plat/xilinx/zynqmp/plat_startup.c - imx-atf - Git at Google

 /*
  * Copyright (c) 2014-2016, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch_helpers.h>
 #include <assert.h>
 #include <debug.h>
 #include <mmio.h>
 #include "zynqmp_def.h"

 /*
  * ATFHandoffParams
  * Parameter		bitfield	encoding
  * -----------------------------------------------------------------------------
  * Exec State		0		0 -> Aarch64, 1-> Aarch32
  * endianness		1		0 -> LE, 1 -> BE
  * secure (TZ)		2		0 -> Non secure, 1 -> secure
  * EL			3:4		00 -> EL0, 01 -> EL1, 10 -> EL2, 11 -> EL3
  * CPU#			5:6		00 -> A53_0, 01 -> A53_1, 10 -> A53_2, 11 -> A53_3
  */

 #define FSBL_FLAGS_ESTATE_SHIFT		0
 #define FSBL_FLAGS_ESTATE_MASK		(1 << FSBL_FLAGS_ESTATE_SHIFT)
 #define FSBL_FLAGS_ESTATE_A64		0
 #define FSBL_FLAGS_ESTATE_A32		1

 #define FSBL_FLAGS_ENDIAN_SHIFT		1
 #define FSBL_FLAGS_ENDIAN_MASK		(1 << FSBL_FLAGS_ENDIAN_SHIFT)
 #define FSBL_FLAGS_ENDIAN_LE		0
 #define FSBL_FLAGS_ENDIAN_BE		1

 #define FSBL_FLAGS_TZ_SHIFT		2
 #define FSBL_FLAGS_TZ_MASK		(1 << FSBL_FLAGS_TZ_SHIFT)
 #define FSBL_FLAGS_NON_SECURE		0
 #define FSBL_FLAGS_SECURE		1

 #define FSBL_FLAGS_EL_SHIFT		3
 #define FSBL_FLAGS_EL_MASK		(3 << FSBL_FLAGS_EL_SHIFT)
 #define FSBL_FLAGS_EL0			0
 #define FSBL_FLAGS_EL1			1
 #define FSBL_FLAGS_EL2			2
 #define FSBL_FLAGS_EL3			3

 #define FSBL_FLAGS_CPU_SHIFT		5
 #define FSBL_FLAGS_CPU_MASK		(3 << FSBL_FLAGS_CPU_SHIFT)
 #define FSBL_FLAGS_A53_0		0
 #define FSBL_FLAGS_A53_1		1
 #define FSBL_FLAGS_A53_2		2
 #define FSBL_FLAGS_A53_3		3

 #define FSBL_MAX_PARTITIONS		8

 /* Structure corresponding to each partition entry */
 struct xfsbl_partition {
 	uint64_t entry_point;
 	uint64_t flags;
 };

 /* Structure for handoff parameters to ARM Trusted Firmware (ATF) */
 struct xfsbl_atf_handoff_params {
 	uint8_t magic[4];
 	uint32_t num_entries;
 	struct xfsbl_partition partition[FSBL_MAX_PARTITIONS];
 };

 /**
  * @partition: Pointer to partition struct
  *
  * Get the target CPU for @partition.
  *
  * Return: FSBL_FLAGS_A53_0, FSBL_FLAGS_A53_1, FSBL_FLAGS_A53_2 or FSBL_FLAGS_A53_3
  */
 static int get_fsbl_cpu(const struct xfsbl_partition *partition)
 {
 	uint64_t flags = partition->flags & FSBL_FLAGS_CPU_MASK;

 	return flags >> FSBL_FLAGS_CPU_SHIFT;
 }

 /**
  * @partition: Pointer to partition struct
  *
  * Get the target exception level for @partition.
  *
  * Return: FSBL_FLAGS_EL0, FSBL_FLAGS_EL1, FSBL_FLAGS_EL2 or FSBL_FLAGS_EL3
  */
 static int get_fsbl_el(const struct xfsbl_partition *partition)
 {
 	uint64_t flags = partition->flags & FSBL_FLAGS_EL_MASK;

 	return flags >> FSBL_FLAGS_EL_SHIFT;
 }

 /**
  * @partition: Pointer to partition struct
  *
  * Get the target security state for @partition.
  *
  * Return: FSBL_FLAGS_NON_SECURE or FSBL_FLAGS_SECURE
  */
 static int get_fsbl_ss(const struct xfsbl_partition *partition)
 {
 	uint64_t flags = partition->flags & FSBL_FLAGS_TZ_MASK;

 	return flags >> FSBL_FLAGS_TZ_SHIFT;
 }

 /**
  * @partition: Pointer to partition struct
  *
  * Get the target endianness for @partition.
  *
  * Return: SPSR_E_LITTLE or SPSR_E_BIG
  */
 static int get_fsbl_endian(const struct xfsbl_partition *partition)
 {
 	uint64_t flags = partition->flags & FSBL_FLAGS_ENDIAN_MASK;

 	flags >>= FSBL_FLAGS_ENDIAN_SHIFT;

 	if (flags == FSBL_FLAGS_ENDIAN_BE)
 		return SPSR_E_BIG;
 	else
 		return SPSR_E_LITTLE;
 }

 /**
  * @partition: Pointer to partition struct
  *
  * Get the target execution state for @partition.
  *
  * Return: FSBL_FLAGS_ESTATE_A32 or FSBL_FLAGS_ESTATE_A64
  */
 static int get_fsbl_estate(const struct xfsbl_partition *partition)
 {
 	uint64_t flags = partition->flags & FSBL_FLAGS_ESTATE_MASK;

 	return flags >> FSBL_FLAGS_ESTATE_SHIFT;
 }

 /**
  * Populates the bl32 and bl33 image info structures
  * @bl32:	BL32 image info structure
  * @bl33:	BL33 image info structure
  *
  * Process the handoff paramters from the FSBL and populate the BL32 and BL33
  * image info structures accordingly.
  */
 void fsbl_atf_handover(entry_point_info_t *bl32, entry_point_info_t *bl33)
 {
 	uint64_t atf_handoff_addr;
 	const struct xfsbl_atf_handoff_params *ATFHandoffParams;

 	atf_handoff_addr = mmio_read_32(PMU_GLOBAL_GEN_STORAGE6);
 	assert((atf_handoff_addr < BL31_BASE) ||
 	       (atf_handoff_addr > (uint64_t)&__BL31_END__));
 	if (!atf_handoff_addr) {
 		ERROR("BL31: No ATF handoff structure passed\n");
 		panic();
 	}

 	ATFHandoffParams = (struct xfsbl_atf_handoff_params *)atf_handoff_addr;
 	if ((ATFHandoffParams->magic[0] != 'X') ||
 	    (ATFHandoffParams->magic[1] != 'L') ||
 	    (ATFHandoffParams->magic[2] != 'N') ||
 	    (ATFHandoffParams->magic[3] != 'X')) {
 		ERROR("BL31: invalid ATF handoff structure at %lx\n",
 		      atf_handoff_addr);
 		panic();
 	}

 	VERBOSE("BL31: ATF handoff params at:0x%lx, entries:%u\n",
 		atf_handoff_addr, ATFHandoffParams->num_entries);
 	if (ATFHandoffParams->num_entries > FSBL_MAX_PARTITIONS) {
 		ERROR("BL31: ATF handoff params: too many partitions (%u/%u)\n",
 		      ATFHandoffParams->num_entries, FSBL_MAX_PARTITIONS);
 		panic();
 	}

 	/*
 	 * we loop over all passed entries but only populate two image structs
 	 * (bl32, bl33). I.e. the last applicable images in the handoff
 	 * structure will be used for the hand off
 	 */
 	for (size_t i = 0; i < ATFHandoffParams->num_entries; i++) {
 		entry_point_info_t *image;
 		int target_estate, target_secure;
 		int target_cpu, target_endianness, target_el;

 		VERBOSE("BL31: %zd: entry:0x%lx, flags:0x%lx\n", i,
 			ATFHandoffParams->partition[i].entry_point,
 			ATFHandoffParams->partition[i].flags);

 		target_cpu = get_fsbl_cpu(&ATFHandoffParams->partition[i]);
 		if (target_cpu != FSBL_FLAGS_A53_0) {
 			WARN("BL31: invalid target CPU (%i)\n", target_cpu);
 			continue;
 		}

 		target_el = get_fsbl_el(&ATFHandoffParams->partition[i]);
 		if ((target_el == FSBL_FLAGS_EL3) ||
 		    (target_el == FSBL_FLAGS_EL0)) {
 			WARN("BL31: invalid exception level (%i)\n", target_el);
 			continue;
 		}

 		target_secure = get_fsbl_ss(&ATFHandoffParams->partition[i]);
 		if (target_secure == FSBL_FLAGS_SECURE &&
 		    target_el == FSBL_FLAGS_EL2) {
 			WARN("BL31: invalid security state (%i) for exception level (%i)\n",
 			     target_secure, target_el);
 			continue;
 		}

 		target_estate = get_fsbl_estate(&ATFHandoffParams->partition[i]);
 		target_endianness = get_fsbl_endian(&ATFHandoffParams->partition[i]);

 		if (target_secure == FSBL_FLAGS_SECURE) {
 			image = bl32;

 			if (target_estate == FSBL_FLAGS_ESTATE_A32)
 				bl32->spsr = SPSR_MODE32(MODE32_svc, SPSR_T_ARM,
 							 target_endianness,
 							 DISABLE_ALL_EXCEPTIONS);
 			else
 				bl32->spsr = SPSR_64(MODE_EL1, MODE_SP_ELX,
 						     DISABLE_ALL_EXCEPTIONS);
 		} else {
 			image = bl33;

 			if (target_estate == FSBL_FLAGS_ESTATE_A32) {
 				if (target_el == FSBL_FLAGS_EL2)
 					target_el = MODE32_hyp;
 				else
 					target_el = MODE32_sys;

 				bl33->spsr = SPSR_MODE32(target_el, SPSR_T_ARM,
 							 target_endianness,
 							 DISABLE_ALL_EXCEPTIONS);
 			} else {
 				if (target_el == FSBL_FLAGS_EL2)
 					target_el = MODE_EL2;
 				else
 					target_el = MODE_EL1;

 				bl33->spsr = SPSR_64(target_el, MODE_SP_ELX,
 						     DISABLE_ALL_EXCEPTIONS);
 			}
 		}

 		VERBOSE("Setting up %s entry point to:%lx, el:%x\n",
 			target_secure == FSBL_FLAGS_SECURE ? "BL32" : "BL33",
 			ATFHandoffParams->partition[i].entry_point,
 			target_el);
 		image->pc = ATFHandoffParams->partition[i].entry_point;

 		if (target_endianness == SPSR_E_BIG)
 			EP_SET_EE(image->h.attr, EP_EE_BIG);
 		else
 			EP_SET_EE(image->h.attr, EP_EE_LITTLE);
 	}
 }
	/*
	* Copyright (c) 2014-2016, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch_helpers.h>
	#include <assert.h>
	#include <debug.h>
	#include <mmio.h>
	#include "zynqmp_def.h"

	/*
	* ATFHandoffParams
	* Parameter bitfield encoding
	* -----------------------------------------------------------------------------
	* Exec State 0 0 -> Aarch64, 1-> Aarch32
	* endianness 1 0 -> LE, 1 -> BE
	* secure (TZ) 2 0 -> Non secure, 1 -> secure
	* EL 3:4 00 -> EL0, 01 -> EL1, 10 -> EL2, 11 -> EL3
	* CPU# 5:6 00 -> A53_0, 01 -> A53_1, 10 -> A53_2, 11 -> A53_3
	*/

	#define FSBL_FLAGS_ESTATE_SHIFT 0
	#define FSBL_FLAGS_ESTATE_MASK (1 << FSBL_FLAGS_ESTATE_SHIFT)
	#define FSBL_FLAGS_ESTATE_A64 0
	#define FSBL_FLAGS_ESTATE_A32 1

	#define FSBL_FLAGS_ENDIAN_SHIFT 1
	#define FSBL_FLAGS_ENDIAN_MASK (1 << FSBL_FLAGS_ENDIAN_SHIFT)
	#define FSBL_FLAGS_ENDIAN_LE 0
	#define FSBL_FLAGS_ENDIAN_BE 1

	#define FSBL_FLAGS_TZ_SHIFT 2
	#define FSBL_FLAGS_TZ_MASK (1 << FSBL_FLAGS_TZ_SHIFT)
	#define FSBL_FLAGS_NON_SECURE 0
	#define FSBL_FLAGS_SECURE 1

	#define FSBL_FLAGS_EL_SHIFT 3
	#define FSBL_FLAGS_EL_MASK (3 << FSBL_FLAGS_EL_SHIFT)
	#define FSBL_FLAGS_EL0 0
	#define FSBL_FLAGS_EL1 1
	#define FSBL_FLAGS_EL2 2
	#define FSBL_FLAGS_EL3 3

	#define FSBL_FLAGS_CPU_SHIFT 5
	#define FSBL_FLAGS_CPU_MASK (3 << FSBL_FLAGS_CPU_SHIFT)
	#define FSBL_FLAGS_A53_0 0
	#define FSBL_FLAGS_A53_1 1
	#define FSBL_FLAGS_A53_2 2
	#define FSBL_FLAGS_A53_3 3

	#define FSBL_MAX_PARTITIONS 8

	/* Structure corresponding to each partition entry */
	struct xfsbl_partition {
	uint64_t entry_point;
	uint64_t flags;
	};

	/* Structure for handoff parameters to ARM Trusted Firmware (ATF) */
	struct xfsbl_atf_handoff_params {
	uint8_t magic[4];
	uint32_t num_entries;
	struct xfsbl_partition partition[FSBL_MAX_PARTITIONS];
	};

	/**
	* @partition: Pointer to partition struct
	*
	* Get the target CPU for @partition.
	*
	* Return: FSBL_FLAGS_A53_0, FSBL_FLAGS_A53_1, FSBL_FLAGS_A53_2 or FSBL_FLAGS_A53_3
	*/
	static int get_fsbl_cpu(const struct xfsbl_partition *partition)
	{
	uint64_t flags = partition->flags & FSBL_FLAGS_CPU_MASK;

	return flags >> FSBL_FLAGS_CPU_SHIFT;
	}

	/**
	* @partition: Pointer to partition struct
	*
	* Get the target exception level for @partition.
	*
	* Return: FSBL_FLAGS_EL0, FSBL_FLAGS_EL1, FSBL_FLAGS_EL2 or FSBL_FLAGS_EL3
	*/
	static int get_fsbl_el(const struct xfsbl_partition *partition)
	{
	uint64_t flags = partition->flags & FSBL_FLAGS_EL_MASK;

	return flags >> FSBL_FLAGS_EL_SHIFT;
	}

	/**
	* @partition: Pointer to partition struct
	*
	* Get the target security state for @partition.
	*
	* Return: FSBL_FLAGS_NON_SECURE or FSBL_FLAGS_SECURE
	*/
	static int get_fsbl_ss(const struct xfsbl_partition *partition)
	{
	uint64_t flags = partition->flags & FSBL_FLAGS_TZ_MASK;

	return flags >> FSBL_FLAGS_TZ_SHIFT;
	}

	/**
	* @partition: Pointer to partition struct
	*
	* Get the target endianness for @partition.
	*
	* Return: SPSR_E_LITTLE or SPSR_E_BIG
	*/
	static int get_fsbl_endian(const struct xfsbl_partition *partition)
	{
	uint64_t flags = partition->flags & FSBL_FLAGS_ENDIAN_MASK;

	flags >>= FSBL_FLAGS_ENDIAN_SHIFT;

	if (flags == FSBL_FLAGS_ENDIAN_BE)
	return SPSR_E_BIG;
	else
	return SPSR_E_LITTLE;
	}

	/**
	* @partition: Pointer to partition struct
	*
	* Get the target execution state for @partition.
	*
	* Return: FSBL_FLAGS_ESTATE_A32 or FSBL_FLAGS_ESTATE_A64
	*/
	static int get_fsbl_estate(const struct xfsbl_partition *partition)
	{
	uint64_t flags = partition->flags & FSBL_FLAGS_ESTATE_MASK;

	return flags >> FSBL_FLAGS_ESTATE_SHIFT;
	}

	/**
	* Populates the bl32 and bl33 image info structures
	* @bl32: BL32 image info structure
	* @bl33: BL33 image info structure
	*
	* Process the handoff paramters from the FSBL and populate the BL32 and BL33
	* image info structures accordingly.
	*/
	void fsbl_atf_handover(entry_point_info_t bl32, entry_point_info_t bl33)
	{
	uint64_t atf_handoff_addr;
	const struct xfsbl_atf_handoff_params *ATFHandoffParams;

	atf_handoff_addr = mmio_read_32(PMU_GLOBAL_GEN_STORAGE6);
	assert((atf_handoff_addr < BL31_BASE) \|\|
	(atf_handoff_addr > (uint64_t)&__BL31_END__));
	if (!atf_handoff_addr) {
	ERROR("BL31: No ATF handoff structure passed\n");
	panic();
	}

	ATFHandoffParams = (struct xfsbl_atf_handoff_params *)atf_handoff_addr;
	if ((ATFHandoffParams->magic[0] != 'X') \|\|
	(ATFHandoffParams->magic[1] != 'L') \|\|
	(ATFHandoffParams->magic[2] != 'N') \|\|
	(ATFHandoffParams->magic[3] != 'X')) {
	ERROR("BL31: invalid ATF handoff structure at %lx\n",
	atf_handoff_addr);
	panic();
	}

	VERBOSE("BL31: ATF handoff params at:0x%lx, entries:%u\n",
	atf_handoff_addr, ATFHandoffParams->num_entries);
	if (ATFHandoffParams->num_entries > FSBL_MAX_PARTITIONS) {
	ERROR("BL31: ATF handoff params: too many partitions (%u/%u)\n",
	ATFHandoffParams->num_entries, FSBL_MAX_PARTITIONS);
	panic();
	}

	/*
	* we loop over all passed entries but only populate two image structs
	* (bl32, bl33). I.e. the last applicable images in the handoff
	* structure will be used for the hand off
	*/
	for (size_t i = 0; i < ATFHandoffParams->num_entries; i++) {
	entry_point_info_t *image;
	int target_estate, target_secure;
	int target_cpu, target_endianness, target_el;

	VERBOSE("BL31: %zd: entry:0x%lx, flags:0x%lx\n", i,
	ATFHandoffParams->partition[i].entry_point,
	ATFHandoffParams->partition[i].flags);

	target_cpu = get_fsbl_cpu(&ATFHandoffParams->partition[i]);
	if (target_cpu != FSBL_FLAGS_A53_0) {
	WARN("BL31: invalid target CPU (%i)\n", target_cpu);
	continue;
	}

	target_el = get_fsbl_el(&ATFHandoffParams->partition[i]);
	if ((target_el == FSBL_FLAGS_EL3) \|\|
	(target_el == FSBL_FLAGS_EL0)) {
	WARN("BL31: invalid exception level (%i)\n", target_el);
	continue;
	}

	target_secure = get_fsbl_ss(&ATFHandoffParams->partition[i]);
	if (target_secure == FSBL_FLAGS_SECURE &&
	target_el == FSBL_FLAGS_EL2) {
	WARN("BL31: invalid security state (%i) for exception level (%i)\n",
	target_secure, target_el);
	continue;
	}

	target_estate = get_fsbl_estate(&ATFHandoffParams->partition[i]);
	target_endianness = get_fsbl_endian(&ATFHandoffParams->partition[i]);

	if (target_secure == FSBL_FLAGS_SECURE) {
	image = bl32;

	if (target_estate == FSBL_FLAGS_ESTATE_A32)
	bl32->spsr = SPSR_MODE32(MODE32_svc, SPSR_T_ARM,
	target_endianness,
	DISABLE_ALL_EXCEPTIONS);
	else
	bl32->spsr = SPSR_64(MODE_EL1, MODE_SP_ELX,
	DISABLE_ALL_EXCEPTIONS);
	} else {
	image = bl33;

	if (target_estate == FSBL_FLAGS_ESTATE_A32) {
	if (target_el == FSBL_FLAGS_EL2)
	target_el = MODE32_hyp;
	else
	target_el = MODE32_sys;

	bl33->spsr = SPSR_MODE32(target_el, SPSR_T_ARM,
	target_endianness,
	DISABLE_ALL_EXCEPTIONS);
	} else {
	if (target_el == FSBL_FLAGS_EL2)
	target_el = MODE_EL2;
	else
	target_el = MODE_EL1;

	bl33->spsr = SPSR_64(target_el, MODE_SP_ELX,
	DISABLE_ALL_EXCEPTIONS);
	}
	}

	VERBOSE("Setting up %s entry point to:%lx, el:%x\n",
	target_secure == FSBL_FLAGS_SECURE ? "BL32" : "BL33",
	ATFHandoffParams->partition[i].entry_point,
	target_el);
	image->pc = ATFHandoffParams->partition[i].entry_point;

	if (target_endianness == SPSR_E_BIG)
	EP_SET_EE(image->h.attr, EP_EE_BIG);
	else
	EP_SET_EE(image->h.attr, EP_EE_LITTLE);
	}
	}