plat/nvidia/tegra/soc/t186/drivers/mce/mce.c - imx-atf - Git at Google

 /*
  * Copyright (c) 2015-2017, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch.h>
 #include <arch_helpers.h>
 #include <assert.h>
 #include <bl_common.h>
 #include <context.h>
 #include <context_mgmt.h>
 #include <debug.h>
 #include <denver.h>
 #include <mce.h>
 #include <mce_private.h>
 #include <mmio.h>
 #include <string.h>
 #include <sys/errno.h>
 #include <t18x_ari.h>
 #include <tegra_def.h>
 #include <tegra_platform.h>

 /* NVG functions handlers */
 static arch_mce_ops_t nvg_mce_ops = {
 	.enter_cstate = nvg_enter_cstate,
 	.update_cstate_info = nvg_update_cstate_info,
 	.update_crossover_time = nvg_update_crossover_time,
 	.read_cstate_stats = nvg_read_cstate_stats,
 	.write_cstate_stats = nvg_write_cstate_stats,
 	.call_enum_misc = ari_enumeration_misc,
 	.is_ccx_allowed = nvg_is_ccx_allowed,
 	.is_sc7_allowed = nvg_is_sc7_allowed,
 	.online_core = nvg_online_core,
 	.cc3_ctrl = nvg_cc3_ctrl,
 	.update_reset_vector = ari_reset_vector_update,
 	.roc_flush_cache = ari_roc_flush_cache,
 	.roc_flush_cache_trbits = ari_roc_flush_cache_trbits,
 	.roc_clean_cache = ari_roc_clean_cache,
 	.read_write_mca = ari_read_write_mca,
 	.update_ccplex_gsc = ari_update_ccplex_gsc,
 	.enter_ccplex_state = ari_enter_ccplex_state,
 	.read_write_uncore_perfmon = ari_read_write_uncore_perfmon,
 	.misc_ccplex = ari_misc_ccplex
 };

 /* ARI functions handlers */
 static arch_mce_ops_t ari_mce_ops = {
 	.enter_cstate = ari_enter_cstate,
 	.update_cstate_info = ari_update_cstate_info,
 	.update_crossover_time = ari_update_crossover_time,
 	.read_cstate_stats = ari_read_cstate_stats,
 	.write_cstate_stats = ari_write_cstate_stats,
 	.call_enum_misc = ari_enumeration_misc,
 	.is_ccx_allowed = ari_is_ccx_allowed,
 	.is_sc7_allowed = ari_is_sc7_allowed,
 	.online_core = ari_online_core,
 	.cc3_ctrl = ari_cc3_ctrl,
 	.update_reset_vector = ari_reset_vector_update,
 	.roc_flush_cache = ari_roc_flush_cache,
 	.roc_flush_cache_trbits = ari_roc_flush_cache_trbits,
 	.roc_clean_cache = ari_roc_clean_cache,
 	.read_write_mca = ari_read_write_mca,
 	.update_ccplex_gsc = ari_update_ccplex_gsc,
 	.enter_ccplex_state = ari_enter_ccplex_state,
 	.read_write_uncore_perfmon = ari_read_write_uncore_perfmon,
 	.misc_ccplex = ari_misc_ccplex
 };

 typedef struct {
 	uint32_t ari_base;
 	arch_mce_ops_t *ops;
 } mce_config_t;

 /* Table to hold the per-CPU ARI base address and function handlers */
 static mce_config_t mce_cfg_table[MCE_ARI_APERTURES_MAX] = {
 	{
 		/* A57 Core 0 */
 		.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_0_OFFSET,
 		.ops = &ari_mce_ops,
 	},
 	{
 		/* A57 Core 1 */
 		.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_1_OFFSET,
 		.ops = &ari_mce_ops,
 	},
 	{
 		/* A57 Core 2 */
 		.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_2_OFFSET,
 		.ops = &ari_mce_ops,
 	},
 	{
 		/* A57 Core 3 */
 		.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_3_OFFSET,
 		.ops = &ari_mce_ops,
 	},
 	{
 		/* D15 Core 0 */
 		.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_4_OFFSET,
 		.ops = &nvg_mce_ops,
 	},
 	{
 		/* D15 Core 1 */
 		.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_5_OFFSET,
 		.ops = &nvg_mce_ops,
 	}
 };

 static uint32_t mce_get_curr_cpu_ari_base(void)
 {
 	uint64_t mpidr = read_mpidr();
 	uint64_t cpuid = mpidr & (uint64_t)MPIDR_CPU_MASK;
 	uint64_t impl = (read_midr() >> (uint64_t)MIDR_IMPL_SHIFT) & (uint64_t)MIDR_IMPL_MASK;

 	/*
 	 * T186 has 2 CPU clusters, one with Denver CPUs and the other with
 	 * ARM CortexA-57 CPUs. Each cluster consists of 4 CPUs and the CPU
 	 * numbers start from 0. In order to get the proper arch_mce_ops_t
 	 * struct, we have to convert the Denver CPU ids to the corresponding
 	 * indices in the mce_ops_table array.
 	 */
 	if (impl == DENVER_IMPL) {
 		cpuid |= 0x4U;
 	}

 	return mce_cfg_table[cpuid].ari_base;
 }

 static arch_mce_ops_t *mce_get_curr_cpu_ops(void)
 {
 	uint64_t mpidr = read_mpidr();
 	uint64_t cpuid = mpidr & (uint64_t)MPIDR_CPU_MASK;
 	uint64_t impl = (read_midr() >> (uint64_t)MIDR_IMPL_SHIFT) &
 			(uint64_t)MIDR_IMPL_MASK;

 	/*
 	 * T186 has 2 CPU clusters, one with Denver CPUs and the other with
 	 * ARM CortexA-57 CPUs. Each cluster consists of 4 CPUs and the CPU
 	 * numbers start from 0. In order to get the proper arch_mce_ops_t
 	 * struct, we have to convert the Denver CPU ids to the corresponding
 	 * indices in the mce_ops_table array.
 	 */
 	if (impl == DENVER_IMPL) {
 		cpuid |= 0x4U;
 	}

 	return mce_cfg_table[cpuid].ops;
 }

 /*******************************************************************************
  * Common handler for all MCE commands
  ******************************************************************************/
 int32_t mce_command_handler(uint64_t cmd, uint64_t arg0, uint64_t arg1,
 			uint64_t arg2)
 {
 	const arch_mce_ops_t *ops;
 	gp_regs_t *gp_regs = get_gpregs_ctx(cm_get_context(NON_SECURE));
 	uint32_t cpu_ari_base;
 	uint64_t ret64 = 0, arg3, arg4, arg5;
 	int32_t ret = 0;

 	assert(gp_regs != NULL);

 	/* get a pointer to the CPU's arch_mce_ops_t struct */
 	ops = mce_get_curr_cpu_ops();

 	/* get the CPU's ARI base address */
 	cpu_ari_base = mce_get_curr_cpu_ari_base();

 	switch (cmd) {
 	case MCE_CMD_ENTER_CSTATE:
 		ret = ops->enter_cstate(cpu_ari_base, arg0, arg1);
 		if (ret < 0) {
 			ERROR("%s: enter_cstate failed(%d)\n", __func__, ret);
 		}

 		break;

 	case MCE_CMD_UPDATE_CSTATE_INFO:
 		/*
 		 * get the parameters required for the update cstate info
 		 * command
 		 */
 		arg3 = read_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X4));
 		arg4 = read_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X5));
 		arg5 = read_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X6));

 		ret = ops->update_cstate_info(cpu_ari_base, (uint32_t)arg0,
 				(uint32_t)arg1, (uint32_t)arg2, (uint8_t)arg3,
 				(uint32_t)arg4, (uint8_t)arg5);
 		if (ret < 0) {
 			ERROR("%s: update_cstate_info failed(%d)\n",
 				__func__, ret);
 		}

 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X4), (0));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X5), (0));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X6), (0));

 		break;

 	case MCE_CMD_UPDATE_CROSSOVER_TIME:
 		ret = ops->update_crossover_time(cpu_ari_base, arg0, arg1);
 		if (ret < 0) {
 			ERROR("%s: update_crossover_time failed(%d)\n",
 				__func__, ret);
 		}

 		break;

 	case MCE_CMD_READ_CSTATE_STATS:
 		ret64 = ops->read_cstate_stats(cpu_ari_base, arg0);

 		/* update context to return cstate stats value */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2), (ret64));

 		break;

 	case MCE_CMD_WRITE_CSTATE_STATS:
 		ret = ops->write_cstate_stats(cpu_ari_base, arg0, arg1);
 		if (ret < 0) {
 			ERROR("%s: write_cstate_stats failed(%d)\n",
 				__func__, ret);
 		}

 		break;

 	case MCE_CMD_IS_CCX_ALLOWED:
 		ret = ops->is_ccx_allowed(cpu_ari_base, arg0, arg1);
 		if (ret < 0) {
 			ERROR("%s: is_ccx_allowed failed(%d)\n", __func__, ret);
 			break;
 		}

 		/* update context to return CCx status value */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
 			      (uint64_t)(ret));

 		break;

 	case MCE_CMD_IS_SC7_ALLOWED:
 		ret = ops->is_sc7_allowed(cpu_ari_base, arg0, arg1);
 		if (ret < 0) {
 			ERROR("%s: is_sc7_allowed failed(%d)\n", __func__, ret);
 			break;
 		}

 		/* update context to return SC7 status value */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
 			      (uint64_t)(ret));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X3),
 			      (uint64_t)(ret));

 		break;

 	case MCE_CMD_ONLINE_CORE:
 		ret = ops->online_core(cpu_ari_base, arg0);
 		if (ret < 0) {
 			ERROR("%s: online_core failed(%d)\n", __func__, ret);
 		}

 		break;

 	case MCE_CMD_CC3_CTRL:
 		ret = ops->cc3_ctrl(cpu_ari_base, arg0, arg1, arg2);
 		if (ret < 0) {
 			ERROR("%s: cc3_ctrl failed(%d)\n", __func__, ret);
 		}

 		break;

 	case MCE_CMD_ECHO_DATA:
 		ret64 = ops->call_enum_misc(cpu_ari_base, TEGRA_ARI_MISC_ECHO,
 				arg0);

 		/* update context to return if echo'd data matched source */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
 			      ((ret64 == arg0) ? 1ULL : 0ULL));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2),
 			      ((ret64 == arg0) ? 1ULL : 0ULL));

 		break;

 	case MCE_CMD_READ_VERSIONS:
 		ret64 = ops->call_enum_misc(cpu_ari_base, TEGRA_ARI_MISC_VERSION,
 			arg0);

 		/*
 		 * version = minor(63:32) | major(31:0). Update context
 		 * to return major and minor version number.
 		 */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
 			      (ret64));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2),
 			      (ret64 >> 32ULL));

 		break;

 	case MCE_CMD_ENUM_FEATURES:
 		ret64 = ops->call_enum_misc(cpu_ari_base,
 				TEGRA_ARI_MISC_FEATURE_LEAF_0, arg0);

 		/* update context to return features value */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));

 		break;

 	case MCE_CMD_ROC_FLUSH_CACHE_TRBITS:
 		ret = ops->roc_flush_cache_trbits(cpu_ari_base);
 		if (ret < 0) {
 			ERROR("%s: flush cache_trbits failed(%d)\n", __func__,
 				ret);
 		}

 		break;

 	case MCE_CMD_ROC_FLUSH_CACHE:
 		ret = ops->roc_flush_cache(cpu_ari_base);
 		if (ret < 0) {
 			ERROR("%s: flush cache failed(%d)\n", __func__, ret);
 		}

 		break;

 	case MCE_CMD_ROC_CLEAN_CACHE:
 		ret = ops->roc_clean_cache(cpu_ari_base);
 		if (ret < 0) {
 			ERROR("%s: clean cache failed(%d)\n", __func__, ret);
 		}

 		break;

 	case MCE_CMD_ENUM_READ_MCA:
 		ret64 = ops->read_write_mca(cpu_ari_base, arg0, &arg1);

 		/* update context to return MCA data/error */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2), (arg1));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X3), (ret64));

 		break;

 	case MCE_CMD_ENUM_WRITE_MCA:
 		ret64 = ops->read_write_mca(cpu_ari_base, arg0, &arg1);

 		/* update context to return MCA error */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X3), (ret64));

 		break;

 #if ENABLE_CHIP_VERIFICATION_HARNESS
 	case MCE_CMD_ENABLE_LATIC:
 		/*
 		 * This call is not for production use. The constant value,
 		 * 0xFFFF0000, is specific to allowing for enabling LATIC on
 		 * pre-production parts for the chip verification harness.
 		 *
 		 * Enabling LATIC allows S/W to read the MINI ISPs in the
 		 * CCPLEX. The ISMs are used for various measurements relevant
 		 * to particular locations in the Silicon. They are small
 		 * counters which can be polled to determine how fast a
 		 * particular location in the Silicon is.
 		 */
 		ops->enter_ccplex_state(mce_get_curr_cpu_ari_base(),
 			0xFFFF0000);

 		break;
 #endif

 	case MCE_CMD_UNCORE_PERFMON_REQ:
 		ret = ops->read_write_uncore_perfmon(cpu_ari_base, arg0, &arg1);

 		/* update context to return data */
 		write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (arg1));
 		break;

 	case MCE_CMD_MISC_CCPLEX:
 		ops->misc_ccplex(cpu_ari_base, arg0, arg1);

 		break;

 	default:
 		ERROR("unknown MCE command (%lu)\n", cmd);
 		ret = EINVAL;
 		break;
 	}

 	return ret;
 }

 /*******************************************************************************
  * Handler to update the reset vector for CPUs
  ******************************************************************************/
 int32_t mce_update_reset_vector(void)
 {
 	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

 	ops->update_reset_vector(mce_get_curr_cpu_ari_base());

 	return 0;
 }

 static int32_t mce_update_ccplex_gsc(tegra_ari_gsc_index_t gsc_idx)
 {
 	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

 	ops->update_ccplex_gsc(mce_get_curr_cpu_ari_base(), gsc_idx);

 	return 0;
 }

 /*******************************************************************************
  * Handler to update carveout values for Video Memory Carveout region
  ******************************************************************************/
 int32_t mce_update_gsc_videomem(void)
 {
 	return mce_update_ccplex_gsc(TEGRA_ARI_GSC_VPR_IDX);
 }

 /*******************************************************************************
  * Handler to update carveout values for TZDRAM aperture
  ******************************************************************************/
 int32_t mce_update_gsc_tzdram(void)
 {
 	return mce_update_ccplex_gsc(TEGRA_ARI_GSC_TZ_DRAM_IDX);
 }

 /*******************************************************************************
  * Handler to update carveout values for TZ SysRAM aperture
  ******************************************************************************/
 int32_t mce_update_gsc_tzram(void)
 {
 	return mce_update_ccplex_gsc(TEGRA_ARI_GSC_TZRAM);
 }

 /*******************************************************************************
  * Handler to shutdown/reset the entire system
  ******************************************************************************/
 __dead2 void mce_enter_ccplex_state(uint32_t state_idx)
 {
 	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

 	/* sanity check state value */
 	if ((state_idx != TEGRA_ARI_MISC_CCPLEX_SHUTDOWN_POWER_OFF) &&
 	    (state_idx != TEGRA_ARI_MISC_CCPLEX_SHUTDOWN_REBOOT)) {
 		panic();
 	}

 	ops->enter_ccplex_state(mce_get_curr_cpu_ari_base(), state_idx);

 	/* wait till the CCPLEX powers down */
 	for (;;) {
 		;
 	}

 }

 /*******************************************************************************
  * Handler to issue the UPDATE_CSTATE_INFO request
  ******************************************************************************/
 void mce_update_cstate_info(const mce_cstate_info_t *cstate)
 {
 	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

 	/* issue the UPDATE_CSTATE_INFO request */
 	ops->update_cstate_info(mce_get_curr_cpu_ari_base(), cstate->cluster,
 		cstate->ccplex, cstate->system, cstate->system_state_force,
 		cstate->wake_mask, cstate->update_wake_mask);
 }

 /*******************************************************************************
  * Handler to read the MCE firmware version and check if it is compatible
  * with interface header the BL3-1 was compiled against
  ******************************************************************************/
 void mce_verify_firmware_version(void)
 {
 	const arch_mce_ops_t *ops;
 	uint32_t cpu_ari_base;
 	uint64_t version;
 	uint32_t major, minor;

 	/*
 	 * MCE firmware is not supported on simulation platforms.
 	 */
 	if (tegra_platform_is_emulation()) {

 		INFO("MCE firmware is not supported\n");

 	} else {
 		/* get a pointer to the CPU's arch_mce_ops_t struct */
 		ops = mce_get_curr_cpu_ops();

 		/* get the CPU's ARI base address */
 		cpu_ari_base = mce_get_curr_cpu_ari_base();

 		/*
 		 * Read the MCE firmware version and extract the major and minor
 		 * version fields
 		 */
 		version = ops->call_enum_misc(cpu_ari_base, TEGRA_ARI_MISC_VERSION, 0);
 		major = (uint32_t)version;
 		minor = (uint32_t)(version >> 32);

 		INFO("MCE Version - HW=%d:%d, SW=%d:%d\n", major, minor,
 			TEGRA_ARI_VERSION_MAJOR, TEGRA_ARI_VERSION_MINOR);

 		/*
 		 * Verify that the MCE firmware version and the interface header
 		 * match
 		 */
 		if (major != TEGRA_ARI_VERSION_MAJOR) {
 			ERROR("ARI major version mismatch\n");
 			panic();
 		}

 		if (minor < TEGRA_ARI_VERSION_MINOR) {
 			ERROR("ARI minor version mismatch\n");
 			panic();
 		}
 	}
 }
	/*
	* Copyright (c) 2015-2017, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch.h>
	#include <arch_helpers.h>
	#include <assert.h>
	#include <bl_common.h>
	#include <context.h>
	#include <context_mgmt.h>
	#include <debug.h>
	#include <denver.h>
	#include <mce.h>
	#include <mce_private.h>
	#include <mmio.h>
	#include <string.h>
	#include <sys/errno.h>
	#include <t18x_ari.h>
	#include <tegra_def.h>
	#include <tegra_platform.h>

	/* NVG functions handlers */
	static arch_mce_ops_t nvg_mce_ops = {
	.enter_cstate = nvg_enter_cstate,
	.update_cstate_info = nvg_update_cstate_info,
	.update_crossover_time = nvg_update_crossover_time,
	.read_cstate_stats = nvg_read_cstate_stats,
	.write_cstate_stats = nvg_write_cstate_stats,
	.call_enum_misc = ari_enumeration_misc,
	.is_ccx_allowed = nvg_is_ccx_allowed,
	.is_sc7_allowed = nvg_is_sc7_allowed,
	.online_core = nvg_online_core,
	.cc3_ctrl = nvg_cc3_ctrl,
	.update_reset_vector = ari_reset_vector_update,
	.roc_flush_cache = ari_roc_flush_cache,
	.roc_flush_cache_trbits = ari_roc_flush_cache_trbits,
	.roc_clean_cache = ari_roc_clean_cache,
	.read_write_mca = ari_read_write_mca,
	.update_ccplex_gsc = ari_update_ccplex_gsc,
	.enter_ccplex_state = ari_enter_ccplex_state,
	.read_write_uncore_perfmon = ari_read_write_uncore_perfmon,
	.misc_ccplex = ari_misc_ccplex
	};

	/* ARI functions handlers */
	static arch_mce_ops_t ari_mce_ops = {
	.enter_cstate = ari_enter_cstate,
	.update_cstate_info = ari_update_cstate_info,
	.update_crossover_time = ari_update_crossover_time,
	.read_cstate_stats = ari_read_cstate_stats,
	.write_cstate_stats = ari_write_cstate_stats,
	.call_enum_misc = ari_enumeration_misc,
	.is_ccx_allowed = ari_is_ccx_allowed,
	.is_sc7_allowed = ari_is_sc7_allowed,
	.online_core = ari_online_core,
	.cc3_ctrl = ari_cc3_ctrl,
	.update_reset_vector = ari_reset_vector_update,
	.roc_flush_cache = ari_roc_flush_cache,
	.roc_flush_cache_trbits = ari_roc_flush_cache_trbits,
	.roc_clean_cache = ari_roc_clean_cache,
	.read_write_mca = ari_read_write_mca,
	.update_ccplex_gsc = ari_update_ccplex_gsc,
	.enter_ccplex_state = ari_enter_ccplex_state,
	.read_write_uncore_perfmon = ari_read_write_uncore_perfmon,
	.misc_ccplex = ari_misc_ccplex
	};

	typedef struct {
	uint32_t ari_base;
	arch_mce_ops_t *ops;
	} mce_config_t;

	/* Table to hold the per-CPU ARI base address and function handlers */
	static mce_config_t mce_cfg_table[MCE_ARI_APERTURES_MAX] = {
	{
	/* A57 Core 0 */
	.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_0_OFFSET,
	.ops = &ari_mce_ops,
	},
	{
	/* A57 Core 1 */
	.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_1_OFFSET,
	.ops = &ari_mce_ops,
	},
	{
	/* A57 Core 2 */
	.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_2_OFFSET,
	.ops = &ari_mce_ops,
	},
	{
	/* A57 Core 3 */
	.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_3_OFFSET,
	.ops = &ari_mce_ops,
	},
	{
	/* D15 Core 0 */
	.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_4_OFFSET,
	.ops = &nvg_mce_ops,
	},
	{
	/* D15 Core 1 */
	.ari_base = TEGRA_MMCRAB_BASE + MCE_ARI_APERTURE_5_OFFSET,
	.ops = &nvg_mce_ops,
	}
	};

	static uint32_t mce_get_curr_cpu_ari_base(void)
	{
	uint64_t mpidr = read_mpidr();
	uint64_t cpuid = mpidr & (uint64_t)MPIDR_CPU_MASK;
	uint64_t impl = (read_midr() >> (uint64_t)MIDR_IMPL_SHIFT) & (uint64_t)MIDR_IMPL_MASK;

	/*
	* T186 has 2 CPU clusters, one with Denver CPUs and the other with
	* ARM CortexA-57 CPUs. Each cluster consists of 4 CPUs and the CPU
	* numbers start from 0. In order to get the proper arch_mce_ops_t
	* struct, we have to convert the Denver CPU ids to the corresponding
	* indices in the mce_ops_table array.
	*/
	if (impl == DENVER_IMPL) {
	cpuid \|= 0x4U;
	}

	return mce_cfg_table[cpuid].ari_base;
	}

	static arch_mce_ops_t *mce_get_curr_cpu_ops(void)
	{
	uint64_t mpidr = read_mpidr();
	uint64_t cpuid = mpidr & (uint64_t)MPIDR_CPU_MASK;
	uint64_t impl = (read_midr() >> (uint64_t)MIDR_IMPL_SHIFT) &
	(uint64_t)MIDR_IMPL_MASK;

	/*
	* T186 has 2 CPU clusters, one with Denver CPUs and the other with
	* ARM CortexA-57 CPUs. Each cluster consists of 4 CPUs and the CPU
	* numbers start from 0. In order to get the proper arch_mce_ops_t
	* struct, we have to convert the Denver CPU ids to the corresponding
	* indices in the mce_ops_table array.
	*/
	if (impl == DENVER_IMPL) {
	cpuid \|= 0x4U;
	}

	return mce_cfg_table[cpuid].ops;
	}

	/*******************************************************************************
	* Common handler for all MCE commands
	******************************************************************************/
	int32_t mce_command_handler(uint64_t cmd, uint64_t arg0, uint64_t arg1,
	uint64_t arg2)
	{
	const arch_mce_ops_t *ops;
	gp_regs_t *gp_regs = get_gpregs_ctx(cm_get_context(NON_SECURE));
	uint32_t cpu_ari_base;
	uint64_t ret64 = 0, arg3, arg4, arg5;
	int32_t ret = 0;

	assert(gp_regs != NULL);

	/* get a pointer to the CPU's arch_mce_ops_t struct */
	ops = mce_get_curr_cpu_ops();

	/* get the CPU's ARI base address */
	cpu_ari_base = mce_get_curr_cpu_ari_base();

	switch (cmd) {
	case MCE_CMD_ENTER_CSTATE:
	ret = ops->enter_cstate(cpu_ari_base, arg0, arg1);
	if (ret < 0) {
	ERROR("%s: enter_cstate failed(%d)\n", __func__, ret);
	}

	break;

	case MCE_CMD_UPDATE_CSTATE_INFO:
	/*
	* get the parameters required for the update cstate info
	* command
	*/
	arg3 = read_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X4));
	arg4 = read_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X5));
	arg5 = read_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X6));

	ret = ops->update_cstate_info(cpu_ari_base, (uint32_t)arg0,
	(uint32_t)arg1, (uint32_t)arg2, (uint8_t)arg3,
	(uint32_t)arg4, (uint8_t)arg5);
	if (ret < 0) {
	ERROR("%s: update_cstate_info failed(%d)\n",
	__func__, ret);
	}

	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X4), (0));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X5), (0));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X6), (0));

	break;

	case MCE_CMD_UPDATE_CROSSOVER_TIME:
	ret = ops->update_crossover_time(cpu_ari_base, arg0, arg1);
	if (ret < 0) {
	ERROR("%s: update_crossover_time failed(%d)\n",
	__func__, ret);
	}

	break;

	case MCE_CMD_READ_CSTATE_STATS:
	ret64 = ops->read_cstate_stats(cpu_ari_base, arg0);

	/* update context to return cstate stats value */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2), (ret64));

	break;

	case MCE_CMD_WRITE_CSTATE_STATS:
	ret = ops->write_cstate_stats(cpu_ari_base, arg0, arg1);
	if (ret < 0) {
	ERROR("%s: write_cstate_stats failed(%d)\n",
	__func__, ret);
	}

	break;

	case MCE_CMD_IS_CCX_ALLOWED:
	ret = ops->is_ccx_allowed(cpu_ari_base, arg0, arg1);
	if (ret < 0) {
	ERROR("%s: is_ccx_allowed failed(%d)\n", __func__, ret);
	break;
	}

	/* update context to return CCx status value */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
	(uint64_t)(ret));

	break;

	case MCE_CMD_IS_SC7_ALLOWED:
	ret = ops->is_sc7_allowed(cpu_ari_base, arg0, arg1);
	if (ret < 0) {
	ERROR("%s: is_sc7_allowed failed(%d)\n", __func__, ret);
	break;
	}

	/* update context to return SC7 status value */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
	(uint64_t)(ret));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X3),
	(uint64_t)(ret));

	break;

	case MCE_CMD_ONLINE_CORE:
	ret = ops->online_core(cpu_ari_base, arg0);
	if (ret < 0) {
	ERROR("%s: online_core failed(%d)\n", __func__, ret);
	}

	break;

	case MCE_CMD_CC3_CTRL:
	ret = ops->cc3_ctrl(cpu_ari_base, arg0, arg1, arg2);
	if (ret < 0) {
	ERROR("%s: cc3_ctrl failed(%d)\n", __func__, ret);
	}

	break;

	case MCE_CMD_ECHO_DATA:
	ret64 = ops->call_enum_misc(cpu_ari_base, TEGRA_ARI_MISC_ECHO,
	arg0);

	/* update context to return if echo'd data matched source */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
	((ret64 == arg0) ? 1ULL : 0ULL));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2),
	((ret64 == arg0) ? 1ULL : 0ULL));

	break;

	case MCE_CMD_READ_VERSIONS:
	ret64 = ops->call_enum_misc(cpu_ari_base, TEGRA_ARI_MISC_VERSION,
	arg0);

	/*
	* version = minor(63:32) \| major(31:0). Update context
	* to return major and minor version number.
	*/
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1),
	(ret64));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2),
	(ret64 >> 32ULL));

	break;

	case MCE_CMD_ENUM_FEATURES:
	ret64 = ops->call_enum_misc(cpu_ari_base,
	TEGRA_ARI_MISC_FEATURE_LEAF_0, arg0);

	/* update context to return features value */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));

	break;

	case MCE_CMD_ROC_FLUSH_CACHE_TRBITS:
	ret = ops->roc_flush_cache_trbits(cpu_ari_base);
	if (ret < 0) {
	ERROR("%s: flush cache_trbits failed(%d)\n", __func__,
	ret);
	}

	break;

	case MCE_CMD_ROC_FLUSH_CACHE:
	ret = ops->roc_flush_cache(cpu_ari_base);
	if (ret < 0) {
	ERROR("%s: flush cache failed(%d)\n", __func__, ret);
	}

	break;

	case MCE_CMD_ROC_CLEAN_CACHE:
	ret = ops->roc_clean_cache(cpu_ari_base);
	if (ret < 0) {
	ERROR("%s: clean cache failed(%d)\n", __func__, ret);
	}

	break;

	case MCE_CMD_ENUM_READ_MCA:
	ret64 = ops->read_write_mca(cpu_ari_base, arg0, &arg1);

	/* update context to return MCA data/error */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X2), (arg1));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X3), (ret64));

	break;

	case MCE_CMD_ENUM_WRITE_MCA:
	ret64 = ops->read_write_mca(cpu_ari_base, arg0, &arg1);

	/* update context to return MCA error */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (ret64));
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X3), (ret64));

	break;

	#if ENABLE_CHIP_VERIFICATION_HARNESS
	case MCE_CMD_ENABLE_LATIC:
	/*
	* This call is not for production use. The constant value,
	* 0xFFFF0000, is specific to allowing for enabling LATIC on
	* pre-production parts for the chip verification harness.
	*
	* Enabling LATIC allows S/W to read the MINI ISPs in the
	* CCPLEX. The ISMs are used for various measurements relevant
	* to particular locations in the Silicon. They are small
	* counters which can be polled to determine how fast a
	* particular location in the Silicon is.
	*/
	ops->enter_ccplex_state(mce_get_curr_cpu_ari_base(),
	0xFFFF0000);

	break;
	#endif

	case MCE_CMD_UNCORE_PERFMON_REQ:
	ret = ops->read_write_uncore_perfmon(cpu_ari_base, arg0, &arg1);

	/* update context to return data */
	write_ctx_reg((gp_regs), (uint32_t)(CTX_GPREG_X1), (arg1));
	break;

	case MCE_CMD_MISC_CCPLEX:
	ops->misc_ccplex(cpu_ari_base, arg0, arg1);

	break;

	default:
	ERROR("unknown MCE command (%lu)\n", cmd);
	ret = EINVAL;
	break;
	}

	return ret;
	}

	/*******************************************************************************
	* Handler to update the reset vector for CPUs
	******************************************************************************/
	int32_t mce_update_reset_vector(void)
	{
	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

	ops->update_reset_vector(mce_get_curr_cpu_ari_base());

	return 0;
	}

	static int32_t mce_update_ccplex_gsc(tegra_ari_gsc_index_t gsc_idx)
	{
	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

	ops->update_ccplex_gsc(mce_get_curr_cpu_ari_base(), gsc_idx);

	return 0;
	}

	/*******************************************************************************
	* Handler to update carveout values for Video Memory Carveout region
	******************************************************************************/
	int32_t mce_update_gsc_videomem(void)
	{
	return mce_update_ccplex_gsc(TEGRA_ARI_GSC_VPR_IDX);
	}

	/*******************************************************************************
	* Handler to update carveout values for TZDRAM aperture
	******************************************************************************/
	int32_t mce_update_gsc_tzdram(void)
	{
	return mce_update_ccplex_gsc(TEGRA_ARI_GSC_TZ_DRAM_IDX);
	}

	/*******************************************************************************
	* Handler to update carveout values for TZ SysRAM aperture
	******************************************************************************/
	int32_t mce_update_gsc_tzram(void)
	{
	return mce_update_ccplex_gsc(TEGRA_ARI_GSC_TZRAM);
	}

	/*******************************************************************************
	* Handler to shutdown/reset the entire system
	******************************************************************************/
	__dead2 void mce_enter_ccplex_state(uint32_t state_idx)
	{
	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

	/* sanity check state value */
	if ((state_idx != TEGRA_ARI_MISC_CCPLEX_SHUTDOWN_POWER_OFF) &&
	(state_idx != TEGRA_ARI_MISC_CCPLEX_SHUTDOWN_REBOOT)) {
	panic();
	}

	ops->enter_ccplex_state(mce_get_curr_cpu_ari_base(), state_idx);

	/* wait till the CCPLEX powers down */
	for (;;) {
	;
	}

	}

	/*******************************************************************************
	* Handler to issue the UPDATE_CSTATE_INFO request
	******************************************************************************/
	void mce_update_cstate_info(const mce_cstate_info_t *cstate)
	{
	const arch_mce_ops_t *ops = mce_get_curr_cpu_ops();

	/* issue the UPDATE_CSTATE_INFO request */
	ops->update_cstate_info(mce_get_curr_cpu_ari_base(), cstate->cluster,
	cstate->ccplex, cstate->system, cstate->system_state_force,
	cstate->wake_mask, cstate->update_wake_mask);
	}

	/*******************************************************************************
	* Handler to read the MCE firmware version and check if it is compatible
	* with interface header the BL3-1 was compiled against
	******************************************************************************/
	void mce_verify_firmware_version(void)
	{
	const arch_mce_ops_t *ops;
	uint32_t cpu_ari_base;
	uint64_t version;
	uint32_t major, minor;

	/*
	* MCE firmware is not supported on simulation platforms.
	*/
	if (tegra_platform_is_emulation()) {

	INFO("MCE firmware is not supported\n");

	} else {
	/* get a pointer to the CPU's arch_mce_ops_t struct */
	ops = mce_get_curr_cpu_ops();

	/* get the CPU's ARI base address */
	cpu_ari_base = mce_get_curr_cpu_ari_base();

	/*
	* Read the MCE firmware version and extract the major and minor
	* version fields
	*/
	version = ops->call_enum_misc(cpu_ari_base, TEGRA_ARI_MISC_VERSION, 0);
	major = (uint32_t)version;
	minor = (uint32_t)(version >> 32);

	INFO("MCE Version - HW=%d:%d, SW=%d:%d\n", major, minor,
	TEGRA_ARI_VERSION_MAJOR, TEGRA_ARI_VERSION_MINOR);

	/*
	* Verify that the MCE firmware version and the interface header
	* match
	*/
	if (major != TEGRA_ARI_VERSION_MAJOR) {
	ERROR("ARI major version mismatch\n");
	panic();
	}

	if (minor < TEGRA_ARI_VERSION_MINOR) {
	ERROR("ARI minor version mismatch\n");
	panic();
	}
	}
	}