/* * Copyright (c) 2013, ARM Limited and Contributors. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of ARM nor the names of its contributors may be used * to endorse or promote products derived from this software without specific * prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include typedef int (*afflvl_suspend_handler)(unsigned long, aff_map_node *, unsigned long, unsigned long, unsigned int); /******************************************************************************* * The next three functions implement a handler for each supported affinity * level which is called when that affinity level is about to be suspended. ******************************************************************************/ static int psci_afflvl0_suspend(unsigned long mpidr, aff_map_node *cpu_node, unsigned long ns_entrypoint, unsigned long context_id, unsigned int power_state) { unsigned int index, plat_state; unsigned long psci_entrypoint, sctlr = read_sctlr(); int rc = PSCI_E_SUCCESS; /* Sanity check to safeguard against data corruption */ assert(cpu_node->level == MPIDR_AFFLVL0); /* * Generic management: Store the re-entry information for the * non-secure world */ index = cpu_node->data; rc = psci_set_ns_entry_info(index, ns_entrypoint, context_id); if (rc != PSCI_E_SUCCESS) return rc; /* * Arch. management: Save the secure context, flush the * L1 caches and exit intra-cluster coherency et al */ psci_secure_context[index].sctlr = read_sctlr(); psci_secure_context[index].scr = read_scr(); psci_secure_context[index].cptr = read_cptr(); psci_secure_context[index].cpacr = read_cpacr(); psci_secure_context[index].cntfrq = read_cntfrq_el0(); psci_secure_context[index].mair = read_mair(); psci_secure_context[index].tcr = read_tcr(); psci_secure_context[index].ttbr = read_ttbr0(); psci_secure_context[index].vbar = read_vbar(); psci_secure_context[index].pstate = read_daif() & (DAIF_ABT_BIT | DAIF_DBG_BIT); /* Set the secure world (EL3) re-entry point after BL1 */ psci_entrypoint = (unsigned long) psci_aff_suspend_finish_entry; /* * Arch. management. Perform the necessary steps to flush all * cpu caches. * * TODO: This power down sequence varies across cpus so it needs to be * abstracted out on the basis of the MIDR like in cpu_reset_handler(). * Do the bare minimal for the time being. Fix this before porting to * Cortex models. */ sctlr &= ~SCTLR_C_BIT; write_sctlr(sctlr); /* * CAUTION: This flush to the level of unification makes an assumption * about the cache hierarchy at affinity level 0 (cpu) in the platform. * Ideally the platform should tell psci which levels to flush to exit * coherency. */ dcsw_op_louis(DCCISW); /* * Plat. management: Allow the platform to perform the * necessary actions to turn off this cpu e.g. set the * platform defined mailbox with the psci entrypoint, * program the power controller etc. */ if (psci_plat_pm_ops->affinst_suspend) { plat_state = psci_get_aff_phys_state(cpu_node); rc = psci_plat_pm_ops->affinst_suspend(mpidr, psci_entrypoint, ns_entrypoint, cpu_node->level, plat_state); } return rc; } static int psci_afflvl1_suspend(unsigned long mpidr, aff_map_node *cluster_node, unsigned long ns_entrypoint, unsigned long context_id, unsigned int power_state) { int rc = PSCI_E_SUCCESS; unsigned int plat_state; unsigned long psci_entrypoint; /* Sanity check the cluster level */ assert(cluster_node->level == MPIDR_AFFLVL1); /* * Keep the physical state of this cluster handy to decide * what action needs to be taken */ plat_state = psci_get_aff_phys_state(cluster_node); /* * Arch. management: Flush all levels of caches to PoC if the * cluster is to be shutdown */ if (plat_state == PSCI_STATE_OFF) dcsw_op_all(DCCISW); /* * Plat. Management. Allow the platform to do it's cluster * specific bookeeping e.g. turn off interconnect coherency, * program the power controller etc. */ if (psci_plat_pm_ops->affinst_suspend) { /* * Sending the psci entrypoint is currently redundant * beyond affinity level 0 but one never knows what a * platform might do. Also it allows us to keep the * platform handler prototype the same. */ psci_entrypoint = (unsigned long) psci_aff_suspend_finish_entry; rc = psci_plat_pm_ops->affinst_suspend(mpidr, psci_entrypoint, ns_entrypoint, cluster_node->level, plat_state); } return rc; } static int psci_afflvl2_suspend(unsigned long mpidr, aff_map_node *system_node, unsigned long ns_entrypoint, unsigned long context_id, unsigned int power_state) { int rc = PSCI_E_SUCCESS; unsigned int plat_state; unsigned long psci_entrypoint; /* Cannot go beyond this */ assert(system_node->level == MPIDR_AFFLVL2); /* * Keep the physical state of the system handy to decide what * action needs to be taken */ plat_state = psci_get_aff_phys_state(system_node); /* * Plat. Management : Allow the platform to do it's bookeeping * at this affinity level */ if (psci_plat_pm_ops->affinst_suspend) { /* * Sending the psci entrypoint is currently redundant * beyond affinity level 0 but one never knows what a * platform might do. Also it allows us to keep the * platform handler prototype the same. */ psci_entrypoint = (unsigned long) psci_aff_suspend_finish_entry; rc = psci_plat_pm_ops->affinst_suspend(mpidr, psci_entrypoint, ns_entrypoint, system_node->level, plat_state); } return rc; } static const afflvl_suspend_handler psci_afflvl_suspend_handlers[] = { psci_afflvl0_suspend, psci_afflvl1_suspend, psci_afflvl2_suspend, }; /******************************************************************************* * This function implements the core of the processing required to suspend a cpu * It'S assumed that along with suspending the cpu, higher affinity levels will * be suspended as far as possible. Suspending a cpu is equivalent to physically * powering it down, but the cpu is still available to the OS for scheduling. * We first need to determine the new state off all the affinity instances in * the mpidr corresponding to the target cpu. Action will be taken on the basis * of this new state. To do the state change we first need to acquire the locks * for all the implemented affinity level to be able to snapshot the system * state. Then we need to start suspending affinity levels from the lowest to * the highest (e.g. a cpu needs to be suspended before a cluster can be). To * achieve this flow, we start acquiring the locks from the highest to the * lowest affinity level. Once we reach affinity level 0, we do the state change * followed by the actions corresponding to the new state for affinity level 0. * Actions as per the updated state for higher affinity levels are performed as * we unwind back to highest affinity level. ******************************************************************************/ int psci_afflvl_suspend(unsigned long mpidr, unsigned long entrypoint, unsigned long context_id, unsigned int power_state, int cur_afflvl, int tgt_afflvl) { int rc = PSCI_E_SUCCESS, level; unsigned int prev_state, next_state; aff_map_node *aff_node; mpidr &= MPIDR_AFFINITY_MASK; /* * Some affinity instances at levels between the current and * target levels could be absent in the mpidr. Skip them and * start from the first present instance. */ level = psci_get_first_present_afflvl(mpidr, cur_afflvl, tgt_afflvl, &aff_node); /* * Return if there are no more affinity instances beyond this * level to process. Else ensure that the returned affinity * node makes sense. */ if (aff_node == NULL) return rc; assert(level == aff_node->level); /* * This function acquires the lock corresponding to each * affinity level so that state management can be done safely. */ bakery_lock_get(mpidr, &aff_node->lock); /* Keep the old state and the next one handy */ prev_state = psci_get_state(aff_node->state); next_state = PSCI_STATE_SUSPEND; /* * We start from the highest affinity level and work our way * downwards to the lowest i.e. MPIDR_AFFLVL0. */ if (aff_node->level == tgt_afflvl) { psci_change_state(mpidr, tgt_afflvl, get_max_afflvl(), next_state); } else { rc = psci_afflvl_suspend(mpidr, entrypoint, context_id, power_state, level - 1, tgt_afflvl); if (rc != PSCI_E_SUCCESS) { psci_set_state(aff_node->state, prev_state); goto exit; } } /* * Perform generic, architecture and platform specific * handling */ rc = psci_afflvl_suspend_handlers[level](mpidr, aff_node, entrypoint, context_id, power_state); if (rc != PSCI_E_SUCCESS) { psci_set_state(aff_node->state, prev_state); goto exit; } /* * If all has gone as per plan then this cpu should be * marked as OFF */ if (level == MPIDR_AFFLVL0) { next_state = psci_get_state(aff_node->state); assert(next_state == PSCI_STATE_SUSPEND); } exit: bakery_lock_release(mpidr, &aff_node->lock); return rc; } /******************************************************************************* * The following functions finish an earlier affinity suspend request. They * are called by the common finisher routine in psci_common.c. ******************************************************************************/ static unsigned int psci_afflvl0_suspend_finish(unsigned long mpidr, aff_map_node *cpu_node, unsigned int prev_state) { unsigned int index, plat_state, rc = 0; assert(cpu_node->level == MPIDR_AFFLVL0); /* * Plat. management: Perform the platform specific actions * before we change the state of the cpu e.g. enabling the * gic or zeroing the mailbox register. If anything goes * wrong then assert as there is no way to recover from this * situation. */ if (psci_plat_pm_ops->affinst_suspend_finish) { plat_state = psci_get_phys_state(prev_state); rc = psci_plat_pm_ops->affinst_suspend_finish(mpidr, cpu_node->level, plat_state); assert(rc == PSCI_E_SUCCESS); } /* Get the index for restoring the re-entry information */ index = cpu_node->data; /* * Arch. management: Restore the stashed secure architectural * context in the right order. */ write_vbar(psci_secure_context[index].vbar); write_daif(read_daif() | psci_secure_context[index].pstate); write_mair(psci_secure_context[index].mair); write_tcr(psci_secure_context[index].tcr); write_ttbr0(psci_secure_context[index].ttbr); write_sctlr(psci_secure_context[index].sctlr); /* MMU and coherency should be enabled by now */ write_scr(psci_secure_context[index].scr); write_cptr(psci_secure_context[index].cptr); write_cpacr(psci_secure_context[index].cpacr); write_cntfrq_el0(psci_secure_context[index].cntfrq); /* * Generic management: Now we just need to retrieve the * information that we had stashed away during the suspend * call to set this cpu on it's way. */ rc = psci_get_ns_entry_info(index); /* Clean caches before re-entering normal world */ dcsw_op_louis(DCCSW); return rc; } static unsigned int psci_afflvl1_suspend_finish(unsigned long mpidr, aff_map_node *cluster_node, unsigned int prev_state) { unsigned int rc = 0; unsigned int plat_state; assert(cluster_node->level == MPIDR_AFFLVL1); /* * Plat. management: Perform the platform specific actions * as per the old state of the cluster e.g. enabling * coherency at the interconnect depends upon the state with * which this cluster was powered up. If anything goes wrong * then assert as there is no way to recover from this * situation. */ if (psci_plat_pm_ops->affinst_suspend_finish) { plat_state = psci_get_phys_state(prev_state); rc = psci_plat_pm_ops->affinst_suspend_finish(mpidr, cluster_node->level, plat_state); assert(rc == PSCI_E_SUCCESS); } return rc; } static unsigned int psci_afflvl2_suspend_finish(unsigned long mpidr, aff_map_node *system_node, unsigned int target_afflvl) { int rc = PSCI_E_SUCCESS; unsigned int plat_state; /* Cannot go beyond this affinity level */ assert(system_node->level == MPIDR_AFFLVL2); /* * Currently, there are no architectural actions to perform * at the system level. */ /* * Plat. management: Perform the platform specific actions * as per the old state of the cluster e.g. enabling * coherency at the interconnect depends upon the state with * which this cluster was powered up. If anything goes wrong * then assert as there is no way to recover from this * situation. */ if (psci_plat_pm_ops->affinst_suspend_finish) { plat_state = psci_get_phys_state(system_node->state); rc = psci_plat_pm_ops->affinst_suspend_finish(mpidr, system_node->level, plat_state); assert(rc == PSCI_E_SUCCESS); } return rc; } const afflvl_power_on_finisher psci_afflvl_suspend_finishers[] = { psci_afflvl0_suspend_finish, psci_afflvl1_suspend_finish, psci_afflvl2_suspend_finish, };