/* * 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 2010 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Sun4v OS Suspend * * Provides a means to suspend a sun4v guest domain by pausing CPUs and then * calling into the HV to initiate a suspension. Suspension is sequenced * externally by calling suspend_pre, suspend_start, and suspend_post. * suspend_pre and suspend_post are meant to perform any special operations * that should be done before or after a suspend/resume operation. e.g., * callbacks to cluster software to disable heartbeat monitoring before the * system is suspended. suspend_start prepares kernel services to be suspended * and then suspends the domain by calling hv_guest_suspend. * * Special Handling for %tick and %stick Registers * * After a suspend/resume operation, the %tick and %stick registers may have * jumped forwards or backwards. The delta is assumed to be consistent across * all CPUs, within the negligible level of %tick and %stick variation * acceptable on a cold boot. In order to maintain increasing %tick and %stick * counter values without exposing large positive or negative jumps to kernel * or user code, a %tick and %stick offset is used. Kernel reads of these * counters return the sum of the hardware register counter and offset * variable. After a suspend/resume operation, user reads of %tick or %stick * are emulated. Suspend code enables emulation by setting the * %{tick,stick}.NPT fields which trigger a privileged instruction access * trap whenever the registers are read from user mode. If emulation has been * enabled, the trap handler emulates the instruction. Emulation is only * enabled during a successful suspend/resume operation. When emulation is * enabled, CPUs that are DR'd into the system will have their * %{tick,stick}.NPT bits set to 1 as well. */ extern u_longlong_t gettick(void); /* returns %stick */ extern uint64_t gettick_counter(void); /* returns %tick */ extern uint64_t gettick_npt(void); extern uint64_t getstick_npt(void); extern int mach_descrip_update(void); extern cpuset_t cpu_ready_set; extern uint64_t native_tick_offset; extern uint64_t native_stick_offset; extern uint64_t sys_tick_freq; /* * Global Sun Cluster pre/post callbacks. */ const char *(*cl_suspend_error_decode)(int); int (*cl_suspend_pre_callback)(void); int (*cl_suspend_post_callback)(void); #define SC_PRE_FAIL_STR_FMT "Sun Cluster pre-suspend failure: %d" #define SC_POST_FAIL_STR_FMT "Sun Cluster post-suspend failure: %d" #define SC_FAIL_STR_MAX 256 /* * The minimum major and minor version of the HSVC_GROUP_CORE API group * required in order to use OS suspend. */ #define SUSPEND_CORE_MAJOR 1 #define SUSPEND_CORE_MINOR 2 /* * By default, sun4v OS suspend is supported if the required HV version * is present. suspend_disabled should be set on platforms that do not * allow OS suspend regardless of whether or not the HV supports it. * It can also be set in /etc/system. */ static int suspend_disabled = 0; /* * Controls whether or not user-land tick and stick register emulation * will be enabled following a successful suspend operation. */ static int enable_user_tick_stick_emulation = 1; /* * Indicates whether or not tick and stick emulation is currently active. * After a successful suspend operation, if emulation is enabled, this * variable is set to B_TRUE. Global scope to allow emulation code to * check if emulation is active. */ boolean_t tick_stick_emulation_active = B_FALSE; /* * When non-zero, after a successful suspend and resume, cpunodes, CPU HW * sharing data structures, and processor groups will be updated using * information from the updated MD. */ static int suspend_update_cpu_mappings = 1; /* * The maximum number of microseconds by which the %tick or %stick register * can vary between any two CPUs in the system. To calculate the * native_stick_offset and native_tick_offset, we measure the change in these * registers on one CPU over a suspend/resume. Other CPUs may experience * slightly larger or smaller changes. %tick and %stick should be synchronized * between CPUs, but there may be some variation. So we add an additional value * derived from this variable to ensure that these registers always increase * over a suspend/resume operation, assuming all %tick and %stick registers * are synchronized (within a certain limit) across CPUs in the system. The * delta between %sticks on different CPUs should be a small number of cycles, * not perceptible to readers of %stick that migrate between CPUs. We set this * value to 1 millisecond which means that over a suspend/resume operation, * all CPU's %tick and %stick will advance forwards as long as, across all * CPUs, the %tick and %stick are synchronized to within 1 ms. This applies to * CPUs before the suspend and CPUs after the resume. 1 ms is conservative, * but small enough to not trigger TOD faults. */ static uint64_t suspend_tick_stick_max_delta = 1000; /* microseconds */ /* * DBG and DBG_PROM() macro. */ #ifdef DEBUG static int suspend_debug_flag = 0; #define DBG_PROM \ if (suspend_debug_flag) \ prom_printf #define DBG \ if (suspend_debug_flag) \ suspend_debug static void suspend_debug(const char *fmt, ...) { char buf[512]; va_list ap; va_start(ap, fmt); (void) vsprintf(buf, fmt, ap); va_end(ap); cmn_err(CE_NOTE, "%s", buf); } #else /* DEBUG */ #define DBG_PROM #define DBG #endif /* DEBUG */ /* * Return true if the HV supports OS suspend and if suspend has not been * disabled on this platform. */ boolean_t suspend_supported(void) { uint64_t major, minor; if (suspend_disabled) return (B_FALSE); if (hsvc_version(HSVC_GROUP_CORE, &major, &minor) != 0) return (B_FALSE); return ((major == SUSPEND_CORE_MAJOR && minor >= SUSPEND_CORE_MINOR) || (major > SUSPEND_CORE_MAJOR)); } /* * Given a source tick, stick, and tod value, set the tick and stick offsets * such that the (current physical register value) + offset == (source value) * and in addition account for some variation between the %tick/%stick on * different CPUs. We account for this variation by adding in double the value * of suspend_tick_stick_max_delta. The following is an explanation of why * suspend_tick_stick_max_delta must be multplied by two and added to * native_stick_offset. * * Consider a guest instance that is yet to be suspended with CPUs p0 and p1 * with physical "source" %stick values s0 and s1 respectively. When the guest * is first resumed, the physical "target" %stick values are t0 and t1 * respectively. The virtual %stick values after the resume are v0 and v1 * respectively. Let x be the maximum difference between any two CPU's %stick * register at a given point in time and let the %stick values be assigned * such that * * s1 = s0 + x and * t1 = t0 - x * * Let us assume that p0 is driving the suspend and resume. Then, we will * calculate the stick offset f and the virtual %stick on p0 after the * resume as follows. * * f = s0 - t0 and * v0 = t0 + f * * We calculate the virtual %stick v1 on p1 after the resume as * * v1 = t1 + f * * Substitution yields * * v1 = t1 + (s0 - t0) * v1 = (t0 - x) + (s0 - t0) * v1 = -x + s0 * v1 = s0 - x * v1 = (s1 - x) - x * v1 = s1 - 2x * * Therefore, in this scenario, without accounting for %stick variation in * the calculation of the native_stick_offset f, the virtual %stick on p1 * is less than the value of the %stick on p1 before the suspend which is * unacceptable. By adding 2x to v1, we guarantee it will be equal to s1 * which means the %stick on p1 after the resume will always be greater * than or equal to the %stick on p1 before the suspend. Since v1 = t1 + f * at any point in time, we can accomplish this by adding 2x to f. This * guarantees any processes bound to CPU P0 or P1 will not see a %stick * decrease across a suspend/resume. Hence, in the code below, we multiply * suspend_tick_stick_max_delta by two in the calculation for * native_stick_offset, native_tick_offset, and target_hrtime. */ static void set_tick_offsets(uint64_t source_tick, uint64_t source_stick, timestruc_t *tsp) { uint64_t target_tick; uint64_t target_stick; hrtime_t source_hrtime; hrtime_t target_hrtime; /* * Temporarily set the offsets to zero so that the following reads * of the registers will yield physical unadjusted counter values. */ native_tick_offset = 0; native_stick_offset = 0; target_tick = gettick_counter(); /* returns %tick */ target_stick = gettick(); /* returns %stick */ /* * Calculate the new offsets. In addition to the delta observed on * this CPU, add an additional value. Multiply the %tick/%stick * frequency by suspend_tick_stick_max_delta (us). Then, multiply by 2 * to account for a delta between CPUs before the suspend and a * delta between CPUs after the resume. */ native_tick_offset = (source_tick - target_tick) + (CPU->cpu_curr_clock * suspend_tick_stick_max_delta * 2 / MICROSEC); native_stick_offset = (source_stick - target_stick) + (sys_tick_freq * suspend_tick_stick_max_delta * 2 / MICROSEC); /* * We've effectively increased %stick and %tick by twice the value * of suspend_tick_stick_max_delta to account for variation across * CPUs. Now adjust the preserved TOD by the same amount. */ source_hrtime = ts2hrt(tsp); target_hrtime = source_hrtime + (suspend_tick_stick_max_delta * 2 * (NANOSEC/MICROSEC)); hrt2ts(target_hrtime, tsp); } /* * Set the {tick,stick}.NPT field to 1 on this CPU. */ static void enable_tick_stick_npt(void) { (void) hv_stick_set_npt(1); (void) hv_tick_set_npt(1); } /* * Synchronize a CPU's {tick,stick}.NPT fields with the current state * of the system. This is used when a CPU is DR'd into the system. */ void suspend_sync_tick_stick_npt(void) { if (tick_stick_emulation_active) { DBG("enabling {%%tick/%%stick}.NPT on CPU 0x%x", CPU->cpu_id); (void) hv_stick_set_npt(1); (void) hv_tick_set_npt(1); } else { ASSERT(gettick_npt() == 0); ASSERT(getstick_npt() == 0); } } /* * Obtain an updated MD from the hypervisor and update cpunodes, CPU HW * sharing data structures, and processor groups. */ static void update_cpu_mappings(void) { md_t *mdp; processorid_t id; cpu_t *cp; cpu_pg_t *pgps[NCPU]; if ((mdp = md_get_handle()) == NULL) { DBG("suspend: md_get_handle failed"); return; } DBG("suspend: updating CPU mappings"); mutex_enter(&cpu_lock); setup_chip_mappings(mdp); setup_exec_unit_mappings(mdp); for (id = 0; id < NCPU; id++) { if ((cp = cpu_get(id)) == NULL) continue; cpu_map_exec_units(cp); } /* * Re-calculate processor groups. * * First tear down all PG information before adding any new PG * information derived from the MD we just downloaded. We must * call pg_cpu_inactive and pg_cpu_active with CPUs paused and * we want to minimize the number of times pause_cpus is called. * Inactivating all CPUs would leave PGs without any active CPUs, * so while CPUs are paused, call pg_cpu_inactive and swap in the * bootstrap PG structure saving the original PG structure to be * fini'd afterwards. This prevents the dispatcher from encountering * PGs in which all CPUs are inactive. */ pause_cpus(NULL); for (id = 0; id < NCPU; id++) { if ((cp = cpu_get(id)) == NULL) continue; pg_cpu_inactive(cp); pgps[id] = cp->cpu_pg; pg_cpu_bootstrap(cp); } start_cpus(); /* * pg_cpu_fini* and pg_cpu_init* must be called while CPUs are * not paused. Use two separate loops here so that we do not * initialize PG data for CPUs until all the old PG data structures * are torn down. */ for (id = 0; id < NCPU; id++) { if ((cp = cpu_get(id)) == NULL) continue; pg_cpu_fini(cp, pgps[id]); mpo_cpu_remove(id); } /* * Initialize PG data for each CPU, but leave the bootstrapped * PG structure in place to avoid running with any PGs containing * nothing but inactive CPUs. */ for (id = 0; id < NCPU; id++) { if ((cp = cpu_get(id)) == NULL) continue; mpo_cpu_add(mdp, id); pgps[id] = pg_cpu_init(cp, B_TRUE); } /* * Now that PG data has been initialized for all CPUs in the * system, replace the bootstrapped PG structure with the * initialized PG structure and call pg_cpu_active for each CPU. */ pause_cpus(NULL); for (id = 0; id < NCPU; id++) { if ((cp = cpu_get(id)) == NULL) continue; cp->cpu_pg = pgps[id]; pg_cpu_active(cp); } start_cpus(); mutex_exit(&cpu_lock); (void) md_fini_handle(mdp); } /* * Wrapper for the Sun Cluster error decoding function. */ static int cluster_error_decode(int error, char *error_reason, size_t max_reason_len) { const char *decoded; size_t decoded_len; ASSERT(error_reason != NULL); ASSERT(max_reason_len > 0); max_reason_len = MIN(max_reason_len, SC_FAIL_STR_MAX); if (cl_suspend_error_decode == NULL) return (-1); if ((decoded = (*cl_suspend_error_decode)(error)) == NULL) return (-1); /* Get number of non-NULL bytes */ if ((decoded_len = strnlen(decoded, max_reason_len - 1)) == 0) return (-1); bcopy(decoded, error_reason, decoded_len); /* * The error string returned from cl_suspend_error_decode * should be NULL-terminated, but set the terminator here * because we only copied non-NULL bytes. If the decoded * string was not NULL-terminated, this guarantees that * error_reason will be. */ error_reason[decoded_len] = '\0'; return (0); } /* * Wrapper for the Sun Cluster pre-suspend callback. */ static int cluster_pre_wrapper(char *error_reason, size_t max_reason_len) { int rv = 0; if (cl_suspend_pre_callback != NULL) { rv = (*cl_suspend_pre_callback)(); DBG("suspend: cl_suspend_pre_callback returned %d", rv); if (rv != 0 && error_reason != NULL && max_reason_len > 0) { if (cluster_error_decode(rv, error_reason, max_reason_len)) { (void) snprintf(error_reason, max_reason_len, SC_PRE_FAIL_STR_FMT, rv); } } } return (rv); } /* * Wrapper for the Sun Cluster post-suspend callback. */ static int cluster_post_wrapper(char *error_reason, size_t max_reason_len) { int rv = 0; if (cl_suspend_post_callback != NULL) { rv = (*cl_suspend_post_callback)(); DBG("suspend: cl_suspend_post_callback returned %d", rv); if (rv != 0 && error_reason != NULL && max_reason_len > 0) { if (cluster_error_decode(rv, error_reason, max_reason_len)) { (void) snprintf(error_reason, max_reason_len, SC_POST_FAIL_STR_FMT, rv); } } } return (rv); } /* * Execute pre-suspend callbacks preparing the system for a suspend operation. * Returns zero on success, non-zero on failure. Sets the recovered argument * to indicate whether or not callbacks could be undone in the event of a * failure--if callbacks were successfully undone, *recovered is set to B_TRUE, * otherwise *recovered is set to B_FALSE. Must be called successfully before * suspend_start can be called. Callers should first call suspend_support to * determine if OS suspend is supported. */ int suspend_pre(char *error_reason, size_t max_reason_len, boolean_t *recovered) { int rv; ASSERT(recovered != NULL); /* * Return an error if suspend_pre is erreoneously called * when OS suspend is not supported. */ ASSERT(suspend_supported()); if (!suspend_supported()) { DBG("suspend: suspend_pre called without suspend support"); *recovered = B_TRUE; return (ENOTSUP); } DBG("suspend: %s", __func__); rv = cluster_pre_wrapper(error_reason, max_reason_len); /* * At present, only one pre-suspend operation exists. * If it fails, no recovery needs to be done. */ if (rv != 0 && recovered != NULL) *recovered = B_TRUE; return (rv); } /* * Execute post-suspend callbacks. Returns zero on success, non-zero on * failure. Must be called after suspend_start is called, regardless of * whether or not suspend_start is successful. */ int suspend_post(char *error_reason, size_t max_reason_len) { ASSERT(suspend_supported()); DBG("suspend: %s", __func__); return (cluster_post_wrapper(error_reason, max_reason_len)); } /* * Suspends the OS by pausing CPUs and calling into the HV to initiate * the suspend. When the HV routine hv_guest_suspend returns, the system * will be resumed. Must be called after a successful call to suspend_pre. * suspend_post must be called after suspend_start, whether or not * suspend_start returns an error. */ /*ARGSUSED*/ int suspend_start(char *error_reason, size_t max_reason_len) { uint64_t source_tick; uint64_t source_stick; uint64_t rv; timestruc_t source_tod; int spl; ASSERT(suspend_supported()); DBG("suspend: %s", __func__); sfmmu_ctxdoms_lock(); mutex_enter(&cpu_lock); /* Suspend the watchdog */ watchdog_suspend(); /* Record the TOD */ mutex_enter(&tod_lock); source_tod = tod_get(); mutex_exit(&tod_lock); /* Pause all other CPUs */ pause_cpus(NULL); DBG_PROM("suspend: CPUs paused\n"); /* Suspend cyclics */ cyclic_suspend(); DBG_PROM("suspend: cyclics suspended\n"); /* Disable interrupts */ spl = spl8(); DBG_PROM("suspend: spl8()\n"); source_tick = gettick_counter(); source_stick = gettick(); DBG_PROM("suspend: source_tick: 0x%lx\n", source_tick); DBG_PROM("suspend: source_stick: 0x%lx\n", source_stick); /* * Call into the HV to initiate the suspend. hv_guest_suspend() * returns after the guest has been resumed or if the suspend * operation failed or was cancelled. After a successful suspend, * the %tick and %stick registers may have changed by an amount * that is not proportional to the amount of time that has passed. * They may have jumped forwards or backwards. Some variation is * allowed and accounted for using suspend_tick_stick_max_delta, * but otherwise this jump must be uniform across all CPUs and we * operate under the assumption that it is (maintaining two global * offset variables--one for %tick and one for %stick.) */ DBG_PROM("suspend: suspending... \n"); rv = hv_guest_suspend(); if (rv != 0) { splx(spl); cyclic_resume(); start_cpus(); watchdog_resume(); mutex_exit(&cpu_lock); sfmmu_ctxdoms_unlock(); DBG("suspend: failed, rv: %ld\n", rv); return (rv); } /* Update the global tick and stick offsets and the preserved TOD */ set_tick_offsets(source_tick, source_stick, &source_tod); /* Ensure new offsets are globally visible before resuming CPUs */ membar_sync(); /* Enable interrupts */ splx(spl); /* Set the {%tick,%stick}.NPT bits on all CPUs */ if (enable_user_tick_stick_emulation) { xc_all((xcfunc_t *)enable_tick_stick_npt, NULL, NULL); xt_sync(cpu_ready_set); ASSERT(gettick_npt() != 0); ASSERT(getstick_npt() != 0); } /* If emulation is enabled, but not currently active, enable it */ if (enable_user_tick_stick_emulation && !tick_stick_emulation_active) { tick_stick_emulation_active = B_TRUE; } sfmmu_ctxdoms_remove(); /* Resume cyclics, unpause CPUs */ cyclic_resume(); start_cpus(); /* Set the TOD */ mutex_enter(&tod_lock); tod_set(source_tod); mutex_exit(&tod_lock); /* Re-enable the watchdog */ watchdog_resume(); mutex_exit(&cpu_lock); /* Download the latest MD */ if ((rv = mach_descrip_update()) != 0) cmn_err(CE_PANIC, "suspend: mach_descrip_update failed: %ld", rv); sfmmu_ctxdoms_update(); sfmmu_ctxdoms_unlock(); /* Get new MD, update CPU mappings/relationships */ if (suspend_update_cpu_mappings) update_cpu_mappings(); DBG("suspend: target tick: 0x%lx", gettick_counter()); DBG("suspend: target stick: 0x%llx", gettick()); DBG("suspend: user %%tick/%%stick emulation is %d", tick_stick_emulation_active); DBG("suspend: finished"); return (0); }