plat/nvidia/tegra/soc/t194/plat_psci_handlers.c - TF-A/trusted-firmware-a.git - Gitiles

 /*
  * Copyright (c) 2019-2020, NVIDIA CORPORATION. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch.h>
 #include <assert.h>
 #include <stdbool.h>
 #include <string.h>

 #include <arch_helpers.h>
 #include <bpmp_ipc.h>
 #include <common/bl_common.h>
 #include <common/debug.h>
 #include <context.h>
 #include <drivers/delay_timer.h>
 #include <denver.h>
 #include <lib/el3_runtime/context_mgmt.h>
 #include <lib/psci/psci.h>
 #include <mce.h>
 #include <mce_private.h>
 #include <memctrl_v2.h>
 #include <plat/common/platform.h>
 #include <se.h>
 #include <smmu.h>
 #include <t194_nvg.h>
 #include <tegra194_private.h>
 #include <tegra_platform.h>
 #include <tegra_private.h>

 extern uint32_t __tegra194_cpu_reset_handler_data,
 		__tegra194_cpu_reset_handler_end;

 /* TZDRAM offset for saving SMMU context */
 #define TEGRA194_SMMU_CTX_OFFSET	16U

 /* state id mask */
 #define TEGRA194_STATE_ID_MASK		0xFU
 /* constants to get power state's wake time */
 #define TEGRA194_WAKE_TIME_MASK		0x0FFFFFF0U
 #define TEGRA194_WAKE_TIME_SHIFT	4U
 /* default core wake mask for CPU_SUSPEND */
 #define TEGRA194_CORE_WAKE_MASK		0x180cU

 static struct t19x_psci_percpu_data {
 	uint32_t wake_time;
 } __aligned(CACHE_WRITEBACK_GRANULE) t19x_percpu_data[PLATFORM_CORE_COUNT];

 int32_t tegra_soc_validate_power_state(uint32_t power_state,
 					psci_power_state_t *req_state)
 {
 	uint8_t state_id = (uint8_t)psci_get_pstate_id(power_state) &
 			   TEGRA194_STATE_ID_MASK;
 	uint32_t cpu = plat_my_core_pos();
 	int32_t ret = PSCI_E_SUCCESS;

 	/* save the core wake time (in TSC ticks)*/
 	t19x_percpu_data[cpu].wake_time = (power_state & TEGRA194_WAKE_TIME_MASK)
 			<< TEGRA194_WAKE_TIME_SHIFT;

 	/*
 	 * Clean t19x_percpu_data[cpu] to DRAM. This needs to be done to ensure
 	 * that the correct value is read in tegra_soc_pwr_domain_suspend(),
 	 * which is called with caches disabled. It is possible to read a stale
 	 * value from DRAM in that function, because the L2 cache is not flushed
 	 * unless the cluster is entering CC6/CC7.
 	 */
 	clean_dcache_range((uint64_t)&t19x_percpu_data[cpu],
 			sizeof(t19x_percpu_data[cpu]));

 	/* Sanity check the requested state id */
 	switch (state_id) {
 	case PSTATE_ID_CORE_IDLE:

 		if (psci_get_pstate_type(power_state) != PSTATE_TYPE_STANDBY) {
 			ret = PSCI_E_INVALID_PARAMS;
 			break;
 		}

 		/* Core idle request */
 		req_state->pwr_domain_state[MPIDR_AFFLVL0] = PLAT_MAX_RET_STATE;
 		req_state->pwr_domain_state[MPIDR_AFFLVL1] = PSCI_LOCAL_STATE_RUN;
 		break;

 	default:
 		ERROR("%s: unsupported state id (%d)\n", __func__, state_id);
 		ret = PSCI_E_INVALID_PARAMS;
 		break;
 	}

 	return ret;
 }

 int32_t tegra_soc_cpu_standby(plat_local_state_t cpu_state)
 {
 	uint32_t cpu = plat_my_core_pos();
 	mce_cstate_info_t cstate_info = { 0 };

 	/* Program default wake mask */
 	cstate_info.wake_mask = TEGRA194_CORE_WAKE_MASK;
 	cstate_info.update_wake_mask = 1;
 	mce_update_cstate_info(&cstate_info);

 	/* Enter CPU idle */
 	(void)mce_command_handler((uint64_t)MCE_CMD_ENTER_CSTATE,
 				  (uint64_t)TEGRA_NVG_CORE_C6,
 				  t19x_percpu_data[cpu].wake_time,
 				  0U);

 	return PSCI_E_SUCCESS;
 }

 int32_t tegra_soc_pwr_domain_suspend(const psci_power_state_t *target_state)
 {
 	const plat_local_state_t *pwr_domain_state;
 	uint8_t stateid_afflvl2;
 	plat_params_from_bl2_t *params_from_bl2 = bl31_get_plat_params();
 	uint64_t mc_ctx_base;
 	uint32_t val;
 	mce_cstate_info_t sc7_cstate_info = {
 		.cluster = (uint32_t)TEGRA_NVG_CLUSTER_CC6,
 		.ccplex = (uint32_t)TEGRA_NVG_CG_CG7,
 		.system = (uint32_t)TEGRA_NVG_SYSTEM_SC7,
 		.system_state_force = 1U,
 		.update_wake_mask = 1U,
 	};
 	int32_t ret = 0;

 	/* get the state ID */
 	pwr_domain_state = target_state->pwr_domain_state;
 	stateid_afflvl2 = pwr_domain_state[PLAT_MAX_PWR_LVL] &
 		TEGRA194_STATE_ID_MASK;

 	if (stateid_afflvl2 == PSTATE_ID_SOC_POWERDN) {

 		/* save 'Secure Boot' Processor Feature Config Register */
 		val = mmio_read_32(TEGRA_MISC_BASE + MISCREG_PFCFG);
 		mmio_write_32(TEGRA_SCRATCH_BASE + SCRATCH_SECURE_BOOTP_FCFG, val);

 		/* save MC context */
 		mc_ctx_base = params_from_bl2->tzdram_base +
 				tegra194_get_mc_ctx_offset();
 		tegra_mc_save_context((uintptr_t)mc_ctx_base);

 		/*
 		 * Suspend SE, RNG1 and PKA1 only on silcon and fpga,
 		 * since VDK does not support atomic se ctx save
 		 */
 		if (tegra_platform_is_silicon() || tegra_platform_is_fpga()) {
 			ret = tegra_se_suspend();
 			assert(ret == 0);
 		}

 		/* Prepare for system suspend */
 		mce_update_cstate_info(&sc7_cstate_info);

 		do {
 			val = (uint32_t)mce_command_handler(
 					(uint32_t)MCE_CMD_IS_SC7_ALLOWED,
 					(uint32_t)TEGRA_NVG_CORE_C7,
 					MCE_CORE_SLEEP_TIME_INFINITE,
 					0U);
 		} while (val == 0U);

 		/* Instruct the MCE to enter system suspend state */
 		ret = mce_command_handler(
 				(uint64_t)MCE_CMD_ENTER_CSTATE,
 				(uint64_t)TEGRA_NVG_CORE_C7,
 				MCE_CORE_SLEEP_TIME_INFINITE,
 				0U);
 		assert(ret == 0);

 		/* set system suspend state for house-keeping */
 		tegra194_set_system_suspend_entry();
 	}

 	return PSCI_E_SUCCESS;
 }

 /*******************************************************************************
  * Helper function to check if this is the last ON CPU in the cluster
  ******************************************************************************/
 static bool tegra_last_on_cpu_in_cluster(const plat_local_state_t *states,
 			uint32_t ncpu)
 {
 	plat_local_state_t target;
 	bool last_on_cpu = true;
 	uint32_t num_cpus = ncpu, pos = 0;

 	do {
 		target = states[pos];
 		if (target != PLAT_MAX_OFF_STATE) {
 			last_on_cpu = false;
 		}
 		--num_cpus;
 		pos++;
 	} while (num_cpus != 0U);

 	return last_on_cpu;
 }

 /*******************************************************************************
  * Helper function to get target power state for the cluster
  ******************************************************************************/
 static plat_local_state_t tegra_get_afflvl1_pwr_state(const plat_local_state_t *states,
 			uint32_t ncpu)
 {
 	uint32_t core_pos = (uint32_t)read_mpidr() & (uint32_t)MPIDR_CPU_MASK;
 	plat_local_state_t target = states[core_pos];
 	mce_cstate_info_t cstate_info = { 0 };

 	/* CPU off */
 	if (target == PLAT_MAX_OFF_STATE) {

 		/* Enable cluster powerdn from last CPU in the cluster */
 		if (tegra_last_on_cpu_in_cluster(states, ncpu)) {

 			/* Enable CC6 state and turn off wake mask */
 			cstate_info.cluster = (uint32_t)TEGRA_NVG_CLUSTER_CC6;
 			cstate_info.ccplex = (uint32_t)TEGRA_NVG_CG_CG7;
 			cstate_info.system_state_force = 1;
 			cstate_info.update_wake_mask = 1U;
 			mce_update_cstate_info(&cstate_info);

 		} else {

 			/* Turn off wake_mask */
 			cstate_info.update_wake_mask = 1U;
 			mce_update_cstate_info(&cstate_info);
 			target = PSCI_LOCAL_STATE_RUN;
 		}
 	}

 	return target;
 }

 /*******************************************************************************
  * Platform handler to calculate the proper target power level at the
  * specified affinity level
  ******************************************************************************/
 plat_local_state_t tegra_soc_get_target_pwr_state(uint32_t lvl,
 					     const plat_local_state_t *states,
 					     uint32_t ncpu)
 {
 	plat_local_state_t target = PSCI_LOCAL_STATE_RUN;
 	uint32_t cpu = plat_my_core_pos();

 	/* System Suspend */
 	if ((lvl == (uint32_t)MPIDR_AFFLVL2) && (states[cpu] == PSTATE_ID_SOC_POWERDN)) {
 		target = PSTATE_ID_SOC_POWERDN;
 	}

 	/* CPU off, CPU suspend */
 	if (lvl == (uint32_t)MPIDR_AFFLVL1) {
 		target = tegra_get_afflvl1_pwr_state(states, ncpu);
 	}

 	/* target cluster/system state */
 	return target;
 }

 int32_t tegra_soc_pwr_domain_power_down_wfi(const psci_power_state_t *target_state)
 {
 	const plat_local_state_t *pwr_domain_state =
 		target_state->pwr_domain_state;
 	plat_params_from_bl2_t *params_from_bl2 = bl31_get_plat_params();
 	uint8_t stateid_afflvl2 = pwr_domain_state[PLAT_MAX_PWR_LVL] &
 		TEGRA194_STATE_ID_MASK;
 	uint64_t src_len_in_bytes = (uintptr_t)&__BL31_END__ - (uintptr_t)BL31_BASE;
 	uint64_t val;
 	int32_t ret = PSCI_E_SUCCESS;

 	if (stateid_afflvl2 == PSTATE_ID_SOC_POWERDN) {
 		val = params_from_bl2->tzdram_base +
 		      tegra194_get_cpu_reset_handler_size();

 		/* initialise communication channel with BPMP */
 		ret = tegra_bpmp_ipc_init();
 		assert(ret == 0);

 		/* Enable SE clock before SE context save */
 		ret = tegra_bpmp_ipc_enable_clock(TEGRA194_CLK_SE);
 		assert(ret == 0);

 		/*
 		 * It is very unlikely that the BL31 image would be
 		 * bigger than 2^32 bytes
 		 */
 		assert(src_len_in_bytes < UINT32_MAX);

 		if (tegra_se_calculate_save_sha256(BL31_BASE,
 					(uint32_t)src_len_in_bytes) != 0) {
 			ERROR("Hash calculation failed. Reboot\n");
 			(void)tegra_soc_prepare_system_reset();
 		}

 		/*
 		 * The TZRAM loses power when we enter system suspend. To
 		 * allow graceful exit from system suspend, we need to copy
 		 * BL3-1 over to TZDRAM.
 		 */
 		val = params_from_bl2->tzdram_base +
 		      tegra194_get_cpu_reset_handler_size();
 		memcpy((void *)(uintptr_t)val, (void *)(uintptr_t)BL31_BASE,
 		       src_len_in_bytes);

 		/* Disable SE clock after SE context save */
 		ret = tegra_bpmp_ipc_disable_clock(TEGRA194_CLK_SE);
 		assert(ret == 0);
 	}

 	return ret;
 }

 int32_t tegra_soc_pwr_domain_suspend_pwrdown_early(const psci_power_state_t *target_state)
 {
 	return PSCI_E_NOT_SUPPORTED;
 }

 int32_t tegra_soc_pwr_domain_on(u_register_t mpidr)
 {
 	uint64_t target_cpu = mpidr & MPIDR_CPU_MASK;
 	uint64_t target_cluster = (mpidr & MPIDR_CLUSTER_MASK) >>
 			MPIDR_AFFINITY_BITS;
 	int32_t ret = 0;

 	if (target_cluster > ((uint32_t)PLATFORM_CLUSTER_COUNT - 1U)) {
 		ERROR("%s: unsupported CPU (0x%lx)\n", __func__ , mpidr);
 		return PSCI_E_NOT_PRESENT;
 	}

 	/* construct the target CPU # */
 	target_cpu += (target_cluster << 1U);

 	ret = mce_command_handler((uint64_t)MCE_CMD_ONLINE_CORE, target_cpu, 0U, 0U);
 	if (ret < 0) {
 		return PSCI_E_DENIED;
 	}

 	return PSCI_E_SUCCESS;
 }

 int32_t tegra_soc_pwr_domain_on_finish(const psci_power_state_t *target_state)
 {
 	const plat_params_from_bl2_t *params_from_bl2 = bl31_get_plat_params();
 	uint8_t enable_ccplex_lock_step = params_from_bl2->enable_ccplex_lock_step;
 	uint8_t stateid_afflvl2 = target_state->pwr_domain_state[PLAT_MAX_PWR_LVL];
 	cpu_context_t *ctx = cm_get_context(NON_SECURE);
 	uint64_t actlr_elx;

 	/*
 	 * Reset power state info for CPUs when onlining, we set
 	 * deepest power when offlining a core but that may not be
 	 * requested by non-secure sw which controls idle states. It
 	 * will re-init this info from non-secure software when the
 	 * core come online.
 	 */
 	actlr_elx = read_ctx_reg((get_el1_sysregs_ctx(ctx)), (CTX_ACTLR_EL1));
 	actlr_elx &= ~DENVER_CPU_PMSTATE_MASK;
 	actlr_elx |= DENVER_CPU_PMSTATE_C1;
 	write_ctx_reg((get_el1_sysregs_ctx(ctx)), (CTX_ACTLR_EL1), (actlr_elx));

 	/*
 	 * Check if we are exiting from deep sleep and restore SE
 	 * context if we are.
 	 */
 	if (stateid_afflvl2 == PSTATE_ID_SOC_POWERDN) {

 #if ENABLE_STRICT_CHECKING_MODE
 		/*
 		 * Enable strict checking after programming the GSC for
 		 * enabling TZSRAM and TZDRAM
 		 */
 		mce_enable_strict_checking();
 #endif

 		/* Init SMMU */
 		tegra_smmu_init();

 		/* Resume SE, RNG1 and PKA1 */
 		tegra_se_resume();

 		/*
 		 * Program XUSB STREAMIDs
 		 * ======================
 		 * T19x XUSB has support for XUSB virtualization. It will
 		 * have one physical function (PF) and four Virtual functions
 		 * (VF)
 		 *
 		 * There were below two SIDs for XUSB until T186.
 		 * 1) #define TEGRA_SID_XUSB_HOST    0x1bU
 		 * 2) #define TEGRA_SID_XUSB_DEV    0x1cU
 		 *
 		 * We have below four new SIDs added for VF(s)
 		 * 3) #define TEGRA_SID_XUSB_VF0    0x5dU
 		 * 4) #define TEGRA_SID_XUSB_VF1    0x5eU
 		 * 5) #define TEGRA_SID_XUSB_VF2    0x5fU
 		 * 6) #define TEGRA_SID_XUSB_VF3    0x60U
 		 *
 		 * When virtualization is enabled then we have to disable SID
 		 * override and program above SIDs in below newly added SID
 		 * registers in XUSB PADCTL MMIO space. These registers are
 		 * TZ protected and so need to be done in ATF.
 		 *
 		 * a) #define XUSB_PADCTL_HOST_AXI_STREAMID_PF_0 (0x136cU)
 		 * b) #define XUSB_PADCTL_DEV_AXI_STREAMID_PF_0  (0x139cU)
 		 * c) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_0 (0x1370U)
 		 * d) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_1 (0x1374U)
 		 * e) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_2 (0x1378U)
 		 * f) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_3 (0x137cU)
 		 *
 		 * This change disables SID override and programs XUSB SIDs
 		 * in above registers to support both virtualization and
 		 * non-virtualization platforms
 		 */
 		if (tegra_platform_is_silicon() || tegra_platform_is_fpga()) {

 			mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_PF_0, TEGRA_SID_XUSB_HOST);
 			assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_PF_0) == TEGRA_SID_XUSB_HOST);
 			mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_0, TEGRA_SID_XUSB_VF0);
 			assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_0) == TEGRA_SID_XUSB_VF0);
 			mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_1, TEGRA_SID_XUSB_VF1);
 			assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_1) == TEGRA_SID_XUSB_VF1);
 			mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_2, TEGRA_SID_XUSB_VF2);
 			assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_2) == TEGRA_SID_XUSB_VF2);
 			mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_3, TEGRA_SID_XUSB_VF3);
 			assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_HOST_AXI_STREAMID_VF_3) == TEGRA_SID_XUSB_VF3);
 			mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_DEV_AXI_STREAMID_PF_0, TEGRA_SID_XUSB_DEV);
 			assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
 				XUSB_PADCTL_DEV_AXI_STREAMID_PF_0) == TEGRA_SID_XUSB_DEV);
 		}
 	}

 	/*
 	 * Enable dual execution optimized translations for all ELx.
 	 */
 	if (enable_ccplex_lock_step != 0U) {
 		actlr_elx = read_actlr_el3();
 		actlr_elx |= DENVER_CPU_ENABLE_DUAL_EXEC_EL3;
 		write_actlr_el3(actlr_elx);

 		actlr_elx = read_actlr_el2();
 		actlr_elx |= DENVER_CPU_ENABLE_DUAL_EXEC_EL2;
 		write_actlr_el2(actlr_elx);

 		actlr_elx = read_actlr_el1();
 		actlr_elx |= DENVER_CPU_ENABLE_DUAL_EXEC_EL1;
 		write_actlr_el1(actlr_elx);
 	}

 	return PSCI_E_SUCCESS;
 }

 int32_t tegra_soc_pwr_domain_off_early(const psci_power_state_t *target_state)
 {
 	/* Do not power off the boot CPU */
 	if (plat_is_my_cpu_primary()) {
 		return PSCI_E_DENIED;
 	}

 	return PSCI_E_SUCCESS;
 }

 int32_t tegra_soc_pwr_domain_off(const psci_power_state_t *target_state)
 {
 	uint64_t impl = (read_midr() >> MIDR_IMPL_SHIFT) & MIDR_IMPL_MASK;
 	int32_t ret = 0;

 	(void)target_state;

 	/* Disable Denver's DCO operations */
 	if (impl == DENVER_IMPL) {
 		denver_disable_dco();
 	}

 	/* Turn off CPU */
 	ret = mce_command_handler((uint64_t)MCE_CMD_ENTER_CSTATE,
 			(uint64_t)TEGRA_NVG_CORE_C7, MCE_CORE_SLEEP_TIME_INFINITE, 0U);
 	assert(ret == 0);

 	return PSCI_E_SUCCESS;
 }

 __dead2 void tegra_soc_prepare_system_off(void)
 {
 	/* System power off */
 	mce_system_shutdown();

 	wfi();

 	/* wait for the system to power down */
 	for (;;) {
 		;
 	}
 }

 int32_t tegra_soc_prepare_system_reset(void)
 {
 	/* System reboot */
 	mce_system_reboot();

 	return PSCI_E_SUCCESS;
 }
	/*
	* Copyright (c) 2019-2020, NVIDIA CORPORATION. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch.h>
	#include <assert.h>
	#include <stdbool.h>
	#include <string.h>

	#include <arch_helpers.h>
	#include <bpmp_ipc.h>
	#include <common/bl_common.h>
	#include <common/debug.h>
	#include <context.h>
	#include <drivers/delay_timer.h>
	#include <denver.h>
	#include <lib/el3_runtime/context_mgmt.h>
	#include <lib/psci/psci.h>
	#include <mce.h>
	#include <mce_private.h>
	#include <memctrl_v2.h>
	#include <plat/common/platform.h>
	#include <se.h>
	#include <smmu.h>
	#include <t194_nvg.h>
	#include <tegra194_private.h>
	#include <tegra_platform.h>
	#include <tegra_private.h>

	extern uint32_t __tegra194_cpu_reset_handler_data,
	__tegra194_cpu_reset_handler_end;

	/* TZDRAM offset for saving SMMU context */
	#define TEGRA194_SMMU_CTX_OFFSET 16U

	/* state id mask */
	#define TEGRA194_STATE_ID_MASK 0xFU
	/* constants to get power state's wake time */
	#define TEGRA194_WAKE_TIME_MASK 0x0FFFFFF0U
	#define TEGRA194_WAKE_TIME_SHIFT 4U
	/* default core wake mask for CPU_SUSPEND */
	#define TEGRA194_CORE_WAKE_MASK 0x180cU

	static struct t19x_psci_percpu_data {
	uint32_t wake_time;
	} __aligned(CACHE_WRITEBACK_GRANULE) t19x_percpu_data[PLATFORM_CORE_COUNT];

	int32_t tegra_soc_validate_power_state(uint32_t power_state,
	psci_power_state_t *req_state)
	{
	uint8_t state_id = (uint8_t)psci_get_pstate_id(power_state) &
	TEGRA194_STATE_ID_MASK;
	uint32_t cpu = plat_my_core_pos();
	int32_t ret = PSCI_E_SUCCESS;

	/* save the core wake time (in TSC ticks)*/
	t19x_percpu_data[cpu].wake_time = (power_state & TEGRA194_WAKE_TIME_MASK)
	<< TEGRA194_WAKE_TIME_SHIFT;

	/*
	* Clean t19x_percpu_data[cpu] to DRAM. This needs to be done to ensure
	* that the correct value is read in tegra_soc_pwr_domain_suspend(),
	* which is called with caches disabled. It is possible to read a stale
	* value from DRAM in that function, because the L2 cache is not flushed
	* unless the cluster is entering CC6/CC7.
	*/
	clean_dcache_range((uint64_t)&t19x_percpu_data[cpu],
	sizeof(t19x_percpu_data[cpu]));

	/* Sanity check the requested state id */
	switch (state_id) {
	case PSTATE_ID_CORE_IDLE:

	if (psci_get_pstate_type(power_state) != PSTATE_TYPE_STANDBY) {
	ret = PSCI_E_INVALID_PARAMS;
	break;
	}

	/* Core idle request */
	req_state->pwr_domain_state[MPIDR_AFFLVL0] = PLAT_MAX_RET_STATE;
	req_state->pwr_domain_state[MPIDR_AFFLVL1] = PSCI_LOCAL_STATE_RUN;
	break;

	default:
	ERROR("%s: unsupported state id (%d)\n", __func__, state_id);
	ret = PSCI_E_INVALID_PARAMS;
	break;
	}

	return ret;
	}

	int32_t tegra_soc_cpu_standby(plat_local_state_t cpu_state)
	{
	uint32_t cpu = plat_my_core_pos();
	mce_cstate_info_t cstate_info = { 0 };

	/* Program default wake mask */
	cstate_info.wake_mask = TEGRA194_CORE_WAKE_MASK;
	cstate_info.update_wake_mask = 1;
	mce_update_cstate_info(&cstate_info);

	/* Enter CPU idle */
	(void)mce_command_handler((uint64_t)MCE_CMD_ENTER_CSTATE,
	(uint64_t)TEGRA_NVG_CORE_C6,
	t19x_percpu_data[cpu].wake_time,
	0U);

	return PSCI_E_SUCCESS;
	}

	int32_t tegra_soc_pwr_domain_suspend(const psci_power_state_t *target_state)
	{
	const plat_local_state_t *pwr_domain_state;
	uint8_t stateid_afflvl2;
	plat_params_from_bl2_t *params_from_bl2 = bl31_get_plat_params();
	uint64_t mc_ctx_base;
	uint32_t val;
	mce_cstate_info_t sc7_cstate_info = {
	.cluster = (uint32_t)TEGRA_NVG_CLUSTER_CC6,
	.ccplex = (uint32_t)TEGRA_NVG_CG_CG7,
	.system = (uint32_t)TEGRA_NVG_SYSTEM_SC7,
	.system_state_force = 1U,
	.update_wake_mask = 1U,
	};
	int32_t ret = 0;

	/* get the state ID */
	pwr_domain_state = target_state->pwr_domain_state;
	stateid_afflvl2 = pwr_domain_state[PLAT_MAX_PWR_LVL] &
	TEGRA194_STATE_ID_MASK;

	if (stateid_afflvl2 == PSTATE_ID_SOC_POWERDN) {

	/* save 'Secure Boot' Processor Feature Config Register */
	val = mmio_read_32(TEGRA_MISC_BASE + MISCREG_PFCFG);
	mmio_write_32(TEGRA_SCRATCH_BASE + SCRATCH_SECURE_BOOTP_FCFG, val);

	/* save MC context */
	mc_ctx_base = params_from_bl2->tzdram_base +
	tegra194_get_mc_ctx_offset();
	tegra_mc_save_context((uintptr_t)mc_ctx_base);

	/*
	* Suspend SE, RNG1 and PKA1 only on silcon and fpga,
	* since VDK does not support atomic se ctx save
	*/
	if (tegra_platform_is_silicon() \|\| tegra_platform_is_fpga()) {
	ret = tegra_se_suspend();
	assert(ret == 0);
	}

	/* Prepare for system suspend */
	mce_update_cstate_info(&sc7_cstate_info);

	do {
	val = (uint32_t)mce_command_handler(
	(uint32_t)MCE_CMD_IS_SC7_ALLOWED,
	(uint32_t)TEGRA_NVG_CORE_C7,
	MCE_CORE_SLEEP_TIME_INFINITE,
	0U);
	} while (val == 0U);

	/* Instruct the MCE to enter system suspend state */
	ret = mce_command_handler(
	(uint64_t)MCE_CMD_ENTER_CSTATE,
	(uint64_t)TEGRA_NVG_CORE_C7,
	MCE_CORE_SLEEP_TIME_INFINITE,
	0U);
	assert(ret == 0);

	/* set system suspend state for house-keeping */
	tegra194_set_system_suspend_entry();
	}

	return PSCI_E_SUCCESS;
	}

	/*******************************************************************************
	* Helper function to check if this is the last ON CPU in the cluster
	******************************************************************************/
	static bool tegra_last_on_cpu_in_cluster(const plat_local_state_t *states,
	uint32_t ncpu)
	{
	plat_local_state_t target;
	bool last_on_cpu = true;
	uint32_t num_cpus = ncpu, pos = 0;

	do {
	target = states[pos];
	if (target != PLAT_MAX_OFF_STATE) {
	last_on_cpu = false;
	}
	--num_cpus;
	pos++;
	} while (num_cpus != 0U);

	return last_on_cpu;
	}

	/*******************************************************************************
	* Helper function to get target power state for the cluster
	******************************************************************************/
	static plat_local_state_t tegra_get_afflvl1_pwr_state(const plat_local_state_t *states,
	uint32_t ncpu)
	{
	uint32_t core_pos = (uint32_t)read_mpidr() & (uint32_t)MPIDR_CPU_MASK;
	plat_local_state_t target = states[core_pos];
	mce_cstate_info_t cstate_info = { 0 };

	/* CPU off */
	if (target == PLAT_MAX_OFF_STATE) {

	/* Enable cluster powerdn from last CPU in the cluster */
	if (tegra_last_on_cpu_in_cluster(states, ncpu)) {

	/* Enable CC6 state and turn off wake mask */
	cstate_info.cluster = (uint32_t)TEGRA_NVG_CLUSTER_CC6;
	cstate_info.ccplex = (uint32_t)TEGRA_NVG_CG_CG7;
	cstate_info.system_state_force = 1;
	cstate_info.update_wake_mask = 1U;
	mce_update_cstate_info(&cstate_info);

	} else {

	/* Turn off wake_mask */
	cstate_info.update_wake_mask = 1U;
	mce_update_cstate_info(&cstate_info);
	target = PSCI_LOCAL_STATE_RUN;
	}
	}

	return target;
	}

	/*******************************************************************************
	* Platform handler to calculate the proper target power level at the
	* specified affinity level
	******************************************************************************/
	plat_local_state_t tegra_soc_get_target_pwr_state(uint32_t lvl,
	const plat_local_state_t *states,
	uint32_t ncpu)
	{
	plat_local_state_t target = PSCI_LOCAL_STATE_RUN;
	uint32_t cpu = plat_my_core_pos();

	/* System Suspend */
	if ((lvl == (uint32_t)MPIDR_AFFLVL2) && (states[cpu] == PSTATE_ID_SOC_POWERDN)) {
	target = PSTATE_ID_SOC_POWERDN;
	}

	/* CPU off, CPU suspend */
	if (lvl == (uint32_t)MPIDR_AFFLVL1) {
	target = tegra_get_afflvl1_pwr_state(states, ncpu);
	}

	/* target cluster/system state */
	return target;
	}

	int32_t tegra_soc_pwr_domain_power_down_wfi(const psci_power_state_t *target_state)
	{
	const plat_local_state_t *pwr_domain_state =
	target_state->pwr_domain_state;
	plat_params_from_bl2_t *params_from_bl2 = bl31_get_plat_params();
	uint8_t stateid_afflvl2 = pwr_domain_state[PLAT_MAX_PWR_LVL] &
	TEGRA194_STATE_ID_MASK;
	uint64_t src_len_in_bytes = (uintptr_t)&__BL31_END__ - (uintptr_t)BL31_BASE;
	uint64_t val;
	int32_t ret = PSCI_E_SUCCESS;

	if (stateid_afflvl2 == PSTATE_ID_SOC_POWERDN) {
	val = params_from_bl2->tzdram_base +
	tegra194_get_cpu_reset_handler_size();

	/* initialise communication channel with BPMP */
	ret = tegra_bpmp_ipc_init();
	assert(ret == 0);

	/* Enable SE clock before SE context save */
	ret = tegra_bpmp_ipc_enable_clock(TEGRA194_CLK_SE);
	assert(ret == 0);

	/*
	* It is very unlikely that the BL31 image would be
	* bigger than 2^32 bytes
	*/
	assert(src_len_in_bytes < UINT32_MAX);

	if (tegra_se_calculate_save_sha256(BL31_BASE,
	(uint32_t)src_len_in_bytes) != 0) {
	ERROR("Hash calculation failed. Reboot\n");
	(void)tegra_soc_prepare_system_reset();
	}

	/*
	* The TZRAM loses power when we enter system suspend. To
	* allow graceful exit from system suspend, we need to copy
	* BL3-1 over to TZDRAM.
	*/
	val = params_from_bl2->tzdram_base +
	tegra194_get_cpu_reset_handler_size();
	memcpy((void )(uintptr_t)val, (void )(uintptr_t)BL31_BASE,
	src_len_in_bytes);

	/* Disable SE clock after SE context save */
	ret = tegra_bpmp_ipc_disable_clock(TEGRA194_CLK_SE);
	assert(ret == 0);
	}

	return ret;
	}

	int32_t tegra_soc_pwr_domain_suspend_pwrdown_early(const psci_power_state_t *target_state)
	{
	return PSCI_E_NOT_SUPPORTED;
	}

	int32_t tegra_soc_pwr_domain_on(u_register_t mpidr)
	{
	uint64_t target_cpu = mpidr & MPIDR_CPU_MASK;
	uint64_t target_cluster = (mpidr & MPIDR_CLUSTER_MASK) >>
	MPIDR_AFFINITY_BITS;
	int32_t ret = 0;

	if (target_cluster > ((uint32_t)PLATFORM_CLUSTER_COUNT - 1U)) {
	ERROR("%s: unsupported CPU (0x%lx)\n", __func__ , mpidr);
	return PSCI_E_NOT_PRESENT;
	}

	/* construct the target CPU # */
	target_cpu += (target_cluster << 1U);

	ret = mce_command_handler((uint64_t)MCE_CMD_ONLINE_CORE, target_cpu, 0U, 0U);
	if (ret < 0) {
	return PSCI_E_DENIED;
	}

	return PSCI_E_SUCCESS;
	}

	int32_t tegra_soc_pwr_domain_on_finish(const psci_power_state_t *target_state)
	{
	const plat_params_from_bl2_t *params_from_bl2 = bl31_get_plat_params();
	uint8_t enable_ccplex_lock_step = params_from_bl2->enable_ccplex_lock_step;
	uint8_t stateid_afflvl2 = target_state->pwr_domain_state[PLAT_MAX_PWR_LVL];
	cpu_context_t *ctx = cm_get_context(NON_SECURE);
	uint64_t actlr_elx;

	/*
	* Reset power state info for CPUs when onlining, we set
	* deepest power when offlining a core but that may not be
	* requested by non-secure sw which controls idle states. It
	* will re-init this info from non-secure software when the
	* core come online.
	*/
	actlr_elx = read_ctx_reg((get_el1_sysregs_ctx(ctx)), (CTX_ACTLR_EL1));
	actlr_elx &= ~DENVER_CPU_PMSTATE_MASK;
	actlr_elx \|= DENVER_CPU_PMSTATE_C1;
	write_ctx_reg((get_el1_sysregs_ctx(ctx)), (CTX_ACTLR_EL1), (actlr_elx));

	/*
	* Check if we are exiting from deep sleep and restore SE
	* context if we are.
	*/
	if (stateid_afflvl2 == PSTATE_ID_SOC_POWERDN) {

	#if ENABLE_STRICT_CHECKING_MODE
	/*
	* Enable strict checking after programming the GSC for
	* enabling TZSRAM and TZDRAM
	*/
	mce_enable_strict_checking();
	#endif

	/* Init SMMU */
	tegra_smmu_init();

	/* Resume SE, RNG1 and PKA1 */
	tegra_se_resume();

	/*
	* Program XUSB STREAMIDs
	* ======================
	* T19x XUSB has support for XUSB virtualization. It will
	* have one physical function (PF) and four Virtual functions
	* (VF)
	*
	* There were below two SIDs for XUSB until T186.
	* 1) #define TEGRA_SID_XUSB_HOST 0x1bU
	* 2) #define TEGRA_SID_XUSB_DEV 0x1cU
	*
	* We have below four new SIDs added for VF(s)
	* 3) #define TEGRA_SID_XUSB_VF0 0x5dU
	* 4) #define TEGRA_SID_XUSB_VF1 0x5eU
	* 5) #define TEGRA_SID_XUSB_VF2 0x5fU
	* 6) #define TEGRA_SID_XUSB_VF3 0x60U
	*
	* When virtualization is enabled then we have to disable SID
	* override and program above SIDs in below newly added SID
	* registers in XUSB PADCTL MMIO space. These registers are
	* TZ protected and so need to be done in ATF.
	*
	* a) #define XUSB_PADCTL_HOST_AXI_STREAMID_PF_0 (0x136cU)
	* b) #define XUSB_PADCTL_DEV_AXI_STREAMID_PF_0 (0x139cU)
	* c) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_0 (0x1370U)
	* d) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_1 (0x1374U)
	* e) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_2 (0x1378U)
	* f) #define XUSB_PADCTL_HOST_AXI_STREAMID_VF_3 (0x137cU)
	*
	* This change disables SID override and programs XUSB SIDs
	* in above registers to support both virtualization and
	* non-virtualization platforms
	*/
	if (tegra_platform_is_silicon() \|\| tegra_platform_is_fpga()) {

	mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_PF_0, TEGRA_SID_XUSB_HOST);
	assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_PF_0) == TEGRA_SID_XUSB_HOST);
	mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_0, TEGRA_SID_XUSB_VF0);
	assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_0) == TEGRA_SID_XUSB_VF0);
	mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_1, TEGRA_SID_XUSB_VF1);
	assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_1) == TEGRA_SID_XUSB_VF1);
	mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_2, TEGRA_SID_XUSB_VF2);
	assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_2) == TEGRA_SID_XUSB_VF2);
	mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_3, TEGRA_SID_XUSB_VF3);
	assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_HOST_AXI_STREAMID_VF_3) == TEGRA_SID_XUSB_VF3);
	mmio_write_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_DEV_AXI_STREAMID_PF_0, TEGRA_SID_XUSB_DEV);
	assert(mmio_read_32(TEGRA_XUSB_PADCTL_BASE +
	XUSB_PADCTL_DEV_AXI_STREAMID_PF_0) == TEGRA_SID_XUSB_DEV);
	}
	}

	/*
	* Enable dual execution optimized translations for all ELx.
	*/
	if (enable_ccplex_lock_step != 0U) {
	actlr_elx = read_actlr_el3();
	actlr_elx \|= DENVER_CPU_ENABLE_DUAL_EXEC_EL3;
	write_actlr_el3(actlr_elx);

	actlr_elx = read_actlr_el2();
	actlr_elx \|= DENVER_CPU_ENABLE_DUAL_EXEC_EL2;
	write_actlr_el2(actlr_elx);

	actlr_elx = read_actlr_el1();
	actlr_elx \|= DENVER_CPU_ENABLE_DUAL_EXEC_EL1;
	write_actlr_el1(actlr_elx);
	}

	return PSCI_E_SUCCESS;
	}

	int32_t tegra_soc_pwr_domain_off_early(const psci_power_state_t *target_state)
	{
	/* Do not power off the boot CPU */
	if (plat_is_my_cpu_primary()) {
	return PSCI_E_DENIED;
	}

	return PSCI_E_SUCCESS;
	}

	int32_t tegra_soc_pwr_domain_off(const psci_power_state_t *target_state)
	{
	uint64_t impl = (read_midr() >> MIDR_IMPL_SHIFT) & MIDR_IMPL_MASK;
	int32_t ret = 0;

	(void)target_state;

	/* Disable Denver's DCO operations */
	if (impl == DENVER_IMPL) {
	denver_disable_dco();
	}

	/* Turn off CPU */
	ret = mce_command_handler((uint64_t)MCE_CMD_ENTER_CSTATE,
	(uint64_t)TEGRA_NVG_CORE_C7, MCE_CORE_SLEEP_TIME_INFINITE, 0U);
	assert(ret == 0);

	return PSCI_E_SUCCESS;
	}

	__dead2 void tegra_soc_prepare_system_off(void)
	{
	/* System power off */
	mce_system_shutdown();

	wfi();

	/* wait for the system to power down */
	for (;;) {
	;
	}
	}

	int32_t tegra_soc_prepare_system_reset(void)
	{
	/* System reboot */
	mce_system_reboot();

	return PSCI_E_SUCCESS;
	}