lib/psci/psci_setup.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2013-2020, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <assert.h>
 #include <stddef.h>

 #include <arch.h>
 #include <arch_helpers.h>
 #include <common/bl_common.h>
 #include <context.h>
 #include <lib/el3_runtime/context_mgmt.h>
 #include <lib/cpus/errata_report.h>
 #include <plat/common/platform.h>

 #include "psci_private.h"

 /*******************************************************************************
  * Per cpu non-secure contexts used to program the architectural state prior
  * return to the normal world.
  * TODO: Use the memory allocator to set aside memory for the contexts instead
  * of relying on platform defined constants.
  ******************************************************************************/
 static cpu_context_t psci_ns_context[PLATFORM_CORE_COUNT];

 /******************************************************************************
  * Define the psci capability variable.
  *****************************************************************************/
 unsigned int psci_caps;

 /*******************************************************************************
  * Function which initializes the 'psci_non_cpu_pd_nodes' or the
  * 'psci_cpu_pd_nodes' corresponding to the power level.
  ******************************************************************************/
 static void __init psci_init_pwr_domain_node(unsigned char node_idx,
 					unsigned int parent_idx,
 					unsigned char level)
 {
 	if (level > PSCI_CPU_PWR_LVL) {
 		psci_non_cpu_pd_nodes[node_idx].level = level;
 		psci_lock_init(psci_non_cpu_pd_nodes, node_idx);
 		psci_non_cpu_pd_nodes[node_idx].parent_node = parent_idx;
 		psci_non_cpu_pd_nodes[node_idx].local_state =
 							 PLAT_MAX_OFF_STATE;
 	} else {
 		psci_cpu_data_t *svc_cpu_data;

 		psci_cpu_pd_nodes[node_idx].parent_node = parent_idx;

 		/* Initialize with an invalid mpidr */
 		psci_cpu_pd_nodes[node_idx].mpidr = PSCI_INVALID_MPIDR;

 		svc_cpu_data =
 			&(_cpu_data_by_index(node_idx)->psci_svc_cpu_data);

 		/* Set the Affinity Info for the cores as OFF */
 		svc_cpu_data->aff_info_state = AFF_STATE_OFF;

 		/* Invalidate the suspend level for the cpu */
 		svc_cpu_data->target_pwrlvl = PSCI_INVALID_PWR_LVL;

 		/* Set the power state to OFF state */
 		svc_cpu_data->local_state = PLAT_MAX_OFF_STATE;

 		psci_flush_dcache_range((uintptr_t)svc_cpu_data,
 						 sizeof(*svc_cpu_data));

 		cm_set_context_by_index(node_idx,
 					(void *) &psci_ns_context[node_idx],
 					NON_SECURE);
 	}
 }

 /*******************************************************************************
  * This functions updates cpu_start_idx and ncpus field for each of the node in
  * psci_non_cpu_pd_nodes[]. It does so by comparing the parent nodes of each of
  * the CPUs and check whether they match with the parent of the previous
  * CPU. The basic assumption for this work is that children of the same parent
  * are allocated adjacent indices. The platform should ensure this though proper
  * mapping of the CPUs to indices via plat_core_pos_by_mpidr() and
  * plat_my_core_pos() APIs.
  *******************************************************************************/
 static void __init psci_update_pwrlvl_limits(void)
 {
 	unsigned int cpu_idx;
 	int j;
 	unsigned int nodes_idx[PLAT_MAX_PWR_LVL] = {0};
 	unsigned int temp_index[PLAT_MAX_PWR_LVL];

 	for (cpu_idx = 0; cpu_idx < psci_plat_core_count; cpu_idx++) {
 		psci_get_parent_pwr_domain_nodes(cpu_idx,
 						 PLAT_MAX_PWR_LVL,
 						 temp_index);
 		for (j = (int)PLAT_MAX_PWR_LVL - 1; j >= 0; j--) {
 			if (temp_index[j] != nodes_idx[j]) {
 				nodes_idx[j] = temp_index[j];
 				psci_non_cpu_pd_nodes[nodes_idx[j]].cpu_start_idx
 					= cpu_idx;
 			}
 			psci_non_cpu_pd_nodes[nodes_idx[j]].ncpus++;
 		}
 	}
 }

 /*******************************************************************************
  * Core routine to populate the power domain tree. The tree descriptor passed by
  * the platform is populated breadth-first and the first entry in the map
  * informs the number of root power domains. The parent nodes of the root nodes
  * will point to an invalid entry(-1).
  ******************************************************************************/
 static unsigned int __init populate_power_domain_tree(const unsigned char
 							*topology)
 {
 	unsigned int i, j = 0U, num_nodes_at_lvl = 1U, num_nodes_at_next_lvl;
 	unsigned int node_index = 0U, num_children;
 	unsigned int parent_node_index = 0U;
 	int level = (int)PLAT_MAX_PWR_LVL;

 	/*
 	 * For each level the inputs are:
 	 * - number of nodes at this level in plat_array i.e. num_nodes_at_level
 	 *   This is the sum of values of nodes at the parent level.
 	 * - Index of first entry at this level in the plat_array i.e.
 	 *   parent_node_index.
 	 * - Index of first free entry in psci_non_cpu_pd_nodes[] or
 	 *   psci_cpu_pd_nodes[] i.e. node_index depending upon the level.
 	 */
 	while (level >= (int) PSCI_CPU_PWR_LVL) {
 		num_nodes_at_next_lvl = 0U;
 		/*
 		 * For each entry (parent node) at this level in the plat_array:
 		 * - Find the number of children
 		 * - Allocate a node in a power domain array for each child
 		 * - Set the parent of the child to the parent_node_index - 1
 		 * - Increment parent_node_index to point to the next parent
 		 * - Accumulate the number of children at next level.
 		 */
 		for (i = 0U; i < num_nodes_at_lvl; i++) {
 			assert(parent_node_index <=
 					PSCI_NUM_NON_CPU_PWR_DOMAINS);
 			num_children = topology[parent_node_index];

 			for (j = node_index;
 				j < (node_index + num_children); j++)
 				psci_init_pwr_domain_node((unsigned char)j,
 						  parent_node_index - 1U,
 						  (unsigned char)level);

 			node_index = j;
 			num_nodes_at_next_lvl += num_children;
 			parent_node_index++;
 		}

 		num_nodes_at_lvl = num_nodes_at_next_lvl;
 		level--;

 		/* Reset the index for the cpu power domain array */
 		if (level == (int) PSCI_CPU_PWR_LVL)
 			node_index = 0;
 	}

 	/* Validate the sanity of array exported by the platform */
 	assert(j <= PLATFORM_CORE_COUNT);
 	return j;
 }

 /*******************************************************************************
  * This function does the architectural setup and takes the warm boot
  * entry-point `mailbox_ep` as an argument. The function also initializes the
  * power domain topology tree by querying the platform. The power domain nodes
  * higher than the CPU are populated in the array psci_non_cpu_pd_nodes[] and
  * the CPU power domains are populated in psci_cpu_pd_nodes[]. The platform
  * exports its static topology map through the
  * populate_power_domain_topology_tree() API. The algorithm populates the
  * psci_non_cpu_pd_nodes and psci_cpu_pd_nodes iteratively by using this
  * topology map.  On a platform that implements two clusters of 2 cpus each,
  * and supporting 3 domain levels, the populated psci_non_cpu_pd_nodes would
  * look like this:
  *
  * ---------------------------------------------------
  * | system node | cluster 0 node  | cluster 1 node  |
  * ---------------------------------------------------
  *
  * And populated psci_cpu_pd_nodes would look like this :
  * <-    cpus cluster0   -><-   cpus cluster1   ->
  * ------------------------------------------------
  * |   CPU 0   |   CPU 1   |   CPU 2   |   CPU 3  |
  * ------------------------------------------------
  ******************************************************************************/
 int __init psci_setup(const psci_lib_args_t *lib_args)
 {
 	const unsigned char *topology_tree;

 	assert(VERIFY_PSCI_LIB_ARGS_V1(lib_args));

 	/* Do the Architectural initialization */
 	psci_arch_setup();

 	/* Query the topology map from the platform */
 	topology_tree = plat_get_power_domain_tree_desc();

 	/* Populate the power domain arrays using the platform topology map */
 	psci_plat_core_count = populate_power_domain_tree(topology_tree);

 	/* Update the CPU limits for each node in psci_non_cpu_pd_nodes */
 	psci_update_pwrlvl_limits();

 	/* Populate the mpidr field of cpu node for this CPU */
 	psci_cpu_pd_nodes[plat_my_core_pos()].mpidr =
 		read_mpidr() & MPIDR_AFFINITY_MASK;

 	psci_init_req_local_pwr_states();

 	/*
 	 * Set the requested and target state of this CPU and all the higher
 	 * power domain levels for this CPU to run.
 	 */
 	psci_set_pwr_domains_to_run(PLAT_MAX_PWR_LVL);

 	(void) plat_setup_psci_ops((uintptr_t)lib_args->mailbox_ep,
 				   &psci_plat_pm_ops);
 	assert(psci_plat_pm_ops != NULL);

 	/*
 	 * Flush `psci_plat_pm_ops` as it will be accessed by secondary CPUs
 	 * during warm boot, possibly before data cache is enabled.
 	 */
 	psci_flush_dcache_range((uintptr_t)&psci_plat_pm_ops,
 					sizeof(psci_plat_pm_ops));

 	/* Initialize the psci capability */
 	psci_caps = PSCI_GENERIC_CAP;

 	if (psci_plat_pm_ops->pwr_domain_off != NULL)
 		psci_caps |=  define_psci_cap(PSCI_CPU_OFF);
 	if ((psci_plat_pm_ops->pwr_domain_on != NULL) &&
 	    (psci_plat_pm_ops->pwr_domain_on_finish != NULL))
 		psci_caps |=  define_psci_cap(PSCI_CPU_ON_AARCH64);
 	if ((psci_plat_pm_ops->pwr_domain_suspend != NULL) &&
 	    (psci_plat_pm_ops->pwr_domain_suspend_finish != NULL)) {
 		psci_caps |=  define_psci_cap(PSCI_CPU_SUSPEND_AARCH64);
 		if (psci_plat_pm_ops->get_sys_suspend_power_state != NULL)
 			psci_caps |=  define_psci_cap(PSCI_SYSTEM_SUSPEND_AARCH64);
 	}
 	if (psci_plat_pm_ops->system_off != NULL)
 		psci_caps |=  define_psci_cap(PSCI_SYSTEM_OFF);
 	if (psci_plat_pm_ops->system_reset != NULL)
 		psci_caps |=  define_psci_cap(PSCI_SYSTEM_RESET);
 	if (psci_plat_pm_ops->get_node_hw_state != NULL)
 		psci_caps |= define_psci_cap(PSCI_NODE_HW_STATE_AARCH64);
 	if ((psci_plat_pm_ops->read_mem_protect != NULL) &&
 			(psci_plat_pm_ops->write_mem_protect != NULL))
 		psci_caps |= define_psci_cap(PSCI_MEM_PROTECT);
 	if (psci_plat_pm_ops->mem_protect_chk != NULL)
 		psci_caps |= define_psci_cap(PSCI_MEM_CHK_RANGE_AARCH64);
 	if (psci_plat_pm_ops->system_reset2 != NULL)
 		psci_caps |= define_psci_cap(PSCI_SYSTEM_RESET2_AARCH64);

 #if ENABLE_PSCI_STAT
 	psci_caps |=  define_psci_cap(PSCI_STAT_RESIDENCY_AARCH64);
 	psci_caps |=  define_psci_cap(PSCI_STAT_COUNT_AARCH64);
 #endif

 	return 0;
 }

 /*******************************************************************************
  * This duplicates what the primary cpu did after a cold boot in BL1. The same
  * needs to be done when a cpu is hotplugged in. This function could also over-
  * ride any EL3 setup done by BL1 as this code resides in rw memory.
  ******************************************************************************/
 void psci_arch_setup(void)
 {
 #if (ARM_ARCH_MAJOR > 7) || defined(ARMV7_SUPPORTS_GENERIC_TIMER)
 	/* Program the counter frequency */
 	write_cntfrq_el0(plat_get_syscnt_freq2());
 #endif

 	/* Initialize the cpu_ops pointer. */
 	init_cpu_ops();

 	/* Having initialized cpu_ops, we can now print errata status */
 	print_errata_status();

 #if ENABLE_PAUTH
 	/* Store APIAKey_EL1 key */
 	set_cpu_data(apiakey[0], read_apiakeylo_el1());
 	set_cpu_data(apiakey[1], read_apiakeyhi_el1());
 #endif /* ENABLE_PAUTH */
 }

 /******************************************************************************
  * PSCI Library interface to initialize the cpu context for the next non
  * secure image during cold boot. The relevant registers in the cpu context
  * need to be retrieved and programmed on return from this interface.
  *****************************************************************************/
 void psci_prepare_next_non_secure_ctx(entry_point_info_t *next_image_info)
 {
 	assert(GET_SECURITY_STATE(next_image_info->h.attr) == NON_SECURE);
 	cm_init_my_context(next_image_info);
 	cm_prepare_el3_exit(NON_SECURE);
 }
	/*
	* Copyright (c) 2013-2020, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <assert.h>
	#include <stddef.h>

	#include <arch.h>
	#include <arch_helpers.h>
	#include <common/bl_common.h>
	#include <context.h>
	#include <lib/el3_runtime/context_mgmt.h>
	#include <lib/cpus/errata_report.h>
	#include <plat/common/platform.h>

	#include "psci_private.h"

	/*******************************************************************************
	* Per cpu non-secure contexts used to program the architectural state prior
	* return to the normal world.
	* TODO: Use the memory allocator to set aside memory for the contexts instead
	* of relying on platform defined constants.
	******************************************************************************/
	static cpu_context_t psci_ns_context[PLATFORM_CORE_COUNT];

	/******************************************************************************
	* Define the psci capability variable.
	*****************************************************************************/
	unsigned int psci_caps;

	/*******************************************************************************
	* Function which initializes the 'psci_non_cpu_pd_nodes' or the
	* 'psci_cpu_pd_nodes' corresponding to the power level.
	******************************************************************************/
	static void __init psci_init_pwr_domain_node(unsigned char node_idx,
	unsigned int parent_idx,
	unsigned char level)
	{
	if (level > PSCI_CPU_PWR_LVL) {
	psci_non_cpu_pd_nodes[node_idx].level = level;
	psci_lock_init(psci_non_cpu_pd_nodes, node_idx);
	psci_non_cpu_pd_nodes[node_idx].parent_node = parent_idx;
	psci_non_cpu_pd_nodes[node_idx].local_state =
	PLAT_MAX_OFF_STATE;
	} else {
	psci_cpu_data_t *svc_cpu_data;

	psci_cpu_pd_nodes[node_idx].parent_node = parent_idx;

	/* Initialize with an invalid mpidr */
	psci_cpu_pd_nodes[node_idx].mpidr = PSCI_INVALID_MPIDR;

	svc_cpu_data =
	&(_cpu_data_by_index(node_idx)->psci_svc_cpu_data);

	/* Set the Affinity Info for the cores as OFF */
	svc_cpu_data->aff_info_state = AFF_STATE_OFF;

	/* Invalidate the suspend level for the cpu */
	svc_cpu_data->target_pwrlvl = PSCI_INVALID_PWR_LVL;

	/* Set the power state to OFF state */
	svc_cpu_data->local_state = PLAT_MAX_OFF_STATE;

	psci_flush_dcache_range((uintptr_t)svc_cpu_data,
	sizeof(*svc_cpu_data));

	cm_set_context_by_index(node_idx,
	(void *) &psci_ns_context[node_idx],
	NON_SECURE);
	}
	}

	/*******************************************************************************
	* This functions updates cpu_start_idx and ncpus field for each of the node in
	* psci_non_cpu_pd_nodes[]. It does so by comparing the parent nodes of each of
	* the CPUs and check whether they match with the parent of the previous
	* CPU. The basic assumption for this work is that children of the same parent
	* are allocated adjacent indices. The platform should ensure this though proper
	* mapping of the CPUs to indices via plat_core_pos_by_mpidr() and
	* plat_my_core_pos() APIs.
	*******************************************************************************/
	static void __init psci_update_pwrlvl_limits(void)
	{
	unsigned int cpu_idx;
	int j;
	unsigned int nodes_idx[PLAT_MAX_PWR_LVL] = {0};
	unsigned int temp_index[PLAT_MAX_PWR_LVL];

	for (cpu_idx = 0; cpu_idx < psci_plat_core_count; cpu_idx++) {
	psci_get_parent_pwr_domain_nodes(cpu_idx,
	PLAT_MAX_PWR_LVL,
	temp_index);
	for (j = (int)PLAT_MAX_PWR_LVL - 1; j >= 0; j--) {
	if (temp_index[j] != nodes_idx[j]) {
	nodes_idx[j] = temp_index[j];
	psci_non_cpu_pd_nodes[nodes_idx[j]].cpu_start_idx
	= cpu_idx;
	}
	psci_non_cpu_pd_nodes[nodes_idx[j]].ncpus++;
	}
	}
	}

	/*******************************************************************************
	* Core routine to populate the power domain tree. The tree descriptor passed by
	* the platform is populated breadth-first and the first entry in the map
	* informs the number of root power domains. The parent nodes of the root nodes
	* will point to an invalid entry(-1).
	******************************************************************************/
	static unsigned int __init populate_power_domain_tree(const unsigned char
	*topology)
	{
	unsigned int i, j = 0U, num_nodes_at_lvl = 1U, num_nodes_at_next_lvl;
	unsigned int node_index = 0U, num_children;
	unsigned int parent_node_index = 0U;
	int level = (int)PLAT_MAX_PWR_LVL;

	/*
	* For each level the inputs are:
	* - number of nodes at this level in plat_array i.e. num_nodes_at_level
	* This is the sum of values of nodes at the parent level.
	* - Index of first entry at this level in the plat_array i.e.
	* parent_node_index.
	* - Index of first free entry in psci_non_cpu_pd_nodes[] or
	* psci_cpu_pd_nodes[] i.e. node_index depending upon the level.
	*/
	while (level >= (int) PSCI_CPU_PWR_LVL) {
	num_nodes_at_next_lvl = 0U;
	/*
	* For each entry (parent node) at this level in the plat_array:
	* - Find the number of children
	* - Allocate a node in a power domain array for each child
	* - Set the parent of the child to the parent_node_index - 1
	* - Increment parent_node_index to point to the next parent
	* - Accumulate the number of children at next level.
	*/
	for (i = 0U; i < num_nodes_at_lvl; i++) {
	assert(parent_node_index <=
	PSCI_NUM_NON_CPU_PWR_DOMAINS);
	num_children = topology[parent_node_index];

	for (j = node_index;
	j < (node_index + num_children); j++)
	psci_init_pwr_domain_node((unsigned char)j,
	parent_node_index - 1U,
	(unsigned char)level);

	node_index = j;
	num_nodes_at_next_lvl += num_children;
	parent_node_index++;
	}

	num_nodes_at_lvl = num_nodes_at_next_lvl;
	level--;

	/* Reset the index for the cpu power domain array */
	if (level == (int) PSCI_CPU_PWR_LVL)
	node_index = 0;
	}

	/* Validate the sanity of array exported by the platform */
	assert(j <= PLATFORM_CORE_COUNT);
	return j;
	}

	/*******************************************************************************
	* This function does the architectural setup and takes the warm boot
	* entry-point `mailbox_ep` as an argument. The function also initializes the
	* power domain topology tree by querying the platform. The power domain nodes
	* higher than the CPU are populated in the array psci_non_cpu_pd_nodes[] and
	* the CPU power domains are populated in psci_cpu_pd_nodes[]. The platform
	* exports its static topology map through the
	* populate_power_domain_topology_tree() API. The algorithm populates the
	* psci_non_cpu_pd_nodes and psci_cpu_pd_nodes iteratively by using this
	* topology map. On a platform that implements two clusters of 2 cpus each,
	* and supporting 3 domain levels, the populated psci_non_cpu_pd_nodes would
	* look like this:
	*
	* ---------------------------------------------------
	* \| system node \| cluster 0 node \| cluster 1 node \|
	* ---------------------------------------------------
	*
	* And populated psci_cpu_pd_nodes would look like this :
	* <- cpus cluster0 -><- cpus cluster1 ->
	* ------------------------------------------------
	* \| CPU 0 \| CPU 1 \| CPU 2 \| CPU 3 \|
	* ------------------------------------------------
	******************************************************************************/
	int __init psci_setup(const psci_lib_args_t *lib_args)
	{
	const unsigned char *topology_tree;

	assert(VERIFY_PSCI_LIB_ARGS_V1(lib_args));

	/* Do the Architectural initialization */
	psci_arch_setup();

	/* Query the topology map from the platform */
	topology_tree = plat_get_power_domain_tree_desc();

	/* Populate the power domain arrays using the platform topology map */
	psci_plat_core_count = populate_power_domain_tree(topology_tree);

	/* Update the CPU limits for each node in psci_non_cpu_pd_nodes */
	psci_update_pwrlvl_limits();

	/* Populate the mpidr field of cpu node for this CPU */
	psci_cpu_pd_nodes[plat_my_core_pos()].mpidr =
	read_mpidr() & MPIDR_AFFINITY_MASK;

	psci_init_req_local_pwr_states();

	/*
	* Set the requested and target state of this CPU and all the higher
	* power domain levels for this CPU to run.
	*/
	psci_set_pwr_domains_to_run(PLAT_MAX_PWR_LVL);

	(void) plat_setup_psci_ops((uintptr_t)lib_args->mailbox_ep,
	&psci_plat_pm_ops);
	assert(psci_plat_pm_ops != NULL);

	/*
	* Flush `psci_plat_pm_ops` as it will be accessed by secondary CPUs
	* during warm boot, possibly before data cache is enabled.
	*/
	psci_flush_dcache_range((uintptr_t)&psci_plat_pm_ops,
	sizeof(psci_plat_pm_ops));

	/* Initialize the psci capability */
	psci_caps = PSCI_GENERIC_CAP;

	if (psci_plat_pm_ops->pwr_domain_off != NULL)
	psci_caps \|= define_psci_cap(PSCI_CPU_OFF);
	if ((psci_plat_pm_ops->pwr_domain_on != NULL) &&
	(psci_plat_pm_ops->pwr_domain_on_finish != NULL))
	psci_caps \|= define_psci_cap(PSCI_CPU_ON_AARCH64);
	if ((psci_plat_pm_ops->pwr_domain_suspend != NULL) &&
	(psci_plat_pm_ops->pwr_domain_suspend_finish != NULL)) {
	psci_caps \|= define_psci_cap(PSCI_CPU_SUSPEND_AARCH64);
	if (psci_plat_pm_ops->get_sys_suspend_power_state != NULL)
	psci_caps \|= define_psci_cap(PSCI_SYSTEM_SUSPEND_AARCH64);
	}
	if (psci_plat_pm_ops->system_off != NULL)
	psci_caps \|= define_psci_cap(PSCI_SYSTEM_OFF);
	if (psci_plat_pm_ops->system_reset != NULL)
	psci_caps \|= define_psci_cap(PSCI_SYSTEM_RESET);
	if (psci_plat_pm_ops->get_node_hw_state != NULL)
	psci_caps \|= define_psci_cap(PSCI_NODE_HW_STATE_AARCH64);
	if ((psci_plat_pm_ops->read_mem_protect != NULL) &&
	(psci_plat_pm_ops->write_mem_protect != NULL))
	psci_caps \|= define_psci_cap(PSCI_MEM_PROTECT);
	if (psci_plat_pm_ops->mem_protect_chk != NULL)
	psci_caps \|= define_psci_cap(PSCI_MEM_CHK_RANGE_AARCH64);
	if (psci_plat_pm_ops->system_reset2 != NULL)
	psci_caps \|= define_psci_cap(PSCI_SYSTEM_RESET2_AARCH64);

	#if ENABLE_PSCI_STAT
	psci_caps \|= define_psci_cap(PSCI_STAT_RESIDENCY_AARCH64);
	psci_caps \|= define_psci_cap(PSCI_STAT_COUNT_AARCH64);
	#endif

	return 0;
	}

	/*******************************************************************************
	* This duplicates what the primary cpu did after a cold boot in BL1. The same
	* needs to be done when a cpu is hotplugged in. This function could also over-
	* ride any EL3 setup done by BL1 as this code resides in rw memory.
	******************************************************************************/
	void psci_arch_setup(void)
	{
	#if (ARM_ARCH_MAJOR > 7) \|\| defined(ARMV7_SUPPORTS_GENERIC_TIMER)
	/* Program the counter frequency */
	write_cntfrq_el0(plat_get_syscnt_freq2());
	#endif

	/* Initialize the cpu_ops pointer. */
	init_cpu_ops();

	/* Having initialized cpu_ops, we can now print errata status */
	print_errata_status();

	#if ENABLE_PAUTH
	/* Store APIAKey_EL1 key */
	set_cpu_data(apiakey[0], read_apiakeylo_el1());
	set_cpu_data(apiakey[1], read_apiakeyhi_el1());
	#endif /* ENABLE_PAUTH */
	}

	/******************************************************************************
	* PSCI Library interface to initialize the cpu context for the next non
	* secure image during cold boot. The relevant registers in the cpu context
	* need to be retrieved and programmed on return from this interface.
	*****************************************************************************/
	void psci_prepare_next_non_secure_ctx(entry_point_info_t *next_image_info)
	{
	assert(GET_SECURITY_STATE(next_image_info->h.attr) == NON_SECURE);
	cm_init_my_context(next_image_info);
	cm_prepare_el3_exit(NON_SECURE);
	}