req; int result; power_req.request_type = PMR_PPM_TRY_LOCK_POWER; power_req.req.ppm_lock_power_req.who = dip; power_req.req.ppm_lock_power_req.circp = circp; (void) pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); return (result); } /* * Lock power state of a device. * * The implementation handles a special case where another thread may have * acquired the lock and created/launched this thread to do the work. If * the lock cannot be acquired immediately, we check to see if this thread * is registered as a borrower of the lock. If so, we may proceed without * the lock. This assumes that the lending thread blocks on the completion * of this thread. * * Note 1: for use by ppm only. * * Note 2: On failing to get the lock immediately, we search lock_loan list * for curthread (as borrower of the lock). On a hit, we check that the * lending thread already owns the lock we want. It is safe to compare * devi_busy_thread and thread id of the lender because in the == case (the * only one we care about) we know that the owner is blocked. Similarly, * If we find that curthread isn't registered as a lock borrower, it is safe * to use the blocking call (ndi_devi_enter) because we know that if we * weren't already listed as a borrower (upstream on the call stack) we won't * become one. */ void pm_lock_power_single(dev_info_t *dip, int *circp) { lock_loan_t *cur; /* if the lock is available, we are done. */ if (ndi_devi_tryenter(dip, circp)) return; mutex_enter(&pm_loan_lock); /* see if our thread is registered as a lock borrower. */ for (cur = lock_loan_head.pmlk_next; cur; cur = cur->pmlk_next) if (cur->pmlk_borrower == curthread) break; mutex_exit(&pm_loan_lock); /* if this thread not already registered, it is safe to block */ if (cur == NULL) ndi_devi_enter(dip, circp); else { /* registered: does lender own the lock we want? */ if (cur->pmlk_lender == DEVI(dip)->devi_busy_thread) { ASSERT(cur->pmlk_dip == NULL || cur->pmlk_dip == dip); cur->pmlk_dip = dip; } else /* no: just block for it */ ndi_devi_enter(dip, circp); } } /* * Drop the lock on the device's power state. See comment for * pm_lock_power_single() for special implementation considerations. * * Note: for use by ppm only. */ void pm_unlock_power_single(dev_info_t *dip, int circ) { lock_loan_t *cur; /* optimization: mutex not needed to check empty list */ if (lock_loan_head.pmlk_next == NULL) { ndi_devi_exit(dip, circ); return; } mutex_enter(&pm_loan_lock); /* see if our thread is registered as a lock borrower. */ for (cur = lock_loan_head.pmlk_next; cur; cur = cur->pmlk_next) if (cur->pmlk_borrower == curthread) break; mutex_exit(&pm_loan_lock); if (cur == NULL || cur->pmlk_dip != dip) /* we acquired the lock directly, so return it */ ndi_devi_exit(dip, circ); } /* * Try to take the lock for changing the power level of a component. * * Note: for use by ppm only. */ int pm_try_locking_power_single(dev_info_t *dip, int *circp) { return (ndi_devi_tryenter(dip, circp)); } #ifdef DEBUG /* * The following are used only to print out data structures for debugging */ void prdeps(char *msg) { pm_pdr_t *rp; int i; pm_log("pm_dep_head %s %p\n", msg, (void *)pm_dep_head); for (rp = pm_dep_head; rp; rp = rp->pdr_next) { pm_log("%p: %s keeper %s, kept %s, kept count %d, next %p\n", (void *)rp, (rp->pdr_isprop ? "property" : "device"), rp->pdr_keeper, rp->pdr_kept, rp->pdr_kept_count, (void *)rp->pdr_next); if (rp->pdr_kept_count != 0) { pm_log("kept list = "); i = 0; while (i < rp->pdr_kept_count) { pm_log("%s ", rp->pdr_kept_paths[i]); i++; } pm_log("\n"); } } } void pr_noinvol(char *hdr) { pm_noinvol_t *ip; pm_log("%s\n", hdr); rw_enter(&pm_noinvol_rwlock, RW_READER); for (ip = pm_noinvol_head; ip; ip = ip->ni_next) pm_log("\tmaj %d, flags %x, noinvolpm %d %s\n", ip->ni_major, ip->ni_flags, ip->ni_noinvolpm, ip->ni_path); rw_exit(&pm_noinvol_rwlock); } #endif /* * Attempt to apply the thresholds indicated by rp to the node specified by * dip. */ void pm_apply_recorded_thresh(dev_info_t *dip, pm_thresh_rec_t *rp) { PMD_FUNC(pmf, "apply_recorded_thresh") int i, j; int comps = PM_NUMCMPTS(dip); struct pm_component *cp; pm_pte_t *ep; int pm_valid_thresh(dev_info_t *, pm_thresh_rec_t *); PMD(PMD_THRESH, ("%s: part: %s@%s(%s#%d), rp %p, %s\n", pmf, PM_DEVICE(dip), (void *)rp, rp->ptr_physpath)) PM_LOCK_DIP(dip); if (!PM_GET_PM_INFO(dip) || PM_ISBC(dip) || !pm_valid_thresh(dip, rp)) { PMD(PMD_FAIL, ("%s: part: %s@%s(%s#%d) PM_GET_PM_INFO %p\n", pmf, PM_DEVICE(dip), (void*)PM_GET_PM_INFO(dip))) PMD(PMD_FAIL, ("%s: part: %s@%s(%s#%d) PM_ISBC %d\n", pmf, PM_DEVICE(dip), PM_ISBC(dip))) PMD(PMD_FAIL, ("%s: part: %s@%s(%s#%d) pm_valid_thresh %d\n", pmf, PM_DEVICE(dip), pm_valid_thresh(dip, rp))) PM_UNLOCK_DIP(dip); return; } ep = rp->ptr_entries; /* * Here we do the special case of a device threshold */ if (rp->ptr_numcomps == 0) { /* PM_SET_DEVICE_THRESHOLD product */ ASSERT(ep && ep->pte_numthresh == 1); PMD(PMD_THRESH, ("%s: set dev thr %s@%s(%s#%d) to 0x%x\n", pmf, PM_DEVICE(dip), ep->pte_thresh[0])) PM_UNLOCK_DIP(dip); pm_set_device_threshold(dip, ep->pte_thresh[0], PMC_DEV_THRESH); if (PM_SCANABLE(dip)) pm_rescan(dip); return; } for (i = 0; i < comps; i++) { cp = PM_CP(dip, i); for (j = 0; j < ep->pte_numthresh; j++) { PMD(PMD_THRESH, ("%s: set thr %d for %s@%s(%s#%d)[%d] " "to %x\n", pmf, j, PM_DEVICE(dip), i, ep->pte_thresh[j])) cp->pmc_comp.pmc_thresh[j + 1] = ep->pte_thresh[j]; } ep++; } DEVI(dip)->devi_pm_flags &= PMC_THRESH_NONE; DEVI(dip)->devi_pm_flags |= PMC_COMP_THRESH; PM_UNLOCK_DIP(dip); if (PM_SCANABLE(dip)) pm_rescan(dip); } /* * Returns true if the threshold specified by rp could be applied to dip * (that is, the number of components and transitions are the same) */ int pm_valid_thresh(dev_info_t *dip, pm_thresh_rec_t *rp) { PMD_FUNC(pmf, "valid_thresh") int comps, i; pm_component_t *cp; pm_pte_t *ep; if (!PM_GET_PM_INFO(dip) || PM_ISBC(dip)) { PMD(PMD_ERROR, ("%s: %s: no pm_info or BC\n", pmf, rp->ptr_physpath)) return (0); } /* * Special case: we represent the PM_SET_DEVICE_THRESHOLD case by * an entry with numcomps == 0, (since we don't know how many * components there are in advance). This is always a valid * spec. */ if (rp->ptr_numcomps == 0) { ASSERT(rp->ptr_entries && rp->ptr_entries->pte_numthresh == 1); return (1); } if (rp->ptr_numcomps != (comps = PM_NUMCMPTS(dip))) { PMD(PMD_ERROR, ("%s: comp # mm (dip %d cmd %d) for %s\n", pmf, PM_NUMCMPTS(dip), rp->ptr_numcomps, rp->ptr_physpath)) return (0); } ep = rp->ptr_entries; for (i = 0; i < comps; i++) { cp = PM_CP(dip, i); if ((ep + i)->pte_numthresh != cp->pmc_comp.pmc_numlevels - 1) { PMD(PMD_ERROR, ("%s: %s[%d]: thresh=%d, record=%d\n", pmf, rp->ptr_physpath, i, cp->pmc_comp.pmc_numlevels - 1, (ep + i)->pte_numthresh)) return (0); } } return (1); } /* * Remove any recorded threshold for device physpath * We know there will be at most one. */ void pm_unrecord_threshold(char *physpath) { pm_thresh_rec_t *pptr, *ptr; rw_enter(&pm_thresh_rwlock, RW_WRITER); for (pptr = NULL, ptr = pm_thresh_head; ptr; ptr = ptr->ptr_next) { if (strcmp(physpath, ptr->ptr_physpath) == 0) { if (pptr) { pptr->ptr_next = ptr->ptr_next; } else { ASSERT(pm_thresh_head == ptr); pm_thresh_head = ptr->ptr_next; } kmem_free(ptr, ptr->ptr_size); break; } pptr = ptr; } rw_exit(&pm_thresh_rwlock); } /* * Discard all recorded thresholds. We are returning to the default pm state. */ void pm_discard_thresholds(void) { pm_thresh_rec_t *rp; rw_enter(&pm_thresh_rwlock, RW_WRITER); while (pm_thresh_head) { rp = pm_thresh_head; pm_thresh_head = rp->ptr_next; kmem_free(rp, rp->ptr_size); } rw_exit(&pm_thresh_rwlock); } /* * Discard all recorded dependencies. We are returning to the default pm state. */ void pm_discard_dependencies(void) { pm_pdr_t *rp; int i; size_t length; #ifdef DEBUG if (pm_debug & PMD_DEP) prdeps("Before discard\n"); #endif ddi_walk_devs(ddi_root_node(), pm_discard_dep_walk, NULL); #ifdef DEBUG if (pm_debug & PMD_DEP) prdeps("After discard\n"); #endif while (pm_dep_head) { rp = pm_dep_head; if (!rp->pdr_isprop) { ASSERT(rp->pdr_satisfied == 0); ASSERT(pm_unresolved_deps); pm_unresolved_deps--; } else { ASSERT(pm_prop_deps); pm_prop_deps--; } pm_dep_head = rp->pdr_next; if (rp->pdr_kept_count) { for (i = 0; i < rp->pdr_kept_count; i++) { length = strlen(rp->pdr_kept_paths[i]) + 1; kmem_free(rp->pdr_kept_paths[i], length); } kmem_free(rp->pdr_kept_paths, rp->pdr_kept_count * sizeof (char **)); } kmem_free(rp, rp->pdr_size); } } static int pm_discard_dep_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) char *pathbuf; if (PM_GET_PM_INFO(dip) == NULL) return (DDI_WALK_CONTINUE); pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); pm_free_keeper(pathbuf, 0); kmem_free(pathbuf, MAXPATHLEN); return (DDI_WALK_CONTINUE); } static int pm_kept_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) char *pathbuf; pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); (void) pm_kept(pathbuf); kmem_free(pathbuf, MAXPATHLEN); return (DDI_WALK_CONTINUE); } static int pm_keeper_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) char *pathbuf; pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); (void) pm_keeper(pathbuf); kmem_free(pathbuf, MAXPATHLEN); return (DDI_WALK_CONTINUE); } static char * pdw_type_decode(int type) { switch (type) { case PM_DEP_WK_POWER_ON: return ("power on"); case PM_DEP_WK_POWER_OFF: return ("power off"); case PM_DEP_WK_DETACH: return ("detach"); case PM_DEP_WK_REMOVE_DEP: return ("remove dep"); case PM_DEP_WK_BRINGUP_SELF: return ("bringup self"); case PM_DEP_WK_RECORD_KEEPER: return ("add dependent"); case PM_DEP_WK_RECORD_KEEPER_PROP: return ("add dependent property"); case PM_DEP_WK_KEPT: return ("kept"); case PM_DEP_WK_KEEPER: return ("keeper"); case PM_DEP_WK_ATTACH: return ("attach"); case PM_DEP_WK_CHECK_KEPT: return ("check kept"); case PM_DEP_WK_CPR_SUSPEND: return ("suspend"); case PM_DEP_WK_CPR_RESUME: return ("resume"); default: return ("unknown"); } } static void pm_rele_dep(char *keeper) { PMD_FUNC(pmf, "rele_dep") pm_pdr_t *dp; char *kept_path = NULL; dev_info_t *kept = NULL; int count = 0; for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (strcmp(dp->pdr_keeper, keeper) != 0) continue; for (count = 0; count < dp->pdr_kept_count; count++) { kept_path = dp->pdr_kept_paths[count]; if (kept_path == NULL) continue; kept = pm_name_to_dip(kept_path, 1); if (kept) { PMD(PMD_KEEPS, ("%s: release kept=%s@%s(%s#%d) " "of keeper=%s\n", pmf, PM_DEVICE(kept), keeper)) ASSERT(DEVI(kept)->devi_pm_kidsupcnt > 0); pm_rele_power(kept); ddi_release_devi(kept); } } } } /* * Called when we are just released from direct PM. Bring ourself up * if our keeper is up since dependency is not honored while a kept * device is under direct PM. */ static void pm_bring_self_up(char *keptpath) { PMD_FUNC(pmf, "bring_self_up") dev_info_t *kept; dev_info_t *keeper; pm_pdr_t *dp; int i, j; int up = 0, circ; kept = pm_name_to_dip(keptpath, 1); if (kept == NULL) return; PMD(PMD_KEEPS, ("%s: kept=%s@%s(%s#%d)\n", pmf, PM_DEVICE(kept))) for (dp = pm_dep_head; dp; dp = dp->pdr_next) { if (dp->pdr_kept_count == 0) continue; for (i = 0; i < dp->pdr_kept_count; i++) { if (strcmp(dp->pdr_kept_paths[i], keptpath) != 0) continue; keeper = pm_name_to_dip(dp->pdr_keeper, 1); if (keeper) { PMD(PMD_KEEPS, ("%s: keeper=%s@%s(%s#%d)\n", pmf, PM_DEVICE(keeper))) PM_LOCK_POWER(keeper, &circ); for (j = 0; j < PM_NUMCMPTS(keeper); j++) { if (PM_CURPOWER(keeper, j)) { PMD(PMD_KEEPS, ("%s: comp=" "%d is up\n", pmf, j)) up++; } } if (up) { if (PM_SKBU(kept)) DEVI(kept)->devi_pm_flags &= ~PMC_SKIP_BRINGUP; bring_pmdep_up(kept, 1); } PM_UNLOCK_POWER(keeper, circ); ddi_release_devi(keeper); } } } ddi_release_devi(kept); } static void pm_process_dep_request(pm_dep_wk_t *work) { PMD_FUNC(pmf, "dep_req") int ret; PMD(PMD_DEP, ("%s: work=%s\n", pmf, pdw_type_decode(work->pdw_type))) PMD(PMD_DEP, ("%s: keeper=%s, kept=%s\n", pmf, (work->pdw_keeper ? work->pdw_keeper : "NULL"), (work->pdw_kept ? work->pdw_kept : "NULL"))) switch (work->pdw_type) { case PM_DEP_WK_POWER_ON: /* Bring up the kept devices and put a hold on them */ bring_wekeeps_up(work->pdw_keeper); break; case PM_DEP_WK_POWER_OFF: /* Release the kept devices */ pm_rele_dep(work->pdw_keeper); break; case PM_DEP_WK_DETACH: pm_free_keeps(work->pdw_keeper, work->pdw_pwr); break; case PM_DEP_WK_REMOVE_DEP: pm_discard_dependencies(); break; case PM_DEP_WK_BRINGUP_SELF: /* * We deferred satisfying our dependency till now, so satisfy * it again and bring ourselves up. */ pm_bring_self_up(work->pdw_kept); break; case PM_DEP_WK_RECORD_KEEPER: (void) pm_record_keeper(work->pdw_kept, work->pdw_keeper, 0); ddi_walk_devs(ddi_root_node(), pm_kept_walk, NULL); ddi_walk_devs(ddi_root_node(), pm_keeper_walk, NULL); break; case PM_DEP_WK_RECORD_KEEPER_PROP: (void) pm_record_keeper(work->pdw_kept, work->pdw_keeper, 1); ddi_walk_devs(ddi_root_node(), pm_keeper_walk, NULL); ddi_walk_devs(ddi_root_node(), pm_kept_walk, NULL); break; case PM_DEP_WK_KEPT: ret = pm_kept(work->pdw_kept); PMD(PMD_DEP, ("%s: PM_DEP_WK_KEPT: pm_kept returns %d\n", pmf, ret)) break; case PM_DEP_WK_KEEPER: ret = pm_keeper(work->pdw_keeper); PMD(PMD_DEP, ("%s: PM_DEP_WK_KEEPER: pm_keeper returns %d\n", pmf, ret)) break; case PM_DEP_WK_ATTACH: ret = pm_keeper(work->pdw_keeper); PMD(PMD_DEP, ("%s: PM_DEP_WK_ATTACH: pm_keeper returns %d\n", pmf, ret)) ret = pm_kept(work->pdw_kept); PMD(PMD_DEP, ("%s: PM_DEP_WK_ATTACH: pm_kept returns %d\n", pmf, ret)) break; case PM_DEP_WK_CHECK_KEPT: ret = pm_is_kept(work->pdw_kept); PMD(PMD_DEP, ("%s: PM_DEP_WK_CHECK_KEPT: kept=%s, ret=%d\n", pmf, work->pdw_kept, ret)) break; case PM_DEP_WK_CPR_SUSPEND: pm_discard_dependencies(); break; case PM_DEP_WK_CPR_RESUME: ddi_walk_devs(ddi_root_node(), pm_kept_walk, NULL); ddi_walk_devs(ddi_root_node(), pm_keeper_walk, NULL); break; default: ASSERT(0); break; } /* * Free the work structure if the requester is not waiting * Otherwise it is the requester's responsiblity to free it. */ if (!work->pdw_wait) { if (work->pdw_keeper) kmem_free(work->pdw_keeper, strlen(work->pdw_keeper) + 1); if (work->pdw_kept) kmem_free(work->pdw_kept, strlen(work->pdw_kept) + 1); kmem_free(work, sizeof (pm_dep_wk_t)); } else { /* * Notify requester if it is waiting for it. */ work->pdw_ret = ret; work->pdw_done = 1; cv_signal(&work->pdw_cv); } } /* * Process PM dependency requests. */ static void pm_dep_thread(void) { pm_dep_wk_t *work; callb_cpr_t cprinfo; CALLB_CPR_INIT(&cprinfo, &pm_dep_thread_lock, callb_generic_cpr, "pm_dep_thread"); for (;;) { mutex_enter(&pm_dep_thread_lock); if (pm_dep_thread_workq == NULL) { CALLB_CPR_SAFE_BEGIN(&cprinfo); cv_wait(&pm_dep_thread_cv, &pm_dep_thread_lock); CALLB_CPR_SAFE_END(&cprinfo, &pm_dep_thread_lock); } work = pm_dep_thread_workq; pm_dep_thread_workq = work->pdw_next; if (pm_dep_thread_tail == work) pm_dep_thread_tail = work->pdw_next; mutex_exit(&pm_dep_thread_lock); pm_process_dep_request(work); } /*NOTREACHED*/ } /* * Set the power level of the indicated device to unknown (if it is not a * backwards compatible device), as it has just been resumed, and it won't * know if the power was removed or not. Adjust parent's kidsupcnt if necessary. */ void pm_forget_power_level(dev_info_t *dip) { dev_info_t *pdip = ddi_get_parent(dip); int i, count = 0; if (!PM_ISBC(dip)) { for (i = 0; i < PM_NUMCMPTS(dip); i++) count += (PM_CURPOWER(dip, i) == 0); if (count && pdip && !PM_WANTS_NOTIFICATION(pdip)) e_pm_hold_rele_power(pdip, count); /* * Count this as a power cycle if we care */ if (DEVI(dip)->devi_pm_volpmd && PM_CP(dip, 0)->pmc_cur_pwr == 0) DEVI(dip)->devi_pm_volpmd = 0; for (i = 0; i < PM_NUMCMPTS(dip); i++) e_pm_set_cur_pwr(dip, PM_CP(dip, i), PM_LEVEL_UNKNOWN); } } /* * This function advises the caller whether it should make a power-off * transition at this time or not. If the transition is not advised * at this time, the time that the next power-off transition can * be made from now is returned through "intervalp" pointer. * This function returns: * * 1 power-off advised * 0 power-off not advised, intervalp will point to seconds from * now that a power-off is advised. If it is passed the number * of years that policy specifies the device should last, * a large number is returned as the time interval. * -1 error */ int pm_trans_check(struct pm_trans_data *datap, time_t *intervalp) { PMD_FUNC(pmf, "pm_trans_check") char dbuf[DC_SCSI_MFR_LEN]; struct pm_scsi_cycles *scp; int service_years, service_weeks, full_years; time_t now, service_seconds, tdiff; time_t within_year, when_allowed; char *ptr; int lower_bound_cycles, upper_bound_cycles, cycles_allowed; int cycles_diff, cycles_over; if (datap == NULL) { PMD(PMD_TCHECK, ("%s: NULL data pointer!\n", pmf)) return (-1); } if (datap->format == DC_SCSI_FORMAT) { /* * Power cycles of the scsi drives are distributed * over 5 years with the following percentage ratio: * * 30%, 25%, 20%, 15%, and 10% * * The power cycle quota for each year is distributed * linearly through out the year. The equation for * determining the expected cycles is: * * e = a * (n / y) * * e = expected cycles * a = allocated cycles for this year * n = number of seconds since beginning of this year * y = number of seconds in a year * * Note that beginning of the year starts the day that * the drive has been put on service. * * If the drive has passed its expected cycles, we * can determine when it can start to power cycle * again to keep it on track to meet the 5-year * life expectancy. The equation for determining * when to power cycle is: * * w = y * (c / a) * * w = when it can power cycle again * y = number of seconds in a year * c = current number of cycles * a = allocated cycles for the year * */ char pcnt[DC_SCSI_NPY] = { 30, 55, 75, 90, 100 }; scp = &datap->un.scsi_cycles; PMD(PMD_TCHECK, ("%s: format=%d, lifemax=%d, ncycles=%d, " "svc_date=%s, svc_flag=%d\n", pmf, datap->format, scp->lifemax, scp->ncycles, scp->svc_date, scp->flag)) if (scp->ncycles < 0 || scp->flag != 0) { PMD(PMD_TCHECK, ("%s: ncycles < 0 || flag != 0\n", pmf)) return (-1); } if (scp->ncycles > scp->lifemax) { *intervalp = (LONG_MAX / hz); return (0); } /* * convert service date to time_t */ bcopy(scp->svc_date, dbuf, DC_SCSI_YEAR_LEN); dbuf[DC_SCSI_YEAR_LEN] = '\0'; ptr = dbuf; service_years = stoi(&ptr) - EPOCH_YEAR; bcopy(&scp->svc_date[DC_SCSI_YEAR_LEN], dbuf, DC_SCSI_WEEK_LEN); dbuf[DC_SCSI_WEEK_LEN] = '\0'; /* * scsi standard does not specify WW data, * could be (00-51) or (01-52) */ ptr = dbuf; service_weeks = stoi(&ptr); if (service_years < 0 || service_weeks < 0 || service_weeks > 52) { PMD(PMD_TCHECK, ("%s: service year %d and week %d\n", pmf, service_years, service_weeks)) return (-1); } /* * calculate service date in seconds-since-epoch, * adding one day for each leap-year. * * (years-since-epoch + 2) fixes integer truncation, * example: (8) leap-years during [1972, 2000] * (2000 - 1970) = 30; and (30 + 2) / 4 = 8; */ service_seconds = (service_years * DC_SPY) + (service_weeks * DC_SPW) + (((service_years + 2) / 4) * DC_SPD); now = gethrestime_sec(); /* * since the granularity of 'svc_date' is day not second, * 'now' should be rounded up to full day. */ now = ((now + DC_SPD -1) / DC_SPD) * DC_SPD; if (service_seconds > now) { PMD(PMD_TCHECK, ("%s: service date (%ld) later " "than now (%ld)!\n", pmf, service_seconds, now)) return (-1); } tdiff = now - service_seconds; PMD(PMD_TCHECK, ("%s: age is %ld sec\n", pmf, tdiff)) /* * NOTE - Leap years are not considered in the calculations * below. */ full_years = (tdiff / DC_SPY); if ((full_years >= DC_SCSI_NPY) && (scp->ncycles <= scp->lifemax)) return (1); /* * Determine what is the normal cycle usage for the * device at the beginning and the end of this year. */ lower_bound_cycles = (!full_years) ? 0 : ((scp->lifemax * pcnt[full_years - 1]) / 100); upper_bound_cycles = (scp->lifemax * pcnt[full_years]) / 100; if (scp->ncycles <= lower_bound_cycles) return (1); /* * The linear slope that determines how many cycles * are allowed this year is number of seconds * passed this year over total number of seconds in a year. */ cycles_diff = (upper_bound_cycles - lower_bound_cycles); within_year = (tdiff % DC_SPY); cycles_allowed = lower_bound_cycles + (((uint64_t)cycles_diff * (uint64_t)within_year) / DC_SPY); PMD(PMD_TCHECK, ("%s: lived %d yrs and %ld secs\n", pmf, full_years, within_year)) PMD(PMD_TCHECK, ("%s: # of cycles allowed %d\n", pmf, cycles_allowed)) if (scp->ncycles <= cycles_allowed) return (1); /* * The transition is not advised now but we can * determine when the next transition can be made. * * Depending on how many cycles the device has been * over-used, we may need to skip years with * different percentage quota in order to determine * when the next transition can be made. */ cycles_over = (scp->ncycles - lower_bound_cycles); while (cycles_over > cycles_diff) { full_years++; if (full_years >= DC_SCSI_NPY) { *intervalp = (LONG_MAX / hz); return (0); } cycles_over -= cycles_diff; lower_bound_cycles = upper_bound_cycles; upper_bound_cycles = (scp->lifemax * pcnt[full_years]) / 100; cycles_diff = (upper_bound_cycles - lower_bound_cycles); } /* * The linear slope that determines when the next transition * can be made is the relative position of used cycles within a * year over total number of cycles within that year. */ when_allowed = service_seconds + (full_years * DC_SPY) + (((uint64_t)DC_SPY * (uint64_t)cycles_over) / cycles_diff); *intervalp = (when_allowed - now); if (*intervalp > (LONG_MAX / hz)) *intervalp = (LONG_MAX / hz); PMD(PMD_TCHECK, ("%s: no cycle is allowed in %ld secs\n", pmf, *intervalp)) return (0); } PMD(PMD_TCHECK, ("%s: unknown format!\n", pmf)) return (-1); } /* * Nexus drivers call into pm framework to indicate which child driver is about * to be installed. In some platforms, ppm may need to configure the hardware * for successful installation of a driver. */ int pm_init_child(dev_info_t *dip) { power_req_t power_req; ASSERT(ddi_binding_name(dip)); ASSERT(ddi_get_name_addr(dip)); pm_ppm_claim(dip); if (pm_ppm_claimed(dip)) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_INIT_CHILD; power_req.req.ppm_config_req.who = dip; ASSERT(PPM(dip) != NULL); return (pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, NULL)); } else { #ifdef DEBUG /* pass it to the default handler so we can debug things */ power_req.request_type = PMR_PPM_INIT_CHILD; power_req.req.ppm_config_req.who = dip; (void) pm_ctlops(NULL, dip, DDI_CTLOPS_POWER, &power_req, NULL); #endif } return (DDI_SUCCESS); } /* * Bring parent of a node that is about to be probed up to full power, and * arrange for it to stay up until pm_post_probe() or pm_post_attach() decide * it is time to let it go down again */ void pm_pre_probe(dev_info_t *dip, pm_ppm_cookie_t *cp) { int result; power_req_t power_req; bzero(cp, sizeof (*cp)); cp->ppc_dip = dip; pm_ppm_claim(dip); if (pm_ppm_claimed(dip)) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_PRE_PROBE; power_req.req.ppm_config_req.who = dip; ASSERT(PPM(dip) != NULL); (void) pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); cp->ppc_ppm = PPM(dip); } else { #ifdef DEBUG /* pass it to the default handler so we can debug things */ power_req.request_type = PMR_PPM_PRE_PROBE; power_req.req.ppm_config_req.who = dip; (void) pm_ctlops(NULL, dip, DDI_CTLOPS_POWER, &power_req, &result); #endif cp->ppc_ppm = NULL; } } int pm_pre_config(dev_info_t *dip, char *devnm) { PMD_FUNC(pmf, "pre_config") int ret; if (MDI_VHCI(dip)) { PMD(PMD_SET, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) ret = mdi_power(dip, MDI_PM_PRE_CONFIG, NULL, devnm, 0); return (ret == MDI_SUCCESS ? DDI_SUCCESS : DDI_FAILURE); } else if (!PM_GET_PM_INFO(dip)) return (DDI_SUCCESS); PMD(PMD_SET, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) pm_hold_power(dip); ret = pm_all_to_normal(dip, PM_CANBLOCK_BLOCK); if (ret != DDI_SUCCESS) pm_rele_power(dip); return (ret); } /* * This routine is called by devfs during its walk to unconfigue a node. * If the call is due to auto mod_unloads and the dip is not at its * full power, we return DDI_FAILURE to terminate the walk, otherwise * return DDI_SUCCESS. */ int pm_pre_unconfig(dev_info_t *dip, int flags, int *held, char *devnm) { PMD_FUNC(pmf, "pre_unconfig") int ret; if (MDI_VHCI(dip)) { PMD(PMD_SET, ("%s: %s@%s(%s#%d), flags=%x\n", pmf, PM_DEVICE(dip), flags)) ret = mdi_power(dip, MDI_PM_PRE_UNCONFIG, held, devnm, flags); return (ret == MDI_SUCCESS ? DDI_SUCCESS : DDI_FAILURE); } else if (!PM_GET_PM_INFO(dip)) return (DDI_SUCCESS); PMD(PMD_SET, ("%s: %s@%s(%s#%d), flags=%x\n", pmf, PM_DEVICE(dip), flags)) *held = 0; /* * If the dip is a leaf node, don't power it up. */ if (!ddi_get_child(dip)) return (DDI_SUCCESS); /* * Do not power up the node if it is called due to auto-modunload. */ if ((flags & NDI_AUTODETACH) && !pm_all_at_normal(dip)) return (DDI_FAILURE); pm_hold_power(dip); *held = 1; ret = pm_all_to_normal(dip, PM_CANBLOCK_BLOCK); if (ret != DDI_SUCCESS) { pm_rele_power(dip); *held = 0; } return (ret); } /* * Notify ppm of attach action. Parent is already held at full power by * probe action. */ void pm_pre_attach(dev_info_t *dip, pm_ppm_cookie_t *cp, ddi_attach_cmd_t cmd) { static char *me = "pm_pre_attach"; power_req_t power_req; int result; /* * Initialize and fill in the PPM cookie */ bzero(cp, sizeof (*cp)); cp->ppc_cmd = (int)cmd; cp->ppc_ppm = PPM(dip); cp->ppc_dip = dip; /* * DDI_ATTACH and DDI_RESUME cmds need to call platform specific * Power Management stuff. DDI_RESUME also has to purge it's * powerlevel information. */ switch (cmd) { case DDI_ATTACH: if (cp->ppc_ppm) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_PRE_ATTACH; power_req.req.ppm_config_req.who = dip; ASSERT(PPM(dip)); (void) pm_ctlops(cp->ppc_ppm, dip, DDI_CTLOPS_POWER, &power_req, &result); } #ifdef DEBUG else { power_req.request_type = PMR_PPM_PRE_ATTACH; power_req.req.ppm_config_req.who = dip; (void) pm_ctlops(NULL, dip, DDI_CTLOPS_POWER, &power_req, &result); } #endif break; case DDI_RESUME: pm_forget_power_level(dip); if (cp->ppc_ppm) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_PRE_RESUME; power_req.req.resume_req.who = cp->ppc_dip; power_req.req.resume_req.cmd = (ddi_attach_cmd_t)cp->ppc_cmd; ASSERT(PPM(cp->ppc_dip) == cp->ppc_ppm); (void) pm_ctlops(cp->ppc_ppm, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #ifdef DEBUG else { power_req.request_type = PMR_PPM_PRE_RESUME; power_req.req.resume_req.who = cp->ppc_dip; power_req.req.resume_req.cmd = (ddi_attach_cmd_t)cp->ppc_cmd; (void) pm_ctlops(NULL, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #endif break; case DDI_PM_RESUME: break; default: panic(me); } } /* * Nexus drivers call into pm framework to indicate which child driver is * being uninstalled. In some platforms, ppm may need to reconfigure the * hardware since the device driver is no longer installed. */ int pm_uninit_child(dev_info_t *dip) { power_req_t power_req; ASSERT(ddi_binding_name(dip)); ASSERT(ddi_get_name_addr(dip)); pm_ppm_claim(dip); if (pm_ppm_claimed(dip)) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_UNINIT_CHILD; power_req.req.ppm_config_req.who = dip; ASSERT(PPM(dip)); return (pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, NULL)); } else { #ifdef DEBUG /* pass it to the default handler so we can debug things */ power_req.request_type = PMR_PPM_UNINIT_CHILD; power_req.req.ppm_config_req.who = dip; (void) pm_ctlops(NULL, dip, DDI_CTLOPS_POWER, &power_req, NULL); #endif } return (DDI_SUCCESS); } /* * Decrement kidsupcnt so scan can turn the parent back off if it is idle * Also notify ppm of result of probe if there is a ppm that cares */ void pm_post_probe(pm_ppm_cookie_t *cp, int ret, int probe_failed) { _NOTE(ARGUNUSED(probe_failed)) int result; power_req_t power_req; if (cp->ppc_ppm) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_POST_PROBE; power_req.req.ppm_config_req.who = cp->ppc_dip; power_req.req.ppm_config_req.result = ret; ASSERT(PPM(cp->ppc_dip) == cp->ppc_ppm); (void) pm_ctlops(cp->ppc_ppm, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #ifdef DEBUG else { power_req.request_type = PMR_PPM_POST_PROBE; power_req.req.ppm_config_req.who = cp->ppc_dip; power_req.req.ppm_config_req.result = ret; (void) pm_ctlops(NULL, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #endif } void pm_post_config(dev_info_t *dip, char *devnm) { PMD_FUNC(pmf, "post_config") if (MDI_VHCI(dip)) { PMD(PMD_SET, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) (void) mdi_power(dip, MDI_PM_POST_CONFIG, NULL, devnm, 0); return; } else if (!PM_GET_PM_INFO(dip)) return; PMD(PMD_SET, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) pm_rele_power(dip); } void pm_post_unconfig(dev_info_t *dip, int held, char *devnm) { PMD_FUNC(pmf, "post_unconfig") if (MDI_VHCI(dip)) { PMD(PMD_SET, ("%s: %s@%s(%s#%d), held = %d\n", pmf, PM_DEVICE(dip), held)) (void) mdi_power(dip, MDI_PM_POST_UNCONFIG, &held, devnm, 0); return; } else if (!PM_GET_PM_INFO(dip)) return; PMD(PMD_SET, ("%s: %s@%s(%s#%d), held = %d\n", pmf, PM_DEVICE(dip), held)) if (!held) return; /* * We have held power in pre_unconfig, release it here. */ pm_rele_power(dip); } /* * Notify ppm of result of attach if there is a ppm that cares */ void pm_post_attach(pm_ppm_cookie_t *cp, int ret) { int result; power_req_t power_req; dev_info_t *dip; if (cp->ppc_cmd != DDI_ATTACH) return; dip = cp->ppc_dip; if (ret == DDI_SUCCESS) { /* * Attach succeeded, so proceed to doing post-attach pm tasks */ if (PM_GET_PM_INFO(dip) == NULL) (void) pm_start(dip); } else { /* * Attach may have got pm started before failing */ pm_stop(dip); } if (cp->ppc_ppm) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_POST_ATTACH; power_req.req.ppm_config_req.who = cp->ppc_dip; power_req.req.ppm_config_req.result = ret; ASSERT(PPM(cp->ppc_dip) == cp->ppc_ppm); (void) pm_ctlops(cp->ppc_ppm, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #ifdef DEBUG else { power_req.request_type = PMR_PPM_POST_ATTACH; power_req.req.ppm_config_req.who = cp->ppc_dip; power_req.req.ppm_config_req.result = ret; (void) pm_ctlops(NULL, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #endif } /* * Notify ppm of attach action. Parent is already held at full power by * probe action. */ void pm_pre_detach(dev_info_t *dip, ddi_detach_cmd_t cmd, pm_ppm_cookie_t *cp) { int result; power_req_t power_req; bzero(cp, sizeof (*cp)); cp->ppc_dip = dip; cp->ppc_cmd = (int)cmd; switch (cmd) { case DDI_DETACH: pm_detaching(dip); /* suspend pm while detaching */ if (pm_ppm_claimed(dip)) { /* if ppm driver claims node */ power_req.request_type = PMR_PPM_PRE_DETACH; power_req.req.ppm_config_req.who = dip; ASSERT(PPM(dip)); (void) pm_ctlops(PPM(dip), dip, DDI_CTLOPS_POWER, &power_req, &result); cp->ppc_ppm = PPM(dip); } else { #ifdef DEBUG /* pass to the default handler so we can debug things */ power_req.request_type = PMR_PPM_PRE_DETACH; power_req.req.ppm_config_req.who = dip; (void) pm_ctlops(NULL, dip, DDI_CTLOPS_POWER, &power_req, &result); #endif cp->ppc_ppm = NULL; } break; default: break; } } /* * Dip is either a leaf node that exported "no-involuntary-power-cycles" prop., * (if devi_pm_noinvol count is 0) or an ancestor of such a node. We need to * make an entry to record the details, which includes certain flag settings. */ static void pm_record_invol_path(char *path, int flags, int noinvolpm, int volpmd, int wasvolpmd, major_t major) { PMD_FUNC(pmf, "record_invol_path") major_t pm_path_to_major(char *); size_t plen; pm_noinvol_t *ip, *np, *pp; pp = NULL; plen = strlen(path) + 1; np = kmem_zalloc(sizeof (*np), KM_SLEEP); np->ni_size = plen; np->ni_path = kmem_alloc(plen, KM_SLEEP); np->ni_noinvolpm = noinvolpm; np->ni_volpmd = volpmd; np->ni_wasvolpmd = wasvolpmd; np->ni_flags = flags; (void) strcpy(np->ni_path, path); /* * If we haven't actually seen the node attached, it is hard to figure * out its major. If we could hold the node by path, we would be much * happier here. */ if (major == (major_t)-1) { np->ni_major = pm_path_to_major(path); } else { np->ni_major = major; } rw_enter(&pm_noinvol_rwlock, RW_WRITER); for (ip = pm_noinvol_head; ip; pp = ip, ip = ip->ni_next) { int comp = strcmp(path, ip->ni_path); if (comp < 0) { PMD(PMD_NOINVOL, ("%s: %s insert before %s\n", pmf, path, ip->ni_path)) /* insert before current entry */ np->ni_next = ip; if (pp) { pp->ni_next = np; } else { pm_noinvol_head = np; } rw_exit(&pm_noinvol_rwlock); #ifdef DEBUG if (pm_debug & PMD_NOINVOL) pr_noinvol("record_invol_path exit0"); #endif return; } else if (comp == 0) { panic("%s already in pm_noinvol list", path); } } /* * If we did not find an entry in the list that this should go before, * then it must go at the end */ if (pp) { PMD(PMD_NOINVOL, ("%s: %s append after %s\n", pmf, path, pp->ni_path)) ASSERT(pp->ni_next == 0); pp->ni_next = np; } else { PMD(PMD_NOINVOL, ("%s: %s added to end-of-list\n", pmf, path)) ASSERT(!pm_noinvol_head); pm_noinvol_head = np; } rw_exit(&pm_noinvol_rwlock); #ifdef DEBUG if (pm_debug & PMD_NOINVOL) pr_noinvol("record_invol_path exit"); #endif } void pm_record_invol(dev_info_t *dip) { char *pathbuf; int pm_all_components_off(dev_info_t *); int volpmd = (PM_NUMCMPTS(dip) > 0) && pm_all_components_off(dip); pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); pm_record_invol_path(pathbuf, (DEVI(dip)->devi_pm_flags & (PMC_NO_INVOL | PMC_CONSOLE_FB)), DEVI(dip)->devi_pm_noinvolpm, DEVI(dip)->devi_pm_volpmd, volpmd, PM_MAJOR(dip)); /* * If this child's detach will be holding up its ancestors, then we * allow for an exception to that if all children of this type have * gone down voluntarily. * Now walk down the tree incrementing devi_pm_noinvolpm */ (void) pm_noinvol_update(PM_BP_NOINVOL_DETACH, 0, volpmd, pathbuf, dip); kmem_free(pathbuf, MAXPATHLEN); } void pm_post_detach(pm_ppm_cookie_t *cp, int ret) { dev_info_t *dip = cp->ppc_dip; int result; power_req_t power_req; switch (cp->ppc_cmd) { case DDI_DETACH: if (cp->ppc_ppm) { /* if ppm driver claims the node */ power_req.request_type = PMR_PPM_POST_DETACH; power_req.req.ppm_config_req.who = cp->ppc_dip; power_req.req.ppm_config_req.result = ret; ASSERT(PPM(cp->ppc_dip) == cp->ppc_ppm); (void) pm_ctlops(cp->ppc_ppm, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #ifdef DEBUG else { power_req.request_type = PMR_PPM_POST_DETACH; power_req.req.ppm_config_req.who = cp->ppc_dip; power_req.req.ppm_config_req.result = ret; (void) pm_ctlops(NULL, cp->ppc_dip, DDI_CTLOPS_POWER, &power_req, &result); } #endif if (ret == DDI_SUCCESS) { /* * For hotplug detach we assume it is *really* gone */ if (cp->ppc_cmd == DDI_DETACH && ((DEVI(dip)->devi_pm_flags & (PMC_NO_INVOL | PMC_CONSOLE_FB)) || DEVI(dip)->devi_pm_noinvolpm)) pm_record_invol(dip); DEVI(dip)->devi_pm_flags &= ~(PMC_NO_INVOL | PMC_NOINVOL_DONE); /* * If console fb is detaching, then we don't need to * worry any more about it going off (pm_detaching has * brought up all components) */ if (PM_IS_CFB(dip)) { mutex_enter(&pm_cfb_lock); ASSERT(cfb_dip_detaching); ASSERT(cfb_dip == NULL); ASSERT(pm_cfb_comps_off == 0); cfb_dip_detaching = NULL; mutex_exit(&pm_cfb_lock); } pm_stop(dip); /* make it permanent */ } else { if (PM_IS_CFB(dip)) { mutex_enter(&pm_cfb_lock); ASSERT(cfb_dip_detaching); ASSERT(cfb_dip == NULL); ASSERT(pm_cfb_comps_off == 0); cfb_dip = cfb_dip_detaching; cfb_dip_detaching = NULL; mutex_exit(&pm_cfb_lock); } pm_detach_failed(dip); /* resume power management */ } break; case DDI_PM_SUSPEND: break; case DDI_SUSPEND: break; /* legal, but nothing to do */ default: #ifdef DEBUG panic("pm_post_detach: unrecognized cmd %d for detach", cp->ppc_cmd); /*NOTREACHED*/ #else break; #endif } } /* * Called after vfs_mountroot has got the clock started to fix up timestamps * that were set when root bush drivers attached. hresttime was 0 then, so the * devices look busy but have a 0 busycnt */ int pm_adjust_timestamps(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) pm_info_t *info = PM_GET_PM_INFO(dip); struct pm_component *cp; int i; if (!info) return (DDI_WALK_CONTINUE); PM_LOCK_BUSY(dip); for (i = 0; i < PM_NUMCMPTS(dip); i++) { cp = PM_CP(dip, i); if (cp->pmc_timestamp == 0 && cp->pmc_busycount == 0) cp->pmc_timestamp = gethrestime_sec(); } PM_UNLOCK_BUSY(dip); return (DDI_WALK_CONTINUE); } /* * Called at attach time to see if the device being attached has a record in * the no involuntary power cycles list. If so, we do some bookkeeping on the * parents and set a flag in the dip */ void pm_noinvol_specd(dev_info_t *dip) { PMD_FUNC(pmf, "noinvol_specd") char *pathbuf; pm_noinvol_t *ip, *pp = NULL; int wasvolpmd; int found = 0; if (DEVI(dip)->devi_pm_flags & PMC_NOINVOL_DONE) return; DEVI(dip)->devi_pm_flags |= PMC_NOINVOL_DONE; pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); PM_LOCK_DIP(dip); DEVI(dip)->devi_pm_volpmd = 0; DEVI(dip)->devi_pm_noinvolpm = 0; rw_enter(&pm_noinvol_rwlock, RW_READER); for (ip = pm_noinvol_head; ip; pp = ip, ip = ip->ni_next) { PMD(PMD_NOINVOL, ("%s: comparing '%s' to '%s'\n", pmf, pathbuf, ip->ni_path)) if (strcmp(pathbuf, ip->ni_path) == 0) { found++; break; } } rw_exit(&pm_noinvol_rwlock); if (!found) { PM_UNLOCK_DIP(dip); kmem_free(pathbuf, MAXPATHLEN); return; } rw_enter(&pm_noinvol_rwlock, RW_WRITER); pp = NULL; for (ip = pm_noinvol_head; ip; pp = ip, ip = ip->ni_next) { PMD(PMD_NOINVOL, ("%s: comparing '%s' to '%s'\n", pmf, pathbuf, ip->ni_path)) if (strcmp(pathbuf, ip->ni_path) == 0) { ip->ni_flags &= ~PMC_DRIVER_REMOVED; DEVI(dip)->devi_pm_flags |= ip->ni_flags; /* * Handle special case of console fb */ if (PM_IS_CFB(dip)) { mutex_enter(&pm_cfb_lock); cfb_dip = dip; PMD(PMD_CFB, ("%s: %s@%s(%s#%d) setting " "cfb_dip\n", pmf, PM_DEVICE(dip))) mutex_exit(&pm_cfb_lock); } DEVI(dip)->devi_pm_noinvolpm = ip->ni_noinvolpm; ASSERT((DEVI(dip)->devi_pm_flags & (PMC_NO_INVOL | PMC_CONSOLE_FB)) || DEVI(dip)->devi_pm_noinvolpm); DEVI(dip)->devi_pm_volpmd = ip->ni_volpmd; PMD(PMD_NOINVOL, ("%s: noinvol=%d, volpmd=%d, " "wasvolpmd=%d, flags=%x, path=%s\n", pmf, ip->ni_noinvolpm, ip->ni_volpmd, ip->ni_wasvolpmd, ip->ni_flags, ip->ni_path)) /* * free the entry in hopes the list will now be empty * and we won't have to search it any more until the * device detaches */ if (pp) { PMD(PMD_NOINVOL, ("%s: free %s, prev %s\n", pmf, ip->ni_path, pp->ni_path)) pp->ni_next = ip->ni_next; } else { PMD(PMD_NOINVOL, ("%s: free %s head\n", pmf, ip->ni_path)) ASSERT(pm_noinvol_head == ip); pm_noinvol_head = ip->ni_next; } PM_UNLOCK_DIP(dip); wasvolpmd = ip->ni_wasvolpmd; rw_exit(&pm_noinvol_rwlock); kmem_free(ip->ni_path, ip->ni_size); kmem_free(ip, sizeof (*ip)); /* * Now walk up the tree decrementing devi_pm_noinvolpm * (and volpmd if appropriate) */ (void) pm_noinvol_update(PM_BP_NOINVOL_ATTACH, 0, wasvolpmd, pathbuf, dip); #ifdef DEBUG if (pm_debug & PMD_NOINVOL) pr_noinvol("noinvol_specd exit"); #endif kmem_free(pathbuf, MAXPATHLEN); return; } } kmem_free(pathbuf, MAXPATHLEN); rw_exit(&pm_noinvol_rwlock); PM_UNLOCK_DIP(dip); } int pm_all_components_off(dev_info_t *dip) { int i; pm_component_t *cp; for (i = 0; i < PM_NUMCMPTS(dip); i++) { cp = PM_CP(dip, i); if (cp->pmc_cur_pwr == PM_LEVEL_UNKNOWN || cp->pmc_comp.pmc_lvals[cp->pmc_cur_pwr]) return (0); } return (1); /* all off */ } /* * Make sure that all "no involuntary power cycles" devices are attached. * Called before doing a cpr suspend to make sure the driver has a say about * the power cycle */ int pm_reattach_noinvol(void) { PMD_FUNC(pmf, "reattach_noinvol") pm_noinvol_t *ip; char *path; dev_info_t *dip; /* * Prevent the modunload thread from unloading any modules until we * have completely stopped all kernel threads. */ modunload_disable(); for (ip = pm_noinvol_head; ip; ip = ip->ni_next) { /* * Forget we'v ever seen any entry */ ip->ni_persistent = 0; } restart: rw_enter(&pm_noinvol_rwlock, RW_READER); for (ip = pm_noinvol_head; ip; ip = ip->ni_next) { major_t maj; maj = ip->ni_major; path = ip->ni_path; if (path != NULL && !(ip->ni_flags & PMC_DRIVER_REMOVED)) { if (ip->ni_persistent) { /* * If we weren't able to make this entry * go away, then we give up, as * holding/attaching the driver ought to have * resulted in this entry being deleted */ PMD(PMD_NOINVOL, ("%s: can't reattach %s " "(%s|%d)\n", pmf, ip->ni_path, ddi_major_to_name(maj), (int)maj)) cmn_err(CE_WARN, "cpr: unable to reattach %s ", ip->ni_path); modunload_enable(); rw_exit(&pm_noinvol_rwlock); return (0); } ip->ni_persistent++; rw_exit(&pm_noinvol_rwlock); PMD(PMD_NOINVOL, ("%s: holding %s\n", pmf, path)) dip = e_ddi_hold_devi_by_path(path, 0); if (dip == NULL) { PMD(PMD_NOINVOL, ("%s: can't hold (%s|%d)\n", pmf, path, (int)maj)) cmn_err(CE_WARN, "cpr: unable to hold %s " "driver", path); modunload_enable(); return (0); } else { PMD(PMD_DHR, ("%s: release %s\n", pmf, path)) /* * Since the modunload thread is stopped, we * don't have to keep the driver held, which * saves a ton of bookkeeping */ ddi_release_devi(dip); goto restart; } } else { PMD(PMD_NOINVOL, ("%s: skip %s; unknown major\n", pmf, ip->ni_path)) continue; } } rw_exit(&pm_noinvol_rwlock); return (1); } void pm_reattach_noinvol_fini(void) { modunload_enable(); } /* * Display pm support code */ /* * console frame-buffer power-mgmt gets enabled when debugging * services are not present or console fbpm override is set */ void pm_cfb_setup(const char *stdout_path) { PMD_FUNC(pmf, "cfb_setup") extern int obpdebug; char *devname; dev_info_t *dip; int devname_len; extern dev_info_t *fbdip; /* * By virtue of this function being called (from consconfig), * we know stdout is a framebuffer. */ stdout_is_framebuffer = 1; if (obpdebug || (boothowto & RB_DEBUG)) { if (pm_cfb_override == 0) { /* * Console is frame buffer, but we want to suppress * pm on it because of debugging setup */ pm_cfb_enabled = 0; cmn_err(CE_NOTE, "Kernel debugger present: disabling " "console power management."); /* * however, we still need to know which is the console * fb in order to suppress pm on it */ } else { cmn_err(CE_WARN, "Kernel debugger present: see " "kmdb(1M) for interaction with power management."); } } #ifdef DEBUG /* * IF console is fb and is power managed, don't do prom_printfs from * pm debug macro */ if (pm_cfb_enabled) { if (pm_debug) prom_printf("pm debug output will be to log only\n"); pm_divertdebug++; } #endif devname = i_ddi_strdup((char *)stdout_path, KM_SLEEP); devname_len = strlen(devname) + 1; PMD(PMD_CFB, ("%s: stripped %s\n", pmf, devname)) /* if the driver is attached */ if ((dip = fbdip) != NULL) { PMD(PMD_CFB, ("%s: attached: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) /* * We set up here as if the driver were power manageable in case * we get a later attach of a pm'able driver (which would result * in a panic later) */ cfb_dip = dip; DEVI(dip)->devi_pm_flags |= (PMC_CONSOLE_FB | PMC_NO_INVOL); PMD(PMD_CFB, ("%s: cfb_dip -> %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) #ifdef DEBUG if (!(PM_GET_PM_INFO(dip) != NULL && PM_NUMCMPTS(dip))) { PMD(PMD_CFB, ("%s: %s@%s(%s#%d) not power-managed\n", pmf, PM_DEVICE(dip))) } #endif } else { char *ep; PMD(PMD_CFB, ("%s: pntd %s failed\n", pmf, devname)) pm_record_invol_path(devname, (PMC_CONSOLE_FB | PMC_NO_INVOL), 1, 0, 0, (major_t)-1); for (ep = strrchr(devname, '/'); ep != devname; ep = strrchr(devname, '/')) { PMD(PMD_CFB, ("%s: devname %s\n", pmf, devname)) *ep = '\0'; dip = pm_name_to_dip(devname, 0); if (dip != NULL) { /* * Walk up the tree incrementing * devi_pm_noinvolpm */ (void) pm_noinvol_update(PM_BP_NOINVOL_CFB, 0, 0, devname, dip); break; } else { pm_record_invol_path(devname, PMC_NO_INVOL, 1, 0, 0, (major_t)-1); } } } kmem_free(devname, devname_len); } void pm_cfb_rele(void) { mutex_enter(&pm_cfb_lock); /* * this call isn't using the console any more, it is ok to take it * down if the count goes to 0 */ cfb_inuse--; mutex_exit(&pm_cfb_lock); } /* * software interrupt handler for fbpm; this function exists because we can't * bring up the frame buffer power from above lock level. So if we need to, * we instead schedule a softint that runs this routine and takes us into * debug_enter (a bit delayed from the original request, but avoiding a panic). */ static uint_t pm_cfb_softint(caddr_t int_handler_arg) { _NOTE(ARGUNUSED(int_handler_arg)) int rval = DDI_INTR_UNCLAIMED; mutex_enter(&pm_cfb_lock); if (pm_soft_pending) { mutex_exit(&pm_cfb_lock); debug_enter((char *)NULL); /* acquired in debug_enter before calling pm_cfb_trigger */ pm_cfb_rele(); mutex_enter(&pm_cfb_lock); pm_soft_pending = 0; mutex_exit(&pm_cfb_lock); rval = DDI_INTR_CLAIMED; } else mutex_exit(&pm_cfb_lock); return (rval); } void pm_cfb_setup_intr(void) { PMD_FUNC(pmf, "cfb_setup_intr") extern void prom_set_outfuncs(void (*)(void), void (*)(void)); void pm_cfb_check_and_powerup(void); if (!stdout_is_framebuffer) { PMD(PMD_CFB, ("%s: console not fb\n", pmf)) return; } mutex_init(&pm_cfb_lock, NULL, MUTEX_SPIN, (void *)ipltospl(SPL8)); #ifdef DEBUG mutex_init(&pm_debug_lock, NULL, MUTEX_SPIN, (void *)ipltospl(SPL8)); #endif /* * setup software interrupt handler */ if (ddi_add_softintr(ddi_root_node(), DDI_SOFTINT_HIGH, &pm_soft_id, NULL, NULL, pm_cfb_softint, NULL) != DDI_SUCCESS) panic("pm: unable to register soft intr."); prom_set_outfuncs(pm_cfb_check_and_powerup, pm_cfb_rele); } /* * Checks to see if it is safe to write to the console wrt power management * (i.e. if the console is a framebuffer, then it must be at full power) * returns 1 when power is off (power-up is needed) * returns 0 when power is on (power-up not needed) */ int pm_cfb_check_and_hold(void) { /* * cfb_dip is set iff console is a power manageable frame buffer * device */ extern int modrootloaded; mutex_enter(&pm_cfb_lock); cfb_inuse++; ASSERT(cfb_inuse); /* wrap? */ if (modrootloaded && cfb_dip) { /* * don't power down the frame buffer, the prom is using it */ if (pm_cfb_comps_off) { mutex_exit(&pm_cfb_lock); return (1); } } mutex_exit(&pm_cfb_lock); return (0); } /* * turn on cfb power (which is known to be off). * Must be called below lock level! */ void pm_cfb_powerup(void) { pm_info_t *info; int norm; int ccount, ci; int unused; #ifdef DEBUG /* * Can't reenter prom_prekern, so suppress pm debug messages * (still go to circular buffer). */ mutex_enter(&pm_debug_lock); pm_divertdebug++; mutex_exit(&pm_debug_lock); #endif info = PM_GET_PM_INFO(cfb_dip); ASSERT(info); ccount = PM_NUMCMPTS(cfb_dip); for (ci = 0; ci < ccount; ci++) { norm = pm_get_normal_power(cfb_dip, ci); (void) pm_set_power(cfb_dip, ci, norm, PM_LEVEL_UPONLY, PM_CANBLOCK_BYPASS, 0, &unused); } #ifdef DEBUG mutex_enter(&pm_debug_lock); pm_divertdebug--; mutex_exit(&pm_debug_lock); #endif } /* * Check if the console framebuffer is powered up. If not power it up. * Note: Calling pm_cfb_check_and_hold has put a hold on the power state which * must be released by calling pm_cfb_rele when the console fb operation * is completed. */ void pm_cfb_check_and_powerup(void) { if (pm_cfb_check_and_hold()) pm_cfb_powerup(); } /* * Trigger a low level interrupt to power up console frame buffer. */ void pm_cfb_trigger(void) { if (cfb_dip == NULL) return; mutex_enter(&pm_cfb_lock); /* * If machine appears to be hung, pulling the keyboard connector of * the console will cause a high level interrupt and go to debug_enter. * But, if the fb is powered down, this routine will be called to bring * it up (by generating a softint to do the work). If soft interrupts * are not running, and the keyboard connector is pulled again, the * following code detects this condition and calls panic which allows * the fb to be brought up from high level. * * If two nearly simultaneous calls to debug_enter occur (both from * high level) the code described above will cause a panic. */ if (lbolt <= pm_soft_pending) { panicstr = "pm_cfb_trigger: lbolt not advancing"; panic(panicstr); /* does a power up at any intr level */ /* NOTREACHED */ } pm_soft_pending = lbolt; mutex_exit(&pm_cfb_lock); ddi_trigger_softintr(pm_soft_id); } major_t pm_path_to_major(char *path) { PMD_FUNC(pmf, "path_to_major") char *np, *ap, *bp; major_t ret; size_t len; static major_t i_path_to_major(char *, char *); PMD(PMD_NOINVOL, ("%s: %s\n", pmf, path)) np = strrchr(path, '/'); if (np != NULL) np++; else np = path; len = strlen(np) + 1; bp = kmem_alloc(len, KM_SLEEP); (void) strcpy(bp, np); if ((ap = strchr(bp, '@')) != NULL) { *ap = '\0'; } PMD(PMD_NOINVOL, ("%s: %d\n", pmf, ddi_name_to_major(np))) ret = i_path_to_major(path, np); kmem_free(bp, len); return (ret); } #ifdef DEBUG char *pm_msgp; char *pm_bufend; char *pm_msgbuf = NULL; int pm_logpages = 2; #define PMLOGPGS pm_logpages /*PRINTFLIKE1*/ void pm_log(const char *fmt, ...) { va_list adx; size_t size; mutex_enter(&pm_debug_lock); if (pm_msgbuf == NULL) { pm_msgbuf = kmem_zalloc(mmu_ptob(PMLOGPGS), KM_SLEEP); pm_bufend = pm_msgbuf + mmu_ptob(PMLOGPGS) - 1; pm_msgp = pm_msgbuf; } va_start(adx, fmt); size = vsnprintf(NULL, 0, fmt, adx) + 1; va_end(adx); va_start(adx, fmt); if (size > (pm_bufend - pm_msgp)) { /* wraps */ bzero(pm_msgp, pm_bufend - pm_msgp); (void) vsnprintf(pm_msgbuf, size, fmt, adx); if (!pm_divertdebug) prom_printf("%s", pm_msgp); pm_msgp = pm_msgbuf + size; } else { (void) vsnprintf(pm_msgp, size, fmt, adx); if (!pm_divertdebug) prom_printf("%s", pm_msgp); pm_msgp += size; } va_end(adx); mutex_exit(&pm_debug_lock); } #endif /* DEBUG */ /* * We want to save the state of any directly pm'd devices over the suspend/ * resume process so that we can put them back the way the controlling * process left them. */ void pm_save_direct_levels(void) { pm_processes_stopped = 1; ddi_walk_devs(ddi_root_node(), pm_save_direct_lvl_walk, 0); } static int pm_save_direct_lvl_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) int i; int *ip; pm_info_t *info = PM_GET_PM_INFO(dip); if (!info) return (DDI_WALK_CONTINUE); if (PM_ISDIRECT(dip) && !PM_ISBC(dip)) { if (PM_NUMCMPTS(dip) > 2) { info->pmi_lp = kmem_alloc(PM_NUMCMPTS(dip) * sizeof (int), KM_SLEEP); ip = info->pmi_lp; } else { ip = info->pmi_levels; } /* autopm and processes are stopped, ok not to lock power */ for (i = 0; i < PM_NUMCMPTS(dip); i++) *ip++ = PM_CURPOWER(dip, i); /* * There is a small window between stopping the * processes and setting pm_processes_stopped where * a driver could get hung up in a pm_raise_power() * call. Free any such driver now. */ pm_proceed(dip, PMP_RELEASE, -1, -1); } return (DDI_WALK_CONTINUE); } void pm_restore_direct_levels(void) { /* * If cpr didn't call pm_save_direct_levels, (because stopping user * threads failed) then we don't want to try to restore them */ if (!pm_processes_stopped) return; ddi_walk_devs(ddi_root_node(), pm_restore_direct_lvl_walk, 0); pm_processes_stopped = 0; } static int pm_restore_direct_lvl_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) PMD_FUNC(pmf, "restore_direct_lvl_walk") int i, nc, result; int *ip; pm_info_t *info = PM_GET_PM_INFO(dip); if (!info) return (DDI_WALK_CONTINUE); if (PM_ISDIRECT(dip) && !PM_ISBC(dip)) { if ((nc = PM_NUMCMPTS(dip)) > 2) { ip = &info->pmi_lp[nc - 1]; } else { ip = &info->pmi_levels[nc - 1]; } /* * Because fb drivers fail attempts to turn off the * fb when the monitor is on, but treat a request to * turn on the monitor as a request to turn on the * fb too, we process components in descending order * Because autopm is disabled and processes aren't * running, it is ok to examine current power outside * of the power lock */ for (i = nc - 1; i >= 0; i--, ip--) { if (PM_CURPOWER(dip, i) == *ip) continue; if (pm_set_power(dip, i, *ip, PM_LEVEL_EXACT, PM_CANBLOCK_BYPASS, 0, &result) != DDI_SUCCESS) { cmn_err(CE_WARN, "cpr: unable " "to restore power level of " "component %d of directly " "power manged device %s@%s" " to %d", i, PM_NAME(dip), PM_ADDR(dip), *ip); PMD(PMD_FAIL, ("%s: failed to restore " "%s@%s(%s#%d)[%d] exact(%d)->%d, " "errno %d\n", pmf, PM_DEVICE(dip), i, PM_CURPOWER(dip, i), *ip, result)) } } if (nc > 2) { kmem_free(info->pmi_lp, nc * sizeof (int)); info->pmi_lp = NULL; } } return (DDI_WALK_CONTINUE); } /* * Stolen from the bootdev module * attempt to convert a path to a major number */ static major_t i_path_to_major(char *path, char *leaf_name) { extern major_t path_to_major(char *pathname); major_t maj; if ((maj = path_to_major(path)) == (major_t)-1) { maj = ddi_name_to_major(leaf_name); } return (maj); } /* * When user calls rem_drv, we need to forget no-involuntary-power-cycles state * An entry in the list means that the device is detached, so we need to * adjust its ancestors as if they had just seen this attach, and any detached * ancestors need to have their list entries adjusted. */ void pm_driver_removed(major_t major) { static void i_pm_driver_removed(major_t major); /* * Serialize removal of drivers. This is to keep ancestors of * a node that is being deleted from getting deleted and added back * with different counters. */ mutex_enter(&pm_remdrv_lock); i_pm_driver_removed(major); mutex_exit(&pm_remdrv_lock); } /* * This routine is called recursively by pm_noinvol_process_ancestors() */ static void i_pm_driver_removed(major_t major) { PMD_FUNC(pmf, "driver_removed") static void adjust_ancestors(char *, int); static int pm_is_noinvol_ancestor(pm_noinvol_t *); static void pm_noinvol_process_ancestors(char *); pm_noinvol_t *ip, *pp = NULL; int wasvolpmd; ASSERT(major != (major_t)-1); PMD(PMD_NOINVOL, ("%s: %s\n", pmf, ddi_major_to_name(major))) again: rw_enter(&pm_noinvol_rwlock, RW_WRITER); for (ip = pm_noinvol_head; ip; pp = ip, ip = ip->ni_next) { if (major != ip->ni_major) continue; /* * If it is an ancestor of no-invol node, which is * not removed, skip it. This is to cover the case of * ancestor removed without removing its descendants. */ if (pm_is_noinvol_ancestor(ip)) { ip->ni_flags |= PMC_DRIVER_REMOVED; continue; } wasvolpmd = ip->ni_wasvolpmd; /* * remove the entry from the list */ if (pp) { PMD(PMD_NOINVOL, ("%s: freeing %s, prev is %s\n", pmf, ip->ni_path, pp->ni_path)) pp->ni_next = ip->ni_next; } else { PMD(PMD_NOINVOL, ("%s: free %s head\n", pmf, ip->ni_path)) ASSERT(pm_noinvol_head == ip); pm_noinvol_head = ip->ni_next; } rw_exit(&pm_noinvol_rwlock); adjust_ancestors(ip->ni_path, wasvolpmd); /* * Had an ancestor been removed before this node, it would have * been skipped. Adjust the no-invol counters for such skipped * ancestors. */ pm_noinvol_process_ancestors(ip->ni_path); kmem_free(ip->ni_path, ip->ni_size); kmem_free(ip, sizeof (*ip)); goto again; } rw_exit(&pm_noinvol_rwlock); } /* * returns 1, if *aip is a ancestor of a no-invol node * 0, otherwise */ static int pm_is_noinvol_ancestor(pm_noinvol_t *aip) { pm_noinvol_t *ip; ASSERT(strlen(aip->ni_path) != 0); for (ip = pm_noinvol_head; ip; ip = ip->ni_next) { if (ip == aip) continue; /* * To be an ancestor, the path must be an initial substring of * the descendent, and end just before a '/' in the * descendent's path. */ if ((strstr(ip->ni_path, aip->ni_path) == ip->ni_path) && (ip->ni_path[strlen(aip->ni_path)] == '/')) return (1); } return (0); } #define PM_MAJOR(dip) ddi_name_to_major(ddi_binding_name(dip)) /* * scan through the pm_noinvolpm list adjusting ancestors of the current * node; Modifies string *path. */ static void adjust_ancestors(char *path, int wasvolpmd) { PMD_FUNC(pmf, "adjust_ancestors") char *cp; pm_noinvol_t *lp; pm_noinvol_t *pp = NULL; major_t locked = (major_t)UINT_MAX; dev_info_t *dip; char *pathbuf; size_t pathbuflen = strlen(path) + 1; /* * First we look up the ancestor's dip. If we find it, then we * adjust counts up the tree */ PMD(PMD_NOINVOL, ("%s: %s wasvolpmd %d\n", pmf, path, wasvolpmd)) pathbuf = kmem_alloc(pathbuflen, KM_SLEEP); (void) strcpy(pathbuf, path); cp = strrchr(pathbuf, '/'); if (cp == NULL) { /* if no ancestors, then nothing to do */ kmem_free(pathbuf, pathbuflen); return; } *cp = '\0'; dip = pm_name_to_dip(pathbuf, 1); if (dip != NULL) { locked = PM_MAJOR(dip); (void) pm_noinvol_update(PM_BP_NOINVOL_REMDRV, 0, wasvolpmd, path, dip); if (locked != (major_t)UINT_MAX) ddi_release_devi(dip); } else { char *apath; size_t len = strlen(pathbuf) + 1; int lock_held = 1; /* * Now check for ancestors that exist only in the list */ apath = kmem_alloc(len, KM_SLEEP); (void) strcpy(apath, pathbuf); rw_enter(&pm_noinvol_rwlock, RW_WRITER); for (lp = pm_noinvol_head; lp; pp = lp, lp = lp->ni_next) { /* * This can only happen once. Since we have to drop * the lock, we need to extract the relevant info. */ if (strcmp(pathbuf, lp->ni_path) == 0) { PMD(PMD_NOINVOL, ("%s: %s no %d -> %d\n", pmf, lp->ni_path, lp->ni_noinvolpm, lp->ni_noinvolpm - 1)) lp->ni_noinvolpm--; if (wasvolpmd && lp->ni_volpmd) { PMD(PMD_NOINVOL, ("%s: %s vol %d -> " "%d\n", pmf, lp->ni_path, lp->ni_volpmd, lp->ni_volpmd - 1)) lp->ni_volpmd--; } /* * remove the entry from the list, if there * are no more no-invol descendants and node * itself is not a no-invol node. */ if (!(lp->ni_noinvolpm || (lp->ni_flags & PMC_NO_INVOL))) { ASSERT(lp->ni_volpmd == 0); if (pp) { PMD(PMD_NOINVOL, ("%s: freeing " "%s, prev is %s\n", pmf, lp->ni_path, pp->ni_path)) pp->ni_next = lp->ni_next; } else { PMD(PMD_NOINVOL, ("%s: free %s " "head\n", pmf, lp->ni_path)) ASSERT(pm_noinvol_head == lp); pm_noinvol_head = lp->ni_next; } lock_held = 0; rw_exit(&pm_noinvol_rwlock); adjust_ancestors(apath, wasvolpmd); /* restore apath */ (void) strcpy(apath, pathbuf); kmem_free(lp->ni_path, lp->ni_size); kmem_free(lp, sizeof (*lp)); } break; } } if (lock_held) rw_exit(&pm_noinvol_rwlock); adjust_ancestors(apath, wasvolpmd); kmem_free(apath, len); } kmem_free(pathbuf, pathbuflen); } /* * Do no-invol processing for any ancestors i.e. adjust counters of ancestors, * which were skipped even though their drivers were removed. */ static void pm_noinvol_process_ancestors(char *path) { pm_noinvol_t *lp; rw_enter(&pm_noinvol_rwlock, RW_READER); for (lp = pm_noinvol_head; lp; lp = lp->ni_next) { if (strstr(path, lp->ni_path) && (lp->ni_flags & PMC_DRIVER_REMOVED)) { rw_exit(&pm_noinvol_rwlock); i_pm_driver_removed(lp->ni_major); return; } } rw_exit(&pm_noinvol_rwlock); } /* * Returns true if (detached) device needs to be kept up because it exported the * "no-involuntary-power-cycles" property or we're pretending it did (console * fb case) or it is an ancestor of such a device and has used up the "one * free cycle" allowed when all such leaf nodes have voluntarily powered down * upon detach. In any event, we need an exact hit on the path or we return * false. */ int pm_noinvol_detached(char *path) { PMD_FUNC(pmf, "noinvol_detached") pm_noinvol_t *ip; int ret = 0; rw_enter(&pm_noinvol_rwlock, RW_READER); for (ip = pm_noinvol_head; ip; ip = ip->ni_next) { if (strcmp(path, ip->ni_path) == 0) { if (ip->ni_flags & PMC_CONSOLE_FB) { PMD(PMD_NOINVOL | PMD_CFB, ("%s: inhibits CFB " "%s\n", pmf, path)) ret = 1; break; } #ifdef DEBUG if (ip->ni_noinvolpm != ip->ni_volpmd) PMD(PMD_NOINVOL, ("%s: (%d != %d) inhibits %s" "\n", pmf, ip->ni_noinvolpm, ip->ni_volpmd, path)) #endif ret = (ip->ni_noinvolpm != ip->ni_volpmd); break; } } rw_exit(&pm_noinvol_rwlock); return (ret); } int pm_is_cfb(dev_info_t *dip) { return (dip == cfb_dip); } #ifdef DEBUG /* * Return true if all components of the console frame buffer are at * "normal" power, i.e., fully on. For the case where the console is not * a framebuffer, we also return true */ int pm_cfb_is_up(void) { return (pm_cfb_comps_off == 0); } #endif /* * Preventing scan from powering down the node by incrementing the * kidsupcnt. */ void pm_hold_power(dev_info_t *dip) { e_pm_hold_rele_power(dip, 1); } /* * Releasing the hold by decrementing the kidsupcnt allowing scan * to power down the node if all conditions are met. */ void pm_rele_power(dev_info_t *dip) { e_pm_hold_rele_power(dip, -1); } /* * A wrapper of pm_all_to_normal() to power up a dip * to its normal level */ int pm_powerup(dev_info_t *dip) { PMD_FUNC(pmf, "pm_powerup") PMD(PMD_ALLNORM, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) ASSERT(!(servicing_interrupt())); /* * in case this node is not already participating pm */ if (!PM_GET_PM_INFO(dip)) { if (!DEVI_IS_ATTACHING(dip)) return (DDI_SUCCESS); if (pm_start(dip) != DDI_SUCCESS) return (DDI_FAILURE); if (!PM_GET_PM_INFO(dip)) return (DDI_SUCCESS); } return (pm_all_to_normal(dip, PM_CANBLOCK_BLOCK)); } int pm_rescan_walk(dev_info_t *dip, void *arg) { _NOTE(ARGUNUSED(arg)) if (!PM_GET_PM_INFO(dip) || PM_ISBC(dip)) return (DDI_WALK_CONTINUE); /* * Currently pm_cpr_callb/resume code is the only caller * and it needs to make sure that stopped scan get * reactivated. Otherwise, rescan walk needn't reactive * stopped scan. */ pm_scan_init(dip); (void) pm_rescan(dip); return (DDI_WALK_CONTINUE); } static dev_info_t * pm_get_next_descendent(dev_info_t *dip, dev_info_t *tdip) { dev_info_t *wdip, *pdip; for (wdip = tdip; wdip != dip; wdip = pdip) { pdip = ddi_get_parent(wdip); if (pdip == dip) return (wdip); } return (NULL); } int pm_busop_bus_power(dev_info_t *dip, void *impl_arg, pm_bus_power_op_t op, void *arg, void *result) { PMD_FUNC(pmf, "bp_bus_power") dev_info_t *cdip; pm_info_t *cinfo; pm_bp_child_pwrchg_t *bpc; pm_sp_misc_t *pspm; pm_bp_nexus_pwrup_t *bpn; pm_bp_child_pwrchg_t new_bpc; pm_bp_noinvol_t *bpi; dev_info_t *tdip; char *pathbuf; int ret = DDI_SUCCESS; int errno = 0; pm_component_t *cp; PMD(PMD_SET, ("%s: %s@%s(%s#%d) %s\n", pmf, PM_DEVICE(dip), pm_decode_op(op))) switch (op) { case BUS_POWER_CHILD_PWRCHG: bpc = (pm_bp_child_pwrchg_t *)arg; pspm = (pm_sp_misc_t *)bpc->bpc_private; tdip = bpc->bpc_dip; cdip = pm_get_next_descendent(dip, tdip); cinfo = PM_GET_PM_INFO(cdip); if (cdip != tdip) { /* * If the node is an involved parent, it needs to * power up the node as it is needed. There is nothing * else the framework can do here. */ if (PM_WANTS_NOTIFICATION(cdip)) { PMD(PMD_SET, ("%s: call bus_power for " "%s@%s(%s#%d)\n", pmf, PM_DEVICE(cdip))) return ((*PM_BUS_POWER_FUNC(cdip))(cdip, impl_arg, op, arg, result)); } ASSERT(pspm->pspm_direction == PM_LEVEL_UPONLY || pspm->pspm_direction == PM_LEVEL_DOWNONLY || pspm->pspm_direction == PM_LEVEL_EXACT); /* * we presume that the parent needs to be up in * order for the child to change state (either * because it must already be on if the child is on * (and the pm_all_to_normal_nexus() will be a nop) * or because it will need to be on for the child * to come on; so we make the call regardless */ pm_hold_power(cdip); if (cinfo) { pm_canblock_t canblock = pspm->pspm_canblock; ret = pm_all_to_normal_nexus(cdip, canblock); if (ret != DDI_SUCCESS) { pm_rele_power(cdip); return (ret); } } PMD(PMD_SET, ("%s: walk down to %s@%s(%s#%d)\n", pmf, PM_DEVICE(cdip))) ret = pm_busop_bus_power(cdip, impl_arg, op, arg, result); pm_rele_power(cdip); } else { ret = pm_busop_set_power(cdip, impl_arg, op, arg, result); } return (ret); case BUS_POWER_NEXUS_PWRUP: bpn = (pm_bp_nexus_pwrup_t *)arg; pspm = (pm_sp_misc_t *)bpn->bpn_private; if (!e_pm_valid_info(dip, NULL) || !e_pm_valid_comp(dip, bpn->bpn_comp, &cp) || !e_pm_valid_power(dip, bpn->bpn_comp, bpn->bpn_level)) { PMD(PMD_SET, ("%s: %s@%s(%s#%d) has no pm info; EIO\n", pmf, PM_DEVICE(dip))) *pspm->pspm_errnop = EIO; *(int *)result = DDI_FAILURE; return (DDI_FAILURE); } ASSERT(bpn->bpn_dip == dip); PMD(PMD_SET, ("%s: nexus powerup for %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) new_bpc.bpc_dip = dip; pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); new_bpc.bpc_path = ddi_pathname(dip, pathbuf); new_bpc.bpc_comp = bpn->bpn_comp; new_bpc.bpc_olevel = PM_CURPOWER(dip, bpn->bpn_comp); new_bpc.bpc_nlevel = bpn->bpn_level; new_bpc.bpc_private = bpn->bpn_private; ((pm_sp_misc_t *)(new_bpc.bpc_private))->pspm_direction = PM_LEVEL_UPONLY; ((pm_sp_misc_t *)(new_bpc.bpc_private))->pspm_errnop = &errno; ret = pm_busop_set_power(dip, impl_arg, BUS_POWER_CHILD_PWRCHG, (void *)&new_bpc, result); kmem_free(pathbuf, MAXPATHLEN); return (ret); case BUS_POWER_NOINVOL: bpi = (pm_bp_noinvol_t *)arg; tdip = bpi->bpni_dip; cdip = pm_get_next_descendent(dip, tdip); /* In case of rem_drv, the leaf node has been removed */ if (cdip == NULL) return (DDI_SUCCESS); cinfo = PM_GET_PM_INFO(cdip); if (cdip != tdip) { if (PM_WANTS_NOTIFICATION(cdip)) { PMD(PMD_NOINVOL, ("%s: call bus_power for %s@%s(%s#%d)\n", pmf, PM_DEVICE(cdip))) ret = (*PM_BUS_POWER_FUNC(cdip)) (cdip, NULL, op, arg, result); if ((cinfo) && (ret == DDI_SUCCESS)) (void) pm_noinvol_update_node(cdip, bpi); return (ret); } else { PMD(PMD_NOINVOL, ("%s: walk down to %s@%s(%s#%d)\n", pmf, PM_DEVICE(cdip))) ret = pm_busop_bus_power(cdip, NULL, op, arg, result); /* * Update the current node. */ if ((cinfo) && (ret == DDI_SUCCESS)) (void) pm_noinvol_update_node(cdip, bpi); return (ret); } } else { /* * For attach, detach, power up: * Do nothing for leaf node since its * counts are already updated. * For CFB and driver removal, since the * path and the target dip passed in is up to and incl. * the immediate ancestor, need to do the update. */ PMD(PMD_NOINVOL, ("%s: target %s@%s(%s#%d) is " "reached\n", pmf, PM_DEVICE(cdip))) if (cinfo && ((bpi->bpni_cmd == PM_BP_NOINVOL_REMDRV) || (bpi->bpni_cmd == PM_BP_NOINVOL_CFB))) (void) pm_noinvol_update_node(cdip, bpi); return (DDI_SUCCESS); } default: PMD(PMD_SET, ("%s: operation %d is not supported!\n", pmf, op)) return (DDI_FAILURE); } } static int pm_busop_set_power(dev_info_t *dip, void *impl_arg, pm_bus_power_op_t op, void *arg, void *resultp) { _NOTE(ARGUNUSED(impl_arg)) PMD_FUNC(pmf, "bp_set_power") pm_ppm_devlist_t *devl; int clevel, circ; #ifdef DEBUG int circ_db, ccirc_db; #endif int ret = DDI_SUCCESS; dev_info_t *cdip; pm_bp_child_pwrchg_t *bpc = (pm_bp_child_pwrchg_t *)arg; pm_sp_misc_t *pspm = (pm_sp_misc_t *)bpc->bpc_private; pm_canblock_t canblock = pspm->pspm_canblock; int scan = pspm->pspm_scan; int comp = bpc->bpc_comp; int olevel = bpc->bpc_olevel; int nlevel = bpc->bpc_nlevel; int comps_off_incr = 0; dev_info_t *pdip = ddi_get_parent(dip); int dodeps; int direction = pspm->pspm_direction; int *errnop = pspm->pspm_errnop; char *dir = pm_decode_direction(direction); int *iresp = (int *)resultp; time_t idletime, thresh; pm_component_t *cp = PM_CP(dip, comp); int work_type; *iresp = DDI_SUCCESS; *errnop = 0; ASSERT(op == BUS_POWER_CHILD_PWRCHG); PMD(PMD_SET, ("%s: %s@%s(%s#%d) %s\n", pmf, PM_DEVICE(dip), pm_decode_op(op))) /* * The following set of conditions indicate we are here to handle a * driver's pm_[raise|lower]_power request, but the device is being * power managed (PM_DIRECT_PM) by a user process. For that case * we want to pm_block and pass a status back to the caller based * on whether the controlling process's next activity on the device * matches the current request or not. This distinction tells * downstream functions to avoid calling into a driver or changing * the framework's power state. To actually block, we need: * * PM_ISDIRECT(dip) * no reason to block unless a process is directly controlling dev * direction != PM_LEVEL_EXACT * EXACT is used by controlling proc's PM_SET_CURRENT_POWER ioctl * !pm_processes_stopped * don't block if controlling proc already be stopped for cpr * canblock != PM_CANBLOCK_BYPASS * our caller must not have explicitly prevented blocking */ if (direction != PM_LEVEL_EXACT && canblock != PM_CANBLOCK_BYPASS) { PM_LOCK_DIP(dip); while (PM_ISDIRECT(dip) && !pm_processes_stopped) { /* releases dip lock */ ret = pm_busop_match_request(dip, bpc); if (ret == EAGAIN) { PM_LOCK_DIP(dip); continue; } return (*iresp = ret); } PM_UNLOCK_DIP(dip); } /* BC device is never scanned, so power will stick until we are done */ if (PM_ISBC(dip) && comp != 0 && nlevel != 0 && direction != PM_LEVEL_DOWNONLY) { int nrmpwr0 = pm_get_normal_power(dip, 0); if (pm_set_power(dip, 0, nrmpwr0, direction, canblock, 0, resultp) != DDI_SUCCESS) { /* *resultp set by pm_set_power */ return (DDI_FAILURE); } } if (PM_WANTS_NOTIFICATION(pdip)) { PMD(PMD_SET, ("%s: pre_notify %s@%s(%s#%d) for child " "%s@%s(%s#%d)\n", pmf, PM_DEVICE(pdip), PM_DEVICE(dip))) ret = (*PM_BUS_POWER_FUNC(pdip))(pdip, NULL, BUS_POWER_PRE_NOTIFICATION, bpc, resultp); if (ret != DDI_SUCCESS) { PMD(PMD_SET, ("%s: failed to pre_notify %s@%s(%s#%d)\n", pmf, PM_DEVICE(pdip))) return (DDI_FAILURE); } } else { /* * Since we don't know what the actual power level is, * we place a power hold on the parent no matter what * component and level is changing. */ pm_hold_power(pdip); } PM_LOCK_POWER(dip, &circ); clevel = PM_CURPOWER(dip, comp); PMD(PMD_SET, ("%s: %s@%s(%s#%d), cmp=%d, olvl=%d, nlvl=%d, clvl=%d, " "dir=%s\n", pmf, PM_DEVICE(dip), comp, bpc->bpc_olevel, nlevel, clevel, dir)) switch (direction) { case PM_LEVEL_UPONLY: /* Powering up */ if (clevel >= nlevel) { PMD(PMD_SET, ("%s: current level is already " "at or above the requested level.\n", pmf)) *iresp = DDI_SUCCESS; ret = DDI_SUCCESS; goto post_notify; } break; case PM_LEVEL_EXACT: /* specific level request */ if (clevel == nlevel && !PM_ISBC(dip)) { PMD(PMD_SET, ("%s: current level is already " "at the requested level.\n", pmf)) *iresp = DDI_SUCCESS; ret = DDI_SUCCESS; goto post_notify; } else if (PM_IS_CFB(dip) && (nlevel < clevel)) { PMD(PMD_CFB, ("%s: powerdown of console\n", pmf)) if (!pm_cfb_enabled) { PMD(PMD_ERROR | PMD_CFB, ("%s: !pm_cfb_enabled, fails\n", pmf)) *errnop = EINVAL; *iresp = DDI_FAILURE; ret = DDI_FAILURE; goto post_notify; } mutex_enter(&pm_cfb_lock); while (cfb_inuse) { mutex_exit(&pm_cfb_lock); if (delay_sig(1) == EINTR) { ret = DDI_FAILURE; *iresp = DDI_FAILURE; *errnop = EINTR; goto post_notify; } mutex_enter(&pm_cfb_lock); } mutex_exit(&pm_cfb_lock); } break; case PM_LEVEL_DOWNONLY: /* Powering down */ thresh = cur_threshold(dip, comp); idletime = gethrestime_sec() - cp->pmc_timestamp; if (scan && ((PM_KUC(dip) != 0) || (cp->pmc_busycount > 0) || ((idletime < thresh) && !PM_IS_PID(dip)))) { #ifdef DEBUG if (DEVI(dip)->devi_pm_kidsupcnt != 0) PMD(PMD_SET, ("%s: scan failed: " "kidsupcnt != 0\n", pmf)) if (cp->pmc_busycount > 0) PMD(PMD_SET, ("%s: scan failed: " "device become busy\n", pmf)) if (idletime < thresh) PMD(PMD_SET, ("%s: scan failed: device " "hasn't been idle long enough\n", pmf)) #endif *iresp = DDI_FAILURE; *errnop = EBUSY; ret = DDI_FAILURE; goto post_notify; } else if (clevel != PM_LEVEL_UNKNOWN && clevel <= nlevel) { PMD(PMD_SET, ("%s: current level is already at " "or below the requested level.\n", pmf)) *iresp = DDI_SUCCESS; ret = DDI_SUCCESS; goto post_notify; } break; } if (PM_IS_CFB(dip) && (comps_off_incr = calc_cfb_comps_incr(dip, comp, clevel, nlevel)) > 0) { /* * Pre-adjust pm_cfb_comps_off if lowering a console fb * component from full power. Remember that we tried to * lower power in case it fails and we need to back out * the adjustment. */ update_comps_off(comps_off_incr, dip); PMD(PMD_CFB, ("%s: %s@%s(%s#%d)[%d] %d->%d cfb_comps_off->%d\n", pmf, PM_DEVICE(dip), comp, clevel, nlevel, pm_cfb_comps_off)) } if ((*iresp = power_dev(dip, comp, nlevel, clevel, canblock, &devl)) == DDI_SUCCESS) { #ifdef DEBUG /* * All descendents of this node should already be powered off. */ if (PM_CURPOWER(dip, comp) == 0) { pm_desc_pwrchk_t pdpchk; pdpchk.pdpc_dip = dip; pdpchk.pdpc_par_involved = PM_WANTS_NOTIFICATION(dip); ndi_devi_enter(dip, &circ_db); for (cdip = ddi_get_child(dip); cdip != NULL; cdip = ddi_get_next_sibling(cdip)) { ndi_devi_enter(cdip, &ccirc_db); ddi_walk_devs(cdip, pm_desc_pwrchk_walk, (void *)&pdpchk); ndi_devi_exit(cdip, ccirc_db); } ndi_devi_exit(dip, circ_db); } #endif /* * Post-adjust pm_cfb_comps_off if we brought an fb component * back up to full power. */ if (PM_IS_CFB(dip) && comps_off_incr < 0) { update_comps_off(comps_off_incr, dip); PMD(PMD_CFB, ("%s: %s@%s(%s#%d)[%d] %d->%d " "cfb_comps_off->%d\n", pmf, PM_DEVICE(dip), comp, clevel, nlevel, pm_cfb_comps_off)) } dodeps = 0; if (POWERING_OFF(clevel, nlevel)) { if (PM_ISBC(dip)) { dodeps = (comp == 0); } else { int i; dodeps = 1; for (i = 0; i < PM_NUMCMPTS(dip); i++) { /* if some component still on */ if (PM_CURPOWER(dip, i)) { dodeps = 0; break; } } } if (dodeps) work_type = PM_DEP_WK_POWER_OFF; } else if (POWERING_ON(clevel, nlevel)) { if (PM_ISBC(dip)) { dodeps = (comp == 0); } else { int i; dodeps = 1; for (i = 0; i < PM_NUMCMPTS(dip); i++) { if (i == comp) continue; if (PM_CURPOWER(dip, i) > 0) { dodeps = 0; break; } } } if (dodeps) work_type = PM_DEP_WK_POWER_ON; } if (dodeps) { char *pathbuf = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, pathbuf); pm_dispatch_to_dep_thread(work_type, pathbuf, NULL, PM_DEP_NOWAIT, NULL, 0); kmem_free(pathbuf, MAXPATHLEN); } if ((PM_CURPOWER(dip, comp) == nlevel) && pm_watchers()) { int old; /* If old power cached during deadlock, use it. */ old = (cp->pmc_flags & PM_PHC_WHILE_SET_POWER ? cp->pmc_phc_pwr : olevel); mutex_enter(&pm_rsvp_lock); pm_enqueue_notify(PSC_HAS_CHANGED, dip, comp, nlevel, old, canblock); pm_enqueue_notify_others(&devl, canblock); mutex_exit(&pm_rsvp_lock); } /* * If we are coming from a scan, don't do it again, * else we can have infinite loops. */ if (!scan) pm_rescan(dip); } else { /* if we incremented pm_comps_off_count, but failed */ if (comps_off_incr > 0) { update_comps_off(-comps_off_incr, dip); PMD(PMD_CFB, ("%s: %s@%s(%s#%d)[%d] %d->%d " "cfb_comps_off->%d\n", pmf, PM_DEVICE(dip), comp, clevel, nlevel, pm_cfb_comps_off)) } *errnop = EIO; } post_notify: /* * This thread may have been in deadlock with pm_power_has_changed. * Before releasing power lock, clear the flag which marks this * condition. */ cp->pmc_flags &= ~PM_PHC_WHILE_SET_POWER; /* * Update the old power level in the bus power structure with the * actual power level before the transition was made to the new level. * Some involved parents depend on this information to keep track of * their children's power transition. */ if (*iresp != DDI_FAILURE) bpc->bpc_olevel = clevel; if (PM_WANTS_NOTIFICATION(pdip)) { ret = (*PM_BUS_POWER_FUNC(pdip))(pdip, NULL, BUS_POWER_POST_NOTIFICATION, bpc, resultp); PM_UNLOCK_POWER(dip, circ); PMD(PMD_SET, ("%s: post_notify %s@%s(%s#%d) for " "child %s@%s(%s#%d), ret=%d\n", pmf, PM_DEVICE(pdip), PM_DEVICE(dip), ret)) } else { nlevel = cur_power(cp); /* in case phc deadlock updated pwr */ PM_UNLOCK_POWER(dip, circ); /* * Now that we know what power transition has occurred * (if any), release the power hold. Leave the hold * in effect in the case of OFF->ON transition. */ if (!(clevel == 0 && nlevel > 0 && (!PM_ISBC(dip) || comp == 0))) pm_rele_power(pdip); /* * If the power transition was an ON->OFF transition, * remove the power hold from the parent. */ if ((clevel > 0 || clevel == PM_LEVEL_UNKNOWN) && nlevel == 0 && (!PM_ISBC(dip) || comp == 0)) pm_rele_power(pdip); } if (*iresp != DDI_SUCCESS || ret != DDI_SUCCESS) return (DDI_FAILURE); else return (DDI_SUCCESS); } /* * If an app (SunVTS or Xsun) has taken control, then block until it * gives it up or makes the requested power level change, unless * we have other instructions about blocking. Returns DDI_SUCCESS, * DDI_FAILURE or EAGAIN (owner released device from directpm). */ static int pm_busop_match_request(dev_info_t *dip, void *arg) { PMD_FUNC(pmf, "bp_match_request") pm_bp_child_pwrchg_t *bpc = (pm_bp_child_pwrchg_t *)arg; pm_sp_misc_t *pspm = (pm_sp_misc_t *)bpc->bpc_private; int comp = bpc->bpc_comp; int nlevel = bpc->bpc_nlevel; pm_canblock_t canblock = pspm->pspm_canblock; int direction = pspm->pspm_direction; int clevel, circ; ASSERT(PM_IAM_LOCKING_DIP(dip)); PM_LOCK_POWER(dip, &circ); clevel = PM_CURPOWER(dip, comp); PMD(PMD_SET, ("%s: %s@%s(%s#%d), cmp=%d, nlvl=%d, clvl=%d\n", pmf, PM_DEVICE(dip), comp, nlevel, clevel)) if (direction == PM_LEVEL_UPONLY) { if (clevel >= nlevel) { PM_UNLOCK_POWER(dip, circ); PM_UNLOCK_DIP(dip); return (DDI_SUCCESS); } } else if (clevel == nlevel) { PM_UNLOCK_POWER(dip, circ); PM_UNLOCK_DIP(dip); return (DDI_SUCCESS); } if (canblock == PM_CANBLOCK_FAIL) { PM_UNLOCK_POWER(dip, circ); PM_UNLOCK_DIP(dip); return (DDI_FAILURE); } if (canblock == PM_CANBLOCK_BLOCK) { /* * To avoid a deadlock, we must not hold the * power lock when we pm_block. */ PM_UNLOCK_POWER(dip, circ); PMD(PMD_SET, ("%s: blocking\n", pmf)) /* pm_block releases dip lock */ switch (pm_block(dip, comp, nlevel, clevel)) { case PMP_RELEASE: return (EAGAIN); case PMP_SUCCEED: return (DDI_SUCCESS); case PMP_FAIL: return (DDI_FAILURE); } } else { ASSERT(0); } _NOTE(NOTREACHED); return (DDI_FAILURE); /* keep gcc happy */ } static int pm_all_to_normal_nexus(dev_info_t *dip, pm_canblock_t canblock) { PMD_FUNC(pmf, "all_to_normal_nexus") int *normal; int i, ncomps; size_t size; int changefailed = 0; int ret, result = DDI_SUCCESS; pm_bp_nexus_pwrup_t bpn; pm_sp_misc_t pspm; ASSERT(PM_GET_PM_INFO(dip)); PMD(PMD_ALLNORM, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) if (pm_get_norm_pwrs(dip, &normal, &size) != DDI_SUCCESS) { PMD(PMD_ALLNORM, ("%s: can't get norm pwrs\n", pmf)) return (DDI_FAILURE); } ncomps = PM_NUMCMPTS(dip); for (i = 0; i < ncomps; i++) { bpn.bpn_dip = dip; bpn.bpn_comp = i; bpn.bpn_level = normal[i]; pspm.pspm_canblock = canblock; pspm.pspm_scan = 0; bpn.bpn_private = &pspm; ret = pm_busop_bus_power(dip, NULL, BUS_POWER_NEXUS_PWRUP, (void *)&bpn, (void *)&result); if (ret != DDI_SUCCESS || result != DDI_SUCCESS) { PMD(PMD_FAIL | PMD_ALLNORM, ("%s: %s@%s(%s#%d)[%d] " "->%d failure result %d\n", pmf, PM_DEVICE(dip), i, normal[i], result)) changefailed++; } } kmem_free(normal, size); if (changefailed) { PMD(PMD_FAIL, ("%s: failed to set %d comps %s@%s(%s#%d) " "full power\n", pmf, changefailed, PM_DEVICE(dip))) return (DDI_FAILURE); } return (DDI_SUCCESS); } int pm_noinvol_update(int subcmd, int volpmd, int wasvolpmd, char *path, dev_info_t *tdip) { PMD_FUNC(pmf, "noinvol_update") pm_bp_noinvol_t args; int ret; int result = DDI_SUCCESS; args.bpni_path = path; args.bpni_dip = tdip; args.bpni_cmd = subcmd; args.bpni_wasvolpmd = wasvolpmd; args.bpni_volpmd = volpmd; PMD(PMD_NOINVOL, ("%s: update for path %s tdip %p subcmd %d " "volpmd %d wasvolpmd %d\n", pmf, path, (void *)tdip, subcmd, wasvolpmd, volpmd)) ret = pm_busop_bus_power(ddi_root_node(), NULL, BUS_POWER_NOINVOL, &args, &result); return (ret); } void pm_noinvol_update_node(dev_info_t *dip, pm_bp_noinvol_t *req) { PMD_FUNC(pmf, "noinvol_update_node") PMD(PMD_NOINVOL, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) switch (req->bpni_cmd) { case PM_BP_NOINVOL_ATTACH: PMD(PMD_NOINVOL, ("%s: PM_PB_NOINVOL_ATTACH %s@%s(%s#%d) " "noinvol %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_noinvolpm, DEVI(dip)->devi_pm_noinvolpm - 1)) ASSERT(DEVI(dip)->devi_pm_noinvolpm); PM_LOCK_DIP(dip); DEVI(dip)->devi_pm_noinvolpm--; if (req->bpni_wasvolpmd) { PMD(PMD_NOINVOL, ("%s: PM_BP_NOINVOL_ATTACH " "%s@%s(%s#%d) volpmd %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_volpmd, DEVI(dip)->devi_pm_volpmd - 1)) if (DEVI(dip)->devi_pm_volpmd) DEVI(dip)->devi_pm_volpmd--; } PM_UNLOCK_DIP(dip); break; case PM_BP_NOINVOL_DETACH: PMD(PMD_NOINVOL, ("%s: PM_BP_NOINVOL_DETACH %s@%s(%s#%d) " "noinvolpm %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_noinvolpm, DEVI(dip)->devi_pm_noinvolpm + 1)) PM_LOCK_DIP(dip); DEVI(dip)->devi_pm_noinvolpm++; if (req->bpni_wasvolpmd) { PMD(PMD_NOINVOL, ("%s: PM_BP_NOINVOL_DETACH " "%s@%s(%s#%d) volpmd %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_volpmd, DEVI(dip)->devi_pm_volpmd + 1)) DEVI(dip)->devi_pm_volpmd++; } PM_UNLOCK_DIP(dip); break; case PM_BP_NOINVOL_REMDRV: PMD(PMD_NOINVOL, ("%s: PM_BP_NOINVOL_REMDRV %s@%s(%s#%d) " "noinvol %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_noinvolpm, DEVI(dip)->devi_pm_noinvolpm - 1)) ASSERT(DEVI(dip)->devi_pm_noinvolpm); PM_LOCK_DIP(dip); DEVI(dip)->devi_pm_noinvolpm--; if (req->bpni_wasvolpmd) { PMD(PMD_NOINVOL, ("%s: PM_BP_NOINVOL_REMDRV %s@%s(%s#%d) " "volpmd %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_volpmd, DEVI(dip)->devi_pm_volpmd - 1)) /* * A power up could come in between and * clear the volpmd, if that's the case, * volpmd would be clear. */ if (DEVI(dip)->devi_pm_volpmd) DEVI(dip)->devi_pm_volpmd--; } PM_UNLOCK_DIP(dip); break; case PM_BP_NOINVOL_CFB: PMD(PMD_NOINVOL, ("%s: PM_BP_NOIVOL_CFB %s@%s(%s#%d) noinvol %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_noinvolpm, DEVI(dip)->devi_pm_noinvolpm + 1)) PM_LOCK_DIP(dip); DEVI(dip)->devi_pm_noinvolpm++; PM_UNLOCK_DIP(dip); break; case PM_BP_NOINVOL_POWER: PMD(PMD_NOINVOL, ("%s: PM_BP_NOIVOL_PWR %s@%s(%s#%d) volpmd %d->%d\n", pmf, PM_DEVICE(dip), DEVI(dip)->devi_pm_volpmd, DEVI(dip)->devi_pm_volpmd - req->bpni_volpmd)) PM_LOCK_DIP(dip); DEVI(dip)->devi_pm_volpmd -= req->bpni_volpmd; PM_UNLOCK_DIP(dip); break; default: break; } } #ifdef DEBUG static int pm_desc_pwrchk_walk(dev_info_t *dip, void *arg) { PMD_FUNC(pmf, "desc_pwrchk") pm_desc_pwrchk_t *pdpchk = (pm_desc_pwrchk_t *)arg; pm_info_t *info = PM_GET_PM_INFO(dip); int i, curpwr, ce_level; if (!info) return (DDI_WALK_CONTINUE); PMD(PMD_SET, ("%s: %s@%s(%s#%d)\n", pmf, PM_DEVICE(dip))) for (i = 0; i < PM_NUMCMPTS(dip); i++) { if ((curpwr = PM_CURPOWER(dip, i)) == 0) continue; ce_level = (pdpchk->pdpc_par_involved == 0) ? CE_PANIC : CE_WARN; PMD(PMD_SET, ("%s: %s@%s(%s#%d) is powered off while desc " "%s@%s(%s#%d)[%d] is at %d\n", pmf, PM_DEVICE(pdpchk->pdpc_dip), PM_DEVICE(dip), i, curpwr)) cmn_err(ce_level, "!device %s@%s(%s#%d) is powered on, " "while its ancestor, %s@%s(%s#%d), is powering off!", PM_DEVICE(dip), PM_DEVICE(pdpchk->pdpc_dip)); } return (DDI_WALK_CONTINUE); } #endif /* * Record the fact that one thread is borrowing the lock on a device node. * Use is restricted to the case where the lending thread will block until * the borrowing thread (always curthread) completes. */ void pm_borrow_lock(kthread_t *lender) { lock_loan_t *prev = &lock_loan_head; lock_loan_t *cur = (lock_loan_t *)kmem_zalloc(sizeof (*cur), KM_SLEEP); cur->pmlk_borrower = curthread; cur->pmlk_lender = lender; mutex_enter(&pm_loan_lock); cur->pmlk_next = prev->pmlk_next; prev->pmlk_next = cur; mutex_exit(&pm_loan_lock); } /* * Return the borrowed lock. A thread can borrow only one. */ void pm_return_lock(void) { lock_loan_t *cur; lock_loan_t *prev = &lock_loan_head; mutex_enter(&pm_loan_lock); ASSERT(prev->pmlk_next != NULL); for (cur = prev->pmlk_next; cur; prev = cur, cur = cur->pmlk_next) if (cur->pmlk_borrower == curthread) break; ASSERT(cur != NULL); prev->pmlk_next = cur->pmlk_next; mutex_exit(&pm_loan_lock); kmem_free(cur, sizeof (*cur)); }