/* * Copyright (c) 2013, ARM Limited. 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_on_handler)(unsigned long, aff_map_node *, unsigned long, unsigned long); /******************************************************************************* * This function checks whether a cpu which has been requested to be turned on * is OFF to begin with. ******************************************************************************/ static int cpu_on_validate_state(unsigned int state) { unsigned int psci_state; /* Get the raw psci state */ psci_state = psci_get_state(state); if (psci_state == PSCI_STATE_ON || psci_state == PSCI_STATE_SUSPEND) return PSCI_E_ALREADY_ON; if (psci_state == PSCI_STATE_ON_PENDING) return PSCI_E_ON_PENDING; assert(psci_state == PSCI_STATE_OFF); return PSCI_E_SUCCESS; } /******************************************************************************* * Handler routine to turn a cpu on. It takes care of any generic, architectural * or platform specific setup required. * TODO: Split this code across separate handlers for each type of setup? ******************************************************************************/ static int psci_afflvl0_on(unsigned long target_cpu, aff_map_node *cpu_node, unsigned long ns_entrypoint, unsigned long context_id) { unsigned int index, plat_state; unsigned long psci_entrypoint; int rc; /* Sanity check to safeguard against data corruption */ assert(cpu_node->level == MPIDR_AFFLVL0); /* * Generic management: Ensure that the cpu is off to be * turned on */ rc = cpu_on_validate_state(cpu_node->state); if (rc != PSCI_E_SUCCESS) return rc; /* * Arch. management: Derive the re-entry information for * the non-secure world from the non-secure state from * where this call originated. */ index = cpu_node->data; rc = psci_set_ns_entry_info(index, ns_entrypoint, context_id); if (rc != PSCI_E_SUCCESS) return rc; /* Set the secure world (EL3) re-entry point after BL1 */ psci_entrypoint = (unsigned long) psci_aff_on_finish_entry; /* * Plat. management: Give the platform the current state * of the target cpu to allow it to perform the necessary * steps to power on. */ if (psci_plat_pm_ops->affinst_on) { /* Get the current physical state of this cpu */ plat_state = psci_get_aff_phys_state(cpu_node); rc = psci_plat_pm_ops->affinst_on(target_cpu, psci_entrypoint, ns_entrypoint, cpu_node->level, plat_state); } return rc; } /******************************************************************************* * Handler routine to turn a cluster on. It takes care or any generic, arch. * or platform specific setup required. * TODO: Split this code across separate handlers for each type of setup? ******************************************************************************/ static int psci_afflvl1_on(unsigned long target_cpu, aff_map_node *cluster_node, unsigned long ns_entrypoint, unsigned long context_id) { int rc = PSCI_E_SUCCESS; unsigned int plat_state; unsigned long psci_entrypoint; assert(cluster_node->level == MPIDR_AFFLVL1); /* * There is no generic and arch. specific cluster * management required */ /* * Plat. management: Give the platform the current state * of the target cpu to allow it to perform the necessary * steps to power on. */ if (psci_plat_pm_ops->affinst_on) { plat_state = psci_get_aff_phys_state(cluster_node); psci_entrypoint = (unsigned long) psci_aff_on_finish_entry; rc = psci_plat_pm_ops->affinst_on(target_cpu, psci_entrypoint, ns_entrypoint, cluster_node->level, plat_state); } return rc; } /******************************************************************************* * Handler routine to turn a cluster of clusters on. It takes care or any * generic, arch. or platform specific setup required. * TODO: Split this code across separate handlers for each type of setup? ******************************************************************************/ static int psci_afflvl2_on(unsigned long target_cpu, aff_map_node *system_node, unsigned long ns_entrypoint, unsigned long context_id) { int rc = PSCI_E_SUCCESS; unsigned int plat_state; unsigned long psci_entrypoint; /* Cannot go beyond affinity level 2 in this psci imp. */ assert(system_node->level == MPIDR_AFFLVL2); /* * There is no generic and arch. specific system management * required */ /* * Plat. management: Give the platform the current state * of the target cpu to allow it to perform the necessary * steps to power on. */ if (psci_plat_pm_ops->affinst_on) { plat_state = psci_get_aff_phys_state(system_node); psci_entrypoint = (unsigned long) psci_aff_on_finish_entry; rc = psci_plat_pm_ops->affinst_on(target_cpu, psci_entrypoint, ns_entrypoint, system_node->level, plat_state); } return rc; } /* Private data structure to make this handlers accessible through indexing */ static const afflvl_on_handler psci_afflvl_on_handlers[] = { psci_afflvl0_on, psci_afflvl1_on, psci_afflvl2_on, }; /******************************************************************************* * This function implements the core of the processing required to turn a cpu * on. It avoids recursion to traverse from the lowest to the highest affinity * level unlike the off/suspend/pon_finisher functions. It does ensure that the * locks are picked in the same order as the order routines to avoid deadlocks. * The flow is: Take all the locks until the highest affinity level, Call the * handlers for turning an affinity level on & finally change the state of the * affinity level. ******************************************************************************/ int psci_afflvl_on(unsigned long target_cpu, unsigned long entrypoint, unsigned long context_id, int current_afflvl, int target_afflvl) { unsigned int prev_state, next_state; int rc = PSCI_E_SUCCESS, level; aff_map_node *aff_node; unsigned long mpidr = read_mpidr() & MPIDR_AFFINITY_MASK; /* * This loop acquires the lock corresponding to each * affinity level so that by the time we hit the lowest * affinity level, the system topology is snapshot and * state management can be done safely. */ for (level = current_afflvl; level >= target_afflvl; level--) { aff_node = psci_get_aff_map_node(target_cpu, level); if (aff_node) bakery_lock_get(mpidr, &aff_node->lock); } /* * Perform generic, architecture and platform specific * handling */ for (level = current_afflvl; level >= target_afflvl; level--) { /* Grab the node for each affinity level once again */ aff_node = psci_get_aff_map_node(target_cpu, level); if (aff_node) { /* Keep the old state and the next one handy */ prev_state = psci_get_state(aff_node->state); rc = psci_afflvl_on_handlers[level](target_cpu, aff_node, entrypoint, context_id); if (rc != PSCI_E_SUCCESS) { psci_set_state(aff_node->state, prev_state); goto exit; } } } /* * State management: Update the states since this is the * target affinity level requested. */ psci_change_state(target_cpu, target_afflvl, get_max_afflvl(), PSCI_STATE_ON_PENDING); exit: /* * This loop releases the lock corresponding to each affinity level * in the reverse order. It also checks the final state of the cpu. */ for (level = target_afflvl; level <= current_afflvl; level++) { aff_node = psci_get_aff_map_node(target_cpu, level); if (aff_node) { if (level == MPIDR_AFFLVL0) { next_state = psci_get_state(aff_node->state); assert(next_state == PSCI_STATE_ON_PENDING); } bakery_lock_release(mpidr, &aff_node->lock); } } return rc; } /******************************************************************************* * The following functions finish an earlier affinity power on request. They * are called by the common finisher routine in psci_common.c. ******************************************************************************/ static unsigned int psci_afflvl0_on_finish(unsigned long mpidr, aff_map_node *cpu_node, unsigned int prev_state) { unsigned int index, plat_state, rc = PSCI_E_SUCCESS; assert(cpu_node->level == MPIDR_AFFLVL0); /* * Plat. management: Perform the platform specific actions * for this cpu e.g. enabling the gic or zeroing the mailbox * register. The actual state of this cpu has already been * changed. */ if (psci_plat_pm_ops->affinst_on_finish) { /* Get the previous physical state of this cpu */ plat_state = psci_get_phys_state(prev_state); rc = psci_plat_pm_ops->affinst_on_finish(mpidr, cpu_node->level, plat_state); assert(rc == PSCI_E_SUCCESS); } /* * Arch. management: Turn on mmu & restore architectural state */ write_vbar((unsigned long) runtime_exceptions); enable_mmu(); /* * All the platform specific actions for turning this cpu * on have completed. Perform enough arch.initialization * to run in the non-secure address space. */ bl31_arch_setup(); /* * Generic management: Now we just need to retrieve the * information that we had stashed away during the cpu_on * call to set this cpu on it's way. First get the index * for restoring the re-entry info */ index = cpu_node->data; 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_on_finish(unsigned long mpidr, aff_map_node *cluster_node, unsigned int prev_state) { unsigned int rc = PSCI_E_SUCCESS; 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_on_finish) { plat_state = psci_get_phys_state(prev_state); rc = psci_plat_pm_ops->affinst_on_finish(mpidr, cluster_node->level, plat_state); assert(rc == PSCI_E_SUCCESS); } return rc; } static unsigned int psci_afflvl2_on_finish(unsigned long mpidr, aff_map_node *system_node, unsigned int prev_state) { 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_on_finish) { plat_state = psci_get_phys_state(system_node->state); rc = psci_plat_pm_ops->affinst_on_finish(mpidr, system_node->level, plat_state); assert(rc == PSCI_E_SUCCESS); } return rc; } const afflvl_power_on_finisher psci_afflvl_on_finishers[] = { psci_afflvl0_on_finish, psci_afflvl1_on_finish, psci_afflvl2_on_finish, };