arch/arm64/include/asm/cpufeature.h - linux - Git at Google

 /*
  * Copyright (C) 2014 Linaro Ltd. <ard.biesheuvel@linaro.org>
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 as
  * published by the Free Software Foundation.
  */

 #ifndef __ASM_CPUFEATURE_H
 #define __ASM_CPUFEATURE_H

 #include <asm/cpucaps.h>
 #include <asm/cputype.h>
 #include <asm/hwcap.h>
 #include <asm/sysreg.h>

 /*
  * In the arm64 world (as in the ARM world), elf_hwcap is used both internally
  * in the kernel and for user space to keep track of which optional features
  * are supported by the current system. So let's map feature 'x' to HWCAP_x.
  * Note that HWCAP_x constants are bit fields so we need to take the log.
  */

 #define MAX_CPU_FEATURES	(8 * sizeof(elf_hwcap))
 #define cpu_feature(x)		ilog2(HWCAP_ ## x)

 #ifndef __ASSEMBLY__

 #include <linux/bug.h>
 #include <linux/jump_label.h>
 #include <linux/kernel.h>

 /*
  * CPU feature register tracking
  *
  * The safe value of a CPUID feature field is dependent on the implications
  * of the values assigned to it by the architecture. Based on the relationship
  * between the values, the features are classified into 3 types - LOWER_SAFE,
  * HIGHER_SAFE and EXACT.
  *
  * The lowest value of all the CPUs is chosen for LOWER_SAFE and highest
  * for HIGHER_SAFE. It is expected that all CPUs have the same value for
  * a field when EXACT is specified, failing which, the safe value specified
  * in the table is chosen.
  */

 enum ftr_type {
 	FTR_EXACT,	/* Use a predefined safe value */
 	FTR_LOWER_SAFE,	/* Smaller value is safe */
 	FTR_HIGHER_SAFE,/* Bigger value is safe */
 };

 #define FTR_STRICT	true	/* SANITY check strict matching required */
 #define FTR_NONSTRICT	false	/* SANITY check ignored */

 #define FTR_SIGNED	true	/* Value should be treated as signed */
 #define FTR_UNSIGNED	false	/* Value should be treated as unsigned */

 #define FTR_VISIBLE	true	/* Feature visible to the user space */
 #define FTR_HIDDEN	false	/* Feature is hidden from the user */

 #define FTR_VISIBLE_IF_IS_ENABLED(config)		\
 	(IS_ENABLED(config) ? FTR_VISIBLE : FTR_HIDDEN)

 struct arm64_ftr_bits {
 	bool		sign;	/* Value is signed ? */
 	bool		visible;
 	bool		strict;	/* CPU Sanity check: strict matching required ? */
 	enum ftr_type	type;
 	u8		shift;
 	u8		width;
 	s64		safe_val; /* safe value for FTR_EXACT features */
 };

 /*
  * @arm64_ftr_reg - Feature register
  * @strict_mask		Bits which should match across all CPUs for sanity.
  * @sys_val		Safe value across the CPUs (system view)
  */
 struct arm64_ftr_reg {
 	const char			*name;
 	u64				strict_mask;
 	u64				user_mask;
 	u64				sys_val;
 	u64				user_val;
 	const struct arm64_ftr_bits	*ftr_bits;
 };

 extern struct arm64_ftr_reg arm64_ftr_reg_ctrel0;

 /*
  * CPU capabilities:
  *
  * We use arm64_cpu_capabilities to represent system features, errata work
  * arounds (both used internally by kernel and tracked in cpu_hwcaps) and
  * ELF HWCAPs (which are exposed to user).
  *
  * To support systems with heterogeneous CPUs, we need to make sure that we
  * detect the capabilities correctly on the system and take appropriate
  * measures to ensure there are no incompatibilities.
  *
  * This comment tries to explain how we treat the capabilities.
  * Each capability has the following list of attributes :
  *
  * 1) Scope of Detection : The system detects a given capability by
  *    performing some checks at runtime. This could be, e.g, checking the
  *    value of a field in CPU ID feature register or checking the cpu
  *    model. The capability provides a call back ( @matches() ) to
  *    perform the check. Scope defines how the checks should be performed.
  *    There are three cases:
  *
  *     a) SCOPE_LOCAL_CPU: check all the CPUs and "detect" if at least one
  *        matches. This implies, we have to run the check on all the
  *        booting CPUs, until the system decides that state of the
  *        capability is finalised. (See section 2 below)
  *		Or
  *     b) SCOPE_SYSTEM: check all the CPUs and "detect" if all the CPUs
  *        matches. This implies, we run the check only once, when the
  *        system decides to finalise the state of the capability. If the
  *        capability relies on a field in one of the CPU ID feature
  *        registers, we use the sanitised value of the register from the
  *        CPU feature infrastructure to make the decision.
  *		Or
  *     c) SCOPE_BOOT_CPU: Check only on the primary boot CPU to detect the
  *        feature. This category is for features that are "finalised"
  *        (or used) by the kernel very early even before the SMP cpus
  *        are brought up.
  *
  *    The process of detection is usually denoted by "update" capability
  *    state in the code.
  *
  * 2) Finalise the state : The kernel should finalise the state of a
  *    capability at some point during its execution and take necessary
  *    actions if any. Usually, this is done, after all the boot-time
  *    enabled CPUs are brought up by the kernel, so that it can make
  *    better decision based on the available set of CPUs. However, there
  *    are some special cases, where the action is taken during the early
  *    boot by the primary boot CPU. (e.g, running the kernel at EL2 with
  *    Virtualisation Host Extensions). The kernel usually disallows any
  *    changes to the state of a capability once it finalises the capability
  *    and takes any action, as it may be impossible to execute the actions
  *    safely. A CPU brought up after a capability is "finalised" is
  *    referred to as "Late CPU" w.r.t the capability. e.g, all secondary
  *    CPUs are treated "late CPUs" for capabilities determined by the boot
  *    CPU.
  *
  *    At the moment there are two passes of finalising the capabilities.
  *      a) Boot CPU scope capabilities - Finalised by primary boot CPU via
  *         setup_boot_cpu_capabilities().
  *      b) Everything except (a) - Run via setup_system_capabilities().
  *
  * 3) Verification: When a CPU is brought online (e.g, by user or by the
  *    kernel), the kernel should make sure that it is safe to use the CPU,
  *    by verifying that the CPU is compliant with the state of the
  *    capabilities finalised already. This happens via :
  *
  *	secondary_start_kernel()-> check_local_cpu_capabilities()
  *
  *    As explained in (2) above, capabilities could be finalised at
  *    different points in the execution. Each newly booted CPU is verified
  *    against the capabilities that have been finalised by the time it
  *    boots.
  *
  *	a) SCOPE_BOOT_CPU : All CPUs are verified against the capability
  *	except for the primary boot CPU.
  *
  *	b) SCOPE_LOCAL_CPU, SCOPE_SYSTEM: All CPUs hotplugged on by the
  *	user after the kernel boot are verified against the capability.
  *
  *    If there is a conflict, the kernel takes an action, based on the
  *    severity (e.g, a CPU could be prevented from booting or cause a
  *    kernel panic). The CPU is allowed to "affect" the state of the
  *    capability, if it has not been finalised already. See section 5
  *    for more details on conflicts.
  *
  * 4) Action: As mentioned in (2), the kernel can take an action for each
  *    detected capability, on all CPUs on the system. Appropriate actions
  *    include, turning on an architectural feature, modifying the control
  *    registers (e.g, SCTLR, TCR etc.) or patching the kernel via
  *    alternatives. The kernel patching is batched and performed at later
  *    point. The actions are always initiated only after the capability
  *    is finalised. This is usally denoted by "enabling" the capability.
  *    The actions are initiated as follows :
  *	a) Action is triggered on all online CPUs, after the capability is
  *	finalised, invoked within the stop_machine() context from
  *	enable_cpu_capabilitie().
  *
  *	b) Any late CPU, brought up after (1), the action is triggered via:
  *
  *	  check_local_cpu_capabilities() -> verify_local_cpu_capabilities()
  *
  * 5) Conflicts: Based on the state of the capability on a late CPU vs.
  *    the system state, we could have the following combinations :
  *
  *		x-----------------------------x
  *		| Type  | System   | Late CPU |
  *		|-----------------------------|
  *		|  a    |   y      |    n     |
  *		|-----------------------------|
  *		|  b    |   n      |    y     |
  *		x-----------------------------x
  *
  *     Two separate flag bits are defined to indicate whether each kind of
  *     conflict can be allowed:
  *		ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU - Case(a) is allowed
  *		ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU - Case(b) is allowed
  *
  *     Case (a) is not permitted for a capability that the system requires
  *     all CPUs to have in order for the capability to be enabled. This is
  *     typical for capabilities that represent enhanced functionality.
  *
  *     Case (b) is not permitted for a capability that must be enabled
  *     during boot if any CPU in the system requires it in order to run
  *     safely. This is typical for erratum work arounds that cannot be
  *     enabled after the corresponding capability is finalised.
  *
  *     In some non-typical cases either both (a) and (b), or neither,
  *     should be permitted. This can be described by including neither
  *     or both flags in the capability's type field.
  */


 /*
  * Decide how the capability is detected.
  * On any local CPU vs System wide vs the primary boot CPU
  */
 #define ARM64_CPUCAP_SCOPE_LOCAL_CPU		((u16)BIT(0))
 #define ARM64_CPUCAP_SCOPE_SYSTEM		((u16)BIT(1))
 /*
  * The capabilitiy is detected on the Boot CPU and is used by kernel
  * during early boot. i.e, the capability should be "detected" and
  * "enabled" as early as possibly on all booting CPUs.
  */
 #define ARM64_CPUCAP_SCOPE_BOOT_CPU		((u16)BIT(2))
 #define ARM64_CPUCAP_SCOPE_MASK			\
 	(ARM64_CPUCAP_SCOPE_SYSTEM	|	\
 	 ARM64_CPUCAP_SCOPE_LOCAL_CPU	|	\
 	 ARM64_CPUCAP_SCOPE_BOOT_CPU)

 #define SCOPE_SYSTEM				ARM64_CPUCAP_SCOPE_SYSTEM
 #define SCOPE_LOCAL_CPU				ARM64_CPUCAP_SCOPE_LOCAL_CPU
 #define SCOPE_BOOT_CPU				ARM64_CPUCAP_SCOPE_BOOT_CPU
 #define SCOPE_ALL				ARM64_CPUCAP_SCOPE_MASK

 /*
  * Is it permitted for a late CPU to have this capability when system
  * hasn't already enabled it ?
  */
 #define ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU	((u16)BIT(4))
 /* Is it safe for a late CPU to miss this capability when system has it */
 #define ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU	((u16)BIT(5))

 /*
  * CPU errata workarounds that need to be enabled at boot time if one or
  * more CPUs in the system requires it. When one of these capabilities
  * has been enabled, it is safe to allow any CPU to boot that doesn't
  * require the workaround. However, it is not safe if a "late" CPU
  * requires a workaround and the system hasn't enabled it already.
  */
 #define ARM64_CPUCAP_LOCAL_CPU_ERRATUM		\
 	(ARM64_CPUCAP_SCOPE_LOCAL_CPU | ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU)
 /*
  * CPU feature detected at boot time based on system-wide value of a
  * feature. It is safe for a late CPU to have this feature even though
  * the system hasn't enabled it, although the featuer will not be used
  * by Linux in this case. If the system has enabled this feature already,
  * then every late CPU must have it.
  */
 #define ARM64_CPUCAP_SYSTEM_FEATURE	\
 	(ARM64_CPUCAP_SCOPE_SYSTEM | ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU)
 /*
  * CPU feature detected at boot time based on feature of one or more CPUs.
  * All possible conflicts for a late CPU are ignored.
  */
 #define ARM64_CPUCAP_WEAK_LOCAL_CPU_FEATURE		\
 	(ARM64_CPUCAP_SCOPE_LOCAL_CPU		|	\
 	 ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU	|	\
 	 ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU)

 /*
  * CPU feature detected at boot time, on one or more CPUs. A late CPU
  * is not allowed to have the capability when the system doesn't have it.
  * It is Ok for a late CPU to miss the feature.
  */
 #define ARM64_CPUCAP_BOOT_RESTRICTED_CPU_LOCAL_FEATURE	\
 	(ARM64_CPUCAP_SCOPE_LOCAL_CPU		|	\
 	 ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU)

 /*
  * CPU feature used early in the boot based on the boot CPU. All secondary
  * CPUs must match the state of the capability as detected by the boot CPU.
  */
 #define ARM64_CPUCAP_STRICT_BOOT_CPU_FEATURE ARM64_CPUCAP_SCOPE_BOOT_CPU

 struct arm64_cpu_capabilities {
 	const char *desc;
 	u16 capability;
 	u16 type;
 	bool (*matches)(const struct arm64_cpu_capabilities *caps, int scope);
 	/*
 	 * Take the appropriate actions to enable this capability for this CPU.
 	 * For each successfully booted CPU, this method is called for each
 	 * globally detected capability.
 	 */
 	void (*cpu_enable)(const struct arm64_cpu_capabilities *cap);
 	union {
 		struct {	/* To be used for erratum handling only */
 			struct midr_range midr_range;
 			const struct arm64_midr_revidr {
 				u32 midr_rv;		/* revision/variant */
 				u32 revidr_mask;
 			} * const fixed_revs;
 		};

 		const struct midr_range *midr_range_list;
 		struct {	/* Feature register checking */
 			u32 sys_reg;
 			u8 field_pos;
 			u8 min_field_value;
 			u8 hwcap_type;
 			bool sign;
 			unsigned long hwcap;
 		};
 		/*
 		 * A list of "matches/cpu_enable" pair for the same
 		 * "capability" of the same "type" as described by the parent.
 		 * Only matches(), cpu_enable() and fields relevant to these
 		 * methods are significant in the list. The cpu_enable is
 		 * invoked only if the corresponding entry "matches()".
 		 * However, if a cpu_enable() method is associated
 		 * with multiple matches(), care should be taken that either
 		 * the match criteria are mutually exclusive, or that the
 		 * method is robust against being called multiple times.
 		 */
 		const struct arm64_cpu_capabilities *match_list;
 	};
 };

 static inline int cpucap_default_scope(const struct arm64_cpu_capabilities *cap)
 {
 	return cap->type & ARM64_CPUCAP_SCOPE_MASK;
 }

 static inline bool
 cpucap_late_cpu_optional(const struct arm64_cpu_capabilities *cap)
 {
 	return !!(cap->type & ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU);
 }

 static inline bool
 cpucap_late_cpu_permitted(const struct arm64_cpu_capabilities *cap)
 {
 	return !!(cap->type & ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU);
 }

 extern DECLARE_BITMAP(cpu_hwcaps, ARM64_NCAPS);
 extern struct static_key_false cpu_hwcap_keys[ARM64_NCAPS];
 extern struct static_key_false arm64_const_caps_ready;

 bool this_cpu_has_cap(unsigned int cap);

 static inline bool cpu_have_feature(unsigned int num)
 {
 	return elf_hwcap & (1UL << num);
 }

 /* System capability check for constant caps */
 static inline bool __cpus_have_const_cap(int num)
 {
 	if (num >= ARM64_NCAPS)
 		return false;
 	return static_branch_unlikely(&cpu_hwcap_keys[num]);
 }

 static inline bool cpus_have_cap(unsigned int num)
 {
 	if (num >= ARM64_NCAPS)
 		return false;
 	return test_bit(num, cpu_hwcaps);
 }

 static inline bool cpus_have_const_cap(int num)
 {
 	if (static_branch_likely(&arm64_const_caps_ready))
 		return __cpus_have_const_cap(num);
 	else
 		return cpus_have_cap(num);
 }

 static inline void cpus_set_cap(unsigned int num)
 {
 	if (num >= ARM64_NCAPS) {
 		pr_warn("Attempt to set an illegal CPU capability (%d >= %d)\n",
 			num, ARM64_NCAPS);
 	} else {
 		__set_bit(num, cpu_hwcaps);
 	}
 }

 static inline int __attribute_const__
 cpuid_feature_extract_signed_field_width(u64 features, int field, int width)
 {
 	return (s64)(features << (64 - width - field)) >> (64 - width);
 }

 static inline int __attribute_const__
 cpuid_feature_extract_signed_field(u64 features, int field)
 {
 	return cpuid_feature_extract_signed_field_width(features, field, 4);
 }

 static inline unsigned int __attribute_const__
 cpuid_feature_extract_unsigned_field_width(u64 features, int field, int width)
 {
 	return (u64)(features << (64 - width - field)) >> (64 - width);
 }

 static inline unsigned int __attribute_const__
 cpuid_feature_extract_unsigned_field(u64 features, int field)
 {
 	return cpuid_feature_extract_unsigned_field_width(features, field, 4);
 }

 static inline u64 arm64_ftr_mask(const struct arm64_ftr_bits *ftrp)
 {
 	return (u64)GENMASK(ftrp->shift + ftrp->width - 1, ftrp->shift);
 }

 static inline u64 arm64_ftr_reg_user_value(const struct arm64_ftr_reg *reg)
 {
 	return (reg->user_val | (reg->sys_val & reg->user_mask));
 }

 static inline int __attribute_const__
 cpuid_feature_extract_field_width(u64 features, int field, int width, bool sign)
 {
 	return (sign) ?
 		cpuid_feature_extract_signed_field_width(features, field, width) :
 		cpuid_feature_extract_unsigned_field_width(features, field, width);
 }

 static inline int __attribute_const__
 cpuid_feature_extract_field(u64 features, int field, bool sign)
 {
 	return cpuid_feature_extract_field_width(features, field, 4, sign);
 }

 static inline s64 arm64_ftr_value(const struct arm64_ftr_bits *ftrp, u64 val)
 {
 	return (s64)cpuid_feature_extract_field_width(val, ftrp->shift, ftrp->width, ftrp->sign);
 }

 static inline bool id_aa64mmfr0_mixed_endian_el0(u64 mmfr0)
 {
 	return cpuid_feature_extract_unsigned_field(mmfr0, ID_AA64MMFR0_BIGENDEL_SHIFT) == 0x1 ||
 		cpuid_feature_extract_unsigned_field(mmfr0, ID_AA64MMFR0_BIGENDEL0_SHIFT) == 0x1;
 }

 static inline bool id_aa64pfr0_32bit_el0(u64 pfr0)
 {
 	u32 val = cpuid_feature_extract_unsigned_field(pfr0, ID_AA64PFR0_EL0_SHIFT);

 	return val == ID_AA64PFR0_EL0_32BIT_64BIT;
 }

 static inline bool id_aa64pfr0_sve(u64 pfr0)
 {
 	u32 val = cpuid_feature_extract_unsigned_field(pfr0, ID_AA64PFR0_SVE_SHIFT);

 	return val > 0;
 }

 void __init setup_cpu_features(void);
 void check_local_cpu_capabilities(void);


 u64 read_sanitised_ftr_reg(u32 id);

 static inline bool cpu_supports_mixed_endian_el0(void)
 {
 	return id_aa64mmfr0_mixed_endian_el0(read_cpuid(ID_AA64MMFR0_EL1));
 }

 static inline bool system_supports_32bit_el0(void)
 {
 	return cpus_have_const_cap(ARM64_HAS_32BIT_EL0);
 }

 static inline bool system_supports_mixed_endian_el0(void)
 {
 	return id_aa64mmfr0_mixed_endian_el0(read_sanitised_ftr_reg(SYS_ID_AA64MMFR0_EL1));
 }

 static inline bool system_supports_fpsimd(void)
 {
 	return !cpus_have_const_cap(ARM64_HAS_NO_FPSIMD);
 }

 static inline bool system_uses_ttbr0_pan(void)
 {
 	return IS_ENABLED(CONFIG_ARM64_SW_TTBR0_PAN) &&
 		!cpus_have_const_cap(ARM64_HAS_PAN);
 }

 static inline bool system_supports_sve(void)
 {
 	return IS_ENABLED(CONFIG_ARM64_SVE) &&
 		cpus_have_const_cap(ARM64_SVE);
 }

 #define ARM64_SSBD_UNKNOWN		-1
 #define ARM64_SSBD_FORCE_DISABLE	0
 #define ARM64_SSBD_KERNEL		1
 #define ARM64_SSBD_FORCE_ENABLE		2
 #define ARM64_SSBD_MITIGATED		3

 static inline int arm64_get_ssbd_state(void)
 {
 #ifdef CONFIG_ARM64_SSBD
 	extern int ssbd_state;
 	return ssbd_state;
 #else
 	return ARM64_SSBD_UNKNOWN;
 #endif
 }

 #ifdef CONFIG_ARM64_SSBD
 void arm64_set_ssbd_mitigation(bool state);
 #else
 static inline void arm64_set_ssbd_mitigation(bool state) {}
 #endif

 #endif /* __ASSEMBLY__ */

 #endif
	/*
	* Copyright (C) 2014 Linaro Ltd. <ard.biesheuvel@linaro.org>
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 as
	* published by the Free Software Foundation.
	*/

	#ifndef __ASM_CPUFEATURE_H
	#define __ASM_CPUFEATURE_H

	#include <asm/cpucaps.h>
	#include <asm/cputype.h>
	#include <asm/hwcap.h>
	#include <asm/sysreg.h>

	/*
	* In the arm64 world (as in the ARM world), elf_hwcap is used both internally
	* in the kernel and for user space to keep track of which optional features
	* are supported by the current system. So let's map feature 'x' to HWCAP_x.
	* Note that HWCAP_x constants are bit fields so we need to take the log.
	*/

	#define MAX_CPU_FEATURES (8 * sizeof(elf_hwcap))
	#define cpu_feature(x) ilog2(HWCAP_ ## x)

	#ifndef __ASSEMBLY__

	#include <linux/bug.h>
	#include <linux/jump_label.h>
	#include <linux/kernel.h>

	/*
	* CPU feature register tracking
	*
	* The safe value of a CPUID feature field is dependent on the implications
	* of the values assigned to it by the architecture. Based on the relationship
	* between the values, the features are classified into 3 types - LOWER_SAFE,
	* HIGHER_SAFE and EXACT.
	*
	* The lowest value of all the CPUs is chosen for LOWER_SAFE and highest
	* for HIGHER_SAFE. It is expected that all CPUs have the same value for
	* a field when EXACT is specified, failing which, the safe value specified
	* in the table is chosen.
	*/

	enum ftr_type {
	FTR_EXACT, /* Use a predefined safe value */
	FTR_LOWER_SAFE, /* Smaller value is safe */
	FTR_HIGHER_SAFE,/* Bigger value is safe */
	};

	#define FTR_STRICT true /* SANITY check strict matching required */
	#define FTR_NONSTRICT false /* SANITY check ignored */

	#define FTR_SIGNED true /* Value should be treated as signed */
	#define FTR_UNSIGNED false /* Value should be treated as unsigned */

	#define FTR_VISIBLE true /* Feature visible to the user space */
	#define FTR_HIDDEN false /* Feature is hidden from the user */

	#define FTR_VISIBLE_IF_IS_ENABLED(config) \
	(IS_ENABLED(config) ? FTR_VISIBLE : FTR_HIDDEN)

	struct arm64_ftr_bits {
	bool sign; /* Value is signed ? */
	bool visible;
	bool strict; /* CPU Sanity check: strict matching required ? */
	enum ftr_type type;
	u8 shift;
	u8 width;
	s64 safe_val; /* safe value for FTR_EXACT features */
	};

	/*
	* @arm64_ftr_reg - Feature register
	* @strict_mask Bits which should match across all CPUs for sanity.
	* @sys_val Safe value across the CPUs (system view)
	*/
	struct arm64_ftr_reg {
	const char *name;
	u64 strict_mask;
	u64 user_mask;
	u64 sys_val;
	u64 user_val;
	const struct arm64_ftr_bits *ftr_bits;
	};

	extern struct arm64_ftr_reg arm64_ftr_reg_ctrel0;

	/*
	* CPU capabilities:
	*
	* We use arm64_cpu_capabilities to represent system features, errata work
	* arounds (both used internally by kernel and tracked in cpu_hwcaps) and
	* ELF HWCAPs (which are exposed to user).
	*
	* To support systems with heterogeneous CPUs, we need to make sure that we
	* detect the capabilities correctly on the system and take appropriate
	* measures to ensure there are no incompatibilities.
	*
	* This comment tries to explain how we treat the capabilities.
	* Each capability has the following list of attributes :
	*
	* 1) Scope of Detection : The system detects a given capability by
	* performing some checks at runtime. This could be, e.g, checking the
	* value of a field in CPU ID feature register or checking the cpu
	* model. The capability provides a call back ( @matches() ) to
	* perform the check. Scope defines how the checks should be performed.
	* There are three cases:
	*
	* a) SCOPE_LOCAL_CPU: check all the CPUs and "detect" if at least one
	* matches. This implies, we have to run the check on all the
	* booting CPUs, until the system decides that state of the
	* capability is finalised. (See section 2 below)
	* Or
	* b) SCOPE_SYSTEM: check all the CPUs and "detect" if all the CPUs
	* matches. This implies, we run the check only once, when the
	* system decides to finalise the state of the capability. If the
	* capability relies on a field in one of the CPU ID feature
	* registers, we use the sanitised value of the register from the
	* CPU feature infrastructure to make the decision.
	* Or
	* c) SCOPE_BOOT_CPU: Check only on the primary boot CPU to detect the
	* feature. This category is for features that are "finalised"
	* (or used) by the kernel very early even before the SMP cpus
	* are brought up.
	*
	* The process of detection is usually denoted by "update" capability
	* state in the code.
	*
	* 2) Finalise the state : The kernel should finalise the state of a
	* capability at some point during its execution and take necessary
	* actions if any. Usually, this is done, after all the boot-time
	* enabled CPUs are brought up by the kernel, so that it can make
	* better decision based on the available set of CPUs. However, there
	* are some special cases, where the action is taken during the early
	* boot by the primary boot CPU. (e.g, running the kernel at EL2 with
	* Virtualisation Host Extensions). The kernel usually disallows any
	* changes to the state of a capability once it finalises the capability
	* and takes any action, as it may be impossible to execute the actions
	* safely. A CPU brought up after a capability is "finalised" is
	* referred to as "Late CPU" w.r.t the capability. e.g, all secondary
	* CPUs are treated "late CPUs" for capabilities determined by the boot
	* CPU.
	*
	* At the moment there are two passes of finalising the capabilities.
	* a) Boot CPU scope capabilities - Finalised by primary boot CPU via
	* setup_boot_cpu_capabilities().
	* b) Everything except (a) - Run via setup_system_capabilities().
	*
	* 3) Verification: When a CPU is brought online (e.g, by user or by the
	* kernel), the kernel should make sure that it is safe to use the CPU,
	* by verifying that the CPU is compliant with the state of the
	* capabilities finalised already. This happens via :
	*
	* secondary_start_kernel()-> check_local_cpu_capabilities()
	*
	* As explained in (2) above, capabilities could be finalised at
	* different points in the execution. Each newly booted CPU is verified
	* against the capabilities that have been finalised by the time it
	* boots.
	*
	* a) SCOPE_BOOT_CPU : All CPUs are verified against the capability
	* except for the primary boot CPU.
	*
	* b) SCOPE_LOCAL_CPU, SCOPE_SYSTEM: All CPUs hotplugged on by the
	* user after the kernel boot are verified against the capability.
	*
	* If there is a conflict, the kernel takes an action, based on the
	* severity (e.g, a CPU could be prevented from booting or cause a
	* kernel panic). The CPU is allowed to "affect" the state of the
	* capability, if it has not been finalised already. See section 5
	* for more details on conflicts.
	*
	* 4) Action: As mentioned in (2), the kernel can take an action for each
	* detected capability, on all CPUs on the system. Appropriate actions
	* include, turning on an architectural feature, modifying the control
	* registers (e.g, SCTLR, TCR etc.) or patching the kernel via
	* alternatives. The kernel patching is batched and performed at later
	* point. The actions are always initiated only after the capability
	* is finalised. This is usally denoted by "enabling" the capability.
	* The actions are initiated as follows :
	* a) Action is triggered on all online CPUs, after the capability is
	* finalised, invoked within the stop_machine() context from
	* enable_cpu_capabilitie().
	*
	* b) Any late CPU, brought up after (1), the action is triggered via:
	*
	* check_local_cpu_capabilities() -> verify_local_cpu_capabilities()
	*
	* 5) Conflicts: Based on the state of the capability on a late CPU vs.
	* the system state, we could have the following combinations :
	*
	* x-----------------------------x
	* \| Type \| System \| Late CPU \|
	* \|-----------------------------\|
	* \| a \| y \| n \|
	* \|-----------------------------\|
	* \| b \| n \| y \|
	* x-----------------------------x
	*
	* Two separate flag bits are defined to indicate whether each kind of
	* conflict can be allowed:
	* ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU - Case(a) is allowed
	* ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU - Case(b) is allowed
	*
	* Case (a) is not permitted for a capability that the system requires
	* all CPUs to have in order for the capability to be enabled. This is
	* typical for capabilities that represent enhanced functionality.
	*
	* Case (b) is not permitted for a capability that must be enabled
	* during boot if any CPU in the system requires it in order to run
	* safely. This is typical for erratum work arounds that cannot be
	* enabled after the corresponding capability is finalised.
	*
	* In some non-typical cases either both (a) and (b), or neither,
	* should be permitted. This can be described by including neither
	* or both flags in the capability's type field.
	*/


	/*
	* Decide how the capability is detected.
	* On any local CPU vs System wide vs the primary boot CPU
	*/
	#define ARM64_CPUCAP_SCOPE_LOCAL_CPU ((u16)BIT(0))
	#define ARM64_CPUCAP_SCOPE_SYSTEM ((u16)BIT(1))
	/*
	* The capabilitiy is detected on the Boot CPU and is used by kernel
	* during early boot. i.e, the capability should be "detected" and
	* "enabled" as early as possibly on all booting CPUs.
	*/
	#define ARM64_CPUCAP_SCOPE_BOOT_CPU ((u16)BIT(2))
	#define ARM64_CPUCAP_SCOPE_MASK \
	(ARM64_CPUCAP_SCOPE_SYSTEM \| \
	ARM64_CPUCAP_SCOPE_LOCAL_CPU \| \
	ARM64_CPUCAP_SCOPE_BOOT_CPU)

	#define SCOPE_SYSTEM ARM64_CPUCAP_SCOPE_SYSTEM
	#define SCOPE_LOCAL_CPU ARM64_CPUCAP_SCOPE_LOCAL_CPU
	#define SCOPE_BOOT_CPU ARM64_CPUCAP_SCOPE_BOOT_CPU
	#define SCOPE_ALL ARM64_CPUCAP_SCOPE_MASK

	/*
	* Is it permitted for a late CPU to have this capability when system
	* hasn't already enabled it ?
	*/
	#define ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU ((u16)BIT(4))
	/* Is it safe for a late CPU to miss this capability when system has it */
	#define ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU ((u16)BIT(5))

	/*
	* CPU errata workarounds that need to be enabled at boot time if one or
	* more CPUs in the system requires it. When one of these capabilities
	* has been enabled, it is safe to allow any CPU to boot that doesn't
	* require the workaround. However, it is not safe if a "late" CPU
	* requires a workaround and the system hasn't enabled it already.
	*/
	#define ARM64_CPUCAP_LOCAL_CPU_ERRATUM \
	(ARM64_CPUCAP_SCOPE_LOCAL_CPU \| ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU)
	/*
	* CPU feature detected at boot time based on system-wide value of a
	* feature. It is safe for a late CPU to have this feature even though
	* the system hasn't enabled it, although the featuer will not be used
	* by Linux in this case. If the system has enabled this feature already,
	* then every late CPU must have it.
	*/
	#define ARM64_CPUCAP_SYSTEM_FEATURE \
	(ARM64_CPUCAP_SCOPE_SYSTEM \| ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU)
	/*
	* CPU feature detected at boot time based on feature of one or more CPUs.
	* All possible conflicts for a late CPU are ignored.
	*/
	#define ARM64_CPUCAP_WEAK_LOCAL_CPU_FEATURE \
	(ARM64_CPUCAP_SCOPE_LOCAL_CPU \| \
	ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU \| \
	ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU)

	/*
	* CPU feature detected at boot time, on one or more CPUs. A late CPU
	* is not allowed to have the capability when the system doesn't have it.
	* It is Ok for a late CPU to miss the feature.
	*/
	#define ARM64_CPUCAP_BOOT_RESTRICTED_CPU_LOCAL_FEATURE \
	(ARM64_CPUCAP_SCOPE_LOCAL_CPU \| \
	ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU)

	/*
	* CPU feature used early in the boot based on the boot CPU. All secondary
	* CPUs must match the state of the capability as detected by the boot CPU.
	*/
	#define ARM64_CPUCAP_STRICT_BOOT_CPU_FEATURE ARM64_CPUCAP_SCOPE_BOOT_CPU

	struct arm64_cpu_capabilities {
	const char *desc;
	u16 capability;
	u16 type;
	bool (matches)(const struct arm64_cpu_capabilities caps, int scope);
	/*
	* Take the appropriate actions to enable this capability for this CPU.
	* For each successfully booted CPU, this method is called for each
	* globally detected capability.
	*/
	void (cpu_enable)(const struct arm64_cpu_capabilities cap);
	union {
	struct { /* To be used for erratum handling only */
	struct midr_range midr_range;
	const struct arm64_midr_revidr {
	u32 midr_rv; /* revision/variant */
	u32 revidr_mask;
	} * const fixed_revs;
	};

	const struct midr_range *midr_range_list;
	struct { /* Feature register checking */
	u32 sys_reg;
	u8 field_pos;
	u8 min_field_value;
	u8 hwcap_type;
	bool sign;
	unsigned long hwcap;
	};
	/*
	* A list of "matches/cpu_enable" pair for the same
	* "capability" of the same "type" as described by the parent.
	* Only matches(), cpu_enable() and fields relevant to these
	* methods are significant in the list. The cpu_enable is
	* invoked only if the corresponding entry "matches()".
	* However, if a cpu_enable() method is associated
	* with multiple matches(), care should be taken that either
	* the match criteria are mutually exclusive, or that the
	* method is robust against being called multiple times.
	*/
	const struct arm64_cpu_capabilities *match_list;
	};
	};

	static inline int cpucap_default_scope(const struct arm64_cpu_capabilities *cap)
	{
	return cap->type & ARM64_CPUCAP_SCOPE_MASK;
	}

	static inline bool
	cpucap_late_cpu_optional(const struct arm64_cpu_capabilities *cap)
	{
	return !!(cap->type & ARM64_CPUCAP_OPTIONAL_FOR_LATE_CPU);
	}

	static inline bool
	cpucap_late_cpu_permitted(const struct arm64_cpu_capabilities *cap)
	{
	return !!(cap->type & ARM64_CPUCAP_PERMITTED_FOR_LATE_CPU);
	}

	extern DECLARE_BITMAP(cpu_hwcaps, ARM64_NCAPS);
	extern struct static_key_false cpu_hwcap_keys[ARM64_NCAPS];
	extern struct static_key_false arm64_const_caps_ready;

	bool this_cpu_has_cap(unsigned int cap);

	static inline bool cpu_have_feature(unsigned int num)
	{
	return elf_hwcap & (1UL << num);
	}

	/* System capability check for constant caps */
	static inline bool __cpus_have_const_cap(int num)
	{
	if (num >= ARM64_NCAPS)
	return false;
	return static_branch_unlikely(&cpu_hwcap_keys[num]);
	}

	static inline bool cpus_have_cap(unsigned int num)
	{
	if (num >= ARM64_NCAPS)
	return false;
	return test_bit(num, cpu_hwcaps);
	}

	static inline bool cpus_have_const_cap(int num)
	{
	if (static_branch_likely(&arm64_const_caps_ready))
	return __cpus_have_const_cap(num);
	else
	return cpus_have_cap(num);
	}

	static inline void cpus_set_cap(unsigned int num)
	{
	if (num >= ARM64_NCAPS) {
	pr_warn("Attempt to set an illegal CPU capability (%d >= %d)\n",
	num, ARM64_NCAPS);
	} else {
	__set_bit(num, cpu_hwcaps);
	}
	}

	static inline int __attribute_const__
	cpuid_feature_extract_signed_field_width(u64 features, int field, int width)
	{
	return (s64)(features << (64 - width - field)) >> (64 - width);
	}

	static inline int __attribute_const__
	cpuid_feature_extract_signed_field(u64 features, int field)
	{
	return cpuid_feature_extract_signed_field_width(features, field, 4);
	}

	static inline unsigned int __attribute_const__
	cpuid_feature_extract_unsigned_field_width(u64 features, int field, int width)
	{
	return (u64)(features << (64 - width - field)) >> (64 - width);
	}

	static inline unsigned int __attribute_const__
	cpuid_feature_extract_unsigned_field(u64 features, int field)
	{
	return cpuid_feature_extract_unsigned_field_width(features, field, 4);
	}

	static inline u64 arm64_ftr_mask(const struct arm64_ftr_bits *ftrp)
	{
	return (u64)GENMASK(ftrp->shift + ftrp->width - 1, ftrp->shift);
	}

	static inline u64 arm64_ftr_reg_user_value(const struct arm64_ftr_reg *reg)
	{
	return (reg->user_val \| (reg->sys_val & reg->user_mask));
	}

	static inline int __attribute_const__
	cpuid_feature_extract_field_width(u64 features, int field, int width, bool sign)
	{
	return (sign) ?
	cpuid_feature_extract_signed_field_width(features, field, width) :
	cpuid_feature_extract_unsigned_field_width(features, field, width);
	}

	static inline int __attribute_const__
	cpuid_feature_extract_field(u64 features, int field, bool sign)
	{
	return cpuid_feature_extract_field_width(features, field, 4, sign);
	}

	static inline s64 arm64_ftr_value(const struct arm64_ftr_bits *ftrp, u64 val)
	{
	return (s64)cpuid_feature_extract_field_width(val, ftrp->shift, ftrp->width, ftrp->sign);
	}

	static inline bool id_aa64mmfr0_mixed_endian_el0(u64 mmfr0)
	{
	return cpuid_feature_extract_unsigned_field(mmfr0, ID_AA64MMFR0_BIGENDEL_SHIFT) == 0x1 \|\|
	cpuid_feature_extract_unsigned_field(mmfr0, ID_AA64MMFR0_BIGENDEL0_SHIFT) == 0x1;
	}

	static inline bool id_aa64pfr0_32bit_el0(u64 pfr0)
	{
	u32 val = cpuid_feature_extract_unsigned_field(pfr0, ID_AA64PFR0_EL0_SHIFT);

	return val == ID_AA64PFR0_EL0_32BIT_64BIT;
	}

	static inline bool id_aa64pfr0_sve(u64 pfr0)
	{
	u32 val = cpuid_feature_extract_unsigned_field(pfr0, ID_AA64PFR0_SVE_SHIFT);

	return val > 0;
	}

	void __init setup_cpu_features(void);
	void check_local_cpu_capabilities(void);


	u64 read_sanitised_ftr_reg(u32 id);

	static inline bool cpu_supports_mixed_endian_el0(void)
	{
	return id_aa64mmfr0_mixed_endian_el0(read_cpuid(ID_AA64MMFR0_EL1));
	}

	static inline bool system_supports_32bit_el0(void)
	{
	return cpus_have_const_cap(ARM64_HAS_32BIT_EL0);
	}

	static inline bool system_supports_mixed_endian_el0(void)
	{
	return id_aa64mmfr0_mixed_endian_el0(read_sanitised_ftr_reg(SYS_ID_AA64MMFR0_EL1));
	}

	static inline bool system_supports_fpsimd(void)
	{
	return !cpus_have_const_cap(ARM64_HAS_NO_FPSIMD);
	}

	static inline bool system_uses_ttbr0_pan(void)
	{
	return IS_ENABLED(CONFIG_ARM64_SW_TTBR0_PAN) &&
	!cpus_have_const_cap(ARM64_HAS_PAN);
	}

	static inline bool system_supports_sve(void)
	{
	return IS_ENABLED(CONFIG_ARM64_SVE) &&
	cpus_have_const_cap(ARM64_SVE);
	}

	#define ARM64_SSBD_UNKNOWN -1
	#define ARM64_SSBD_FORCE_DISABLE 0
	#define ARM64_SSBD_KERNEL 1
	#define ARM64_SSBD_FORCE_ENABLE 2
	#define ARM64_SSBD_MITIGATED 3

	static inline int arm64_get_ssbd_state(void)
	{
	#ifdef CONFIG_ARM64_SSBD
	extern int ssbd_state;
	return ssbd_state;
	#else
	return ARM64_SSBD_UNKNOWN;
	#endif
	}

	#ifdef CONFIG_ARM64_SSBD
	void arm64_set_ssbd_mitigation(bool state);
	#else
	static inline void arm64_set_ssbd_mitigation(bool state) {}
	#endif

	#endif /* __ASSEMBLY__ */

	#endif