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/* SPDX-License-Identifier: GPL-2.0 */
#ifndef _ASM_IA64_PAL_H
#define _ASM_IA64_PAL_H

/*
 * Processor Abstraction Layer definitions.
 *
 * This is based on Intel IA-64 Architecture Software Developer's Manual rev 1.0
 * chapter 11 IA-64 Processor Abstraction Layer
 *
 * Copyright (C) 1998-2001 Hewlett-Packard Co
 *	David Mosberger-Tang <davidm@hpl.hp.com>
 *	Stephane Eranian <eranian@hpl.hp.com>
 * Copyright (C) 1999 VA Linux Systems
 * Copyright (C) 1999 Walt Drummond <drummond@valinux.com>
 * Copyright (C) 1999 Srinivasa Prasad Thirumalachar <sprasad@sprasad.engr.sgi.com>
 * Copyright (C) 2008 Silicon Graphics, Inc. (SGI)
 *
 * 99/10/01	davidm	Make sure we pass zero for reserved parameters.
 * 00/03/07	davidm	Updated pal_cache_flush() to be in sync with PAL v2.6.
 * 00/03/23     cfleck  Modified processor min-state save area to match updated PAL & SAL info
 * 00/05/24     eranian Updated to latest PAL spec, fix structures bugs, added
 * 00/05/25	eranian Support for stack calls, and static physical calls
 * 00/06/18	eranian Support for stacked physical calls
 * 06/10/26	rja	Support for Intel Itanium Architecture Software Developer's
 *			Manual Rev 2.2 (Jan 2006)
 */

/*
 * Note that some of these calls use a static-register only calling
 * convention which has nothing to do with the regular calling
 * convention.
 */
#define PAL_CACHE_FLUSH		1	/* flush i/d cache */
#define PAL_CACHE_INFO		2	/* get detailed i/d cache info */
#define PAL_CACHE_INIT		3	/* initialize i/d cache */
#define PAL_CACHE_SUMMARY	4	/* get summary of cache hierarchy */
#define PAL_MEM_ATTRIB		5	/* list supported memory attributes */
#define PAL_PTCE_INFO		6	/* purge TLB info */
#define PAL_VM_INFO		7	/* return supported virtual memory features */
#define PAL_VM_SUMMARY		8	/* return summary on supported vm features */
#define PAL_BUS_GET_FEATURES	9	/* return processor bus interface features settings */
#define PAL_BUS_SET_FEATURES	10	/* set processor bus features */
#define PAL_DEBUG_INFO		11	/* get number of debug registers */
#define PAL_FIXED_ADDR		12	/* get fixed component of processors's directed address */
#define PAL_FREQ_BASE		13	/* base frequency of the platform */
#define PAL_FREQ_RATIOS		14	/* ratio of processor, bus and ITC frequency */
#define PAL_PERF_MON_INFO	15	/* return performance monitor info */
#define PAL_PLATFORM_ADDR	16	/* set processor interrupt block and IO port space addr */
#define PAL_PROC_GET_FEATURES	17	/* get configurable processor features & settings */
#define PAL_PROC_SET_FEATURES	18	/* enable/disable configurable processor features */
#define PAL_RSE_INFO		19	/* return rse information */
#define PAL_VERSION		20	/* return version of PAL code */
#define PAL_MC_CLEAR_LOG	21	/* clear all processor log info */
#define PAL_MC_DRAIN		22	/* drain operations which could result in an MCA */
#define PAL_MC_EXPECTED		23	/* set/reset expected MCA indicator */
#define PAL_MC_DYNAMIC_STATE	24	/* get processor dynamic state */
#define PAL_MC_ERROR_INFO	25	/* get processor MCA info and static state */
#define PAL_MC_RESUME		26	/* Return to interrupted process */
#define PAL_MC_REGISTER_MEM	27	/* Register memory for PAL to use during MCAs and inits */
#define PAL_HALT		28	/* enter the low power HALT state */
#define PAL_HALT_LIGHT		29	/* enter the low power light halt state*/
#define PAL_COPY_INFO		30	/* returns info needed to relocate PAL */
#define PAL_CACHE_LINE_INIT	31	/* init tags & data of cache line */
#define PAL_PMI_ENTRYPOINT	32	/* register PMI memory entry points with the processor */
#define PAL_ENTER_IA_32_ENV	33	/* enter IA-32 system environment */
#define PAL_VM_PAGE_SIZE	34	/* return vm TC and page walker page sizes */

#define PAL_MEM_FOR_TEST	37	/* get amount of memory needed for late processor test */
#define PAL_CACHE_PROT_INFO	38	/* get i/d cache protection info */
#define PAL_REGISTER_INFO	39	/* return AR and CR register information*/
#define PAL_SHUTDOWN		40	/* enter processor shutdown state */
#define PAL_PREFETCH_VISIBILITY	41	/* Make Processor Prefetches Visible */
#define PAL_LOGICAL_TO_PHYSICAL 42	/* returns information on logical to physical processor mapping */
#define PAL_CACHE_SHARED_INFO	43	/* returns information on caches shared by logical processor */
#define PAL_GET_HW_POLICY	48	/* Get current hardware resource sharing policy */
#define PAL_SET_HW_POLICY	49	/* Set current hardware resource sharing policy */
#define PAL_VP_INFO		50	/* Information about virtual processor features */
#define PAL_MC_HW_TRACKING	51	/* Hardware tracking status */

#define PAL_COPY_PAL		256	/* relocate PAL procedures and PAL PMI */
#define PAL_HALT_INFO		257	/* return the low power capabilities of processor */
#define PAL_TEST_PROC		258	/* perform late processor self-test */
#define PAL_CACHE_READ		259	/* read tag & data of cacheline for diagnostic testing */
#define PAL_CACHE_WRITE		260	/* write tag & data of cacheline for diagnostic testing */
#define PAL_VM_TR_READ		261	/* read contents of translation register */
#define PAL_GET_PSTATE		262	/* get the current P-state */
#define PAL_SET_PSTATE		263	/* set the P-state */
#define PAL_BRAND_INFO		274	/* Processor branding information */

#define PAL_GET_PSTATE_TYPE_LASTSET	0
#define PAL_GET_PSTATE_TYPE_AVGANDRESET	1
#define PAL_GET_PSTATE_TYPE_AVGNORESET	2
#define PAL_GET_PSTATE_TYPE_INSTANT	3

#define PAL_MC_ERROR_INJECT	276	/* Injects processor error or returns injection capabilities */

#ifndef __ASSEMBLY__

#include <linux/types.h>
#include <asm/fpu.h>

/*
 * Data types needed to pass information into PAL procedures and
 * interpret information returned by them.
 */

/* Return status from the PAL procedure */
typedef s64				pal_status_t;

#define PAL_STATUS_SUCCESS		0	/* No error */
#define PAL_STATUS_UNIMPLEMENTED	(-1)	/* Unimplemented procedure */
#define PAL_STATUS_EINVAL		(-2)	/* Invalid argument */
#define PAL_STATUS_ERROR		(-3)	/* Error */
#define PAL_STATUS_CACHE_INIT_FAIL	(-4)	/* Could not initialize the
						 * specified level and type of
						 * cache without sideeffects
						 * and "restrict" was 1
						 */
#define PAL_STATUS_REQUIRES_MEMORY	(-9)	/* Call requires PAL memory buffer */

/* Processor cache level in the hierarchy */
typedef u64				pal_cache_level_t;
#define PAL_CACHE_LEVEL_L0		0	/* L0 */
#define PAL_CACHE_LEVEL_L1		1	/* L1 */
#define PAL_CACHE_LEVEL_L2		2	/* L2 */


/* Processor cache type at a particular level in the hierarchy */

typedef u64				pal_cache_type_t;
#define PAL_CACHE_TYPE_INSTRUCTION	1	/* Instruction cache */
#define PAL_CACHE_TYPE_DATA		2	/* Data or unified cache */
#define PAL_CACHE_TYPE_INSTRUCTION_DATA	3	/* Both Data & Instruction */


#define PAL_CACHE_FLUSH_INVALIDATE	1	/* Invalidate clean lines */
#define PAL_CACHE_FLUSH_CHK_INTRS	2	/* check for interrupts/mc while flushing */

/* Processor cache line size in bytes  */
typedef int				pal_cache_line_size_t;

/* Processor cache line state */
typedef u64				pal_cache_line_state_t;
#define PAL_CACHE_LINE_STATE_INVALID	0	/* Invalid */
#define PAL_CACHE_LINE_STATE_SHARED	1	/* Shared */
#define PAL_CACHE_LINE_STATE_EXCLUSIVE	2	/* Exclusive */
#define PAL_CACHE_LINE_STATE_MODIFIED	3	/* Modified */

typedef struct pal_freq_ratio {
	u32 den, num;		/* numerator & denominator */
} itc_ratio, proc_ratio;

typedef	union  pal_cache_config_info_1_s {
	struct {
		u64		u		: 1,	/* 0 Unified cache ? */
				at		: 2,	/* 2-1 Cache mem attr*/
				reserved	: 5,	/* 7-3 Reserved */
				associativity	: 8,	/* 16-8 Associativity*/
				line_size	: 8,	/* 23-17 Line size */
				stride		: 8,	/* 31-24 Stride */
				store_latency	: 8,	/*39-32 Store latency*/
				load_latency	: 8,	/* 47-40 Load latency*/
				store_hints	: 8,	/* 55-48 Store hints*/
				load_hints	: 8;	/* 63-56 Load hints */
	} pcci1_bits;
	u64			pcci1_data;
} pal_cache_config_info_1_t;

typedef	union  pal_cache_config_info_2_s {
	struct {
		u32		cache_size;		/*cache size in bytes*/


		u32		alias_boundary	: 8,	/* 39-32 aliased addr
							 * separation for max
							 * performance.
							 */
				tag_ls_bit	: 8,	/* 47-40 LSb of addr*/
				tag_ms_bit	: 8,	/* 55-48 MSb of addr*/
				reserved	: 8;	/* 63-56 Reserved */
	} pcci2_bits;
	u64			pcci2_data;
} pal_cache_config_info_2_t;


typedef struct pal_cache_config_info_s {
	pal_status_t			pcci_status;
	pal_cache_config_info_1_t	pcci_info_1;
	pal_cache_config_info_2_t	pcci_info_2;
	u64				pcci_reserved;
} pal_cache_config_info_t;

#define pcci_ld_hints		pcci_info_1.pcci1_bits.load_hints
#define pcci_st_hints		pcci_info_1.pcci1_bits.store_hints
#define pcci_ld_latency		pcci_info_1.pcci1_bits.load_latency
#define pcci_st_latency		pcci_info_1.pcci1_bits.store_latency
#define pcci_stride		pcci_info_1.pcci1_bits.stride
#define pcci_line_size		pcci_info_1.pcci1_bits.line_size
#define pcci_assoc		pcci_info_1.pcci1_bits.associativity
#define pcci_cache_attr		pcci_info_1.pcci1_bits.at
#define pcci_unified		pcci_info_1.pcci1_bits.u
#define pcci_tag_msb		pcci_info_2.pcci2_bits.tag_ms_bit
#define pcci_tag_lsb		pcci_info_2.pcci2_bits.tag_ls_bit
#define pcci_alias_boundary	pcci_info_2.pcci2_bits.alias_boundary
#define pcci_cache_size		pcci_info_2.pcci2_bits.cache_size



/* Possible values for cache attributes */

#define PAL_CACHE_ATTR_WT		0	/* Write through cache */
#define PAL_CACHE_ATTR_WB		1	/* Write back cache */
#define PAL_CACHE_ATTR_WT_OR_WB		2	/* Either write thru or write
						 * back depending on TLB
						 * memory attributes
						 */


/* Possible values for cache hints */

#define PAL_CACHE_HINT_TEMP_1		0	/* Temporal level 1 */
#define PAL_CACHE_HINT_NTEMP_1		1	/* Non-temporal level 1 */
#define PAL_CACHE_HINT_NTEMP_ALL	3	/* Non-temporal all levels */

/* Processor cache protection  information */
typedef union pal_cache_protection_element_u {
	u32			pcpi_data;
	struct {
		u32		data_bits	: 8, /* # data bits covered by
						      * each unit of protection
						      */

				tagprot_lsb	: 6, /* Least -do- */
				tagprot_msb	: 6, /* Most Sig. tag address
						      * bit that this
						      * protection covers.
						      */
				prot_bits	: 6, /* # of protection bits */
				method		: 4, /* Protection method */
				t_d		: 2; /* Indicates which part
						      * of the cache this
						      * protection encoding
						      * applies.
						      */
	} pcp_info;
} pal_cache_protection_element_t;

#define pcpi_cache_prot_part	pcp_info.t_d
#define pcpi_prot_method	pcp_info.method
#define pcpi_prot_bits		pcp_info.prot_bits
#define pcpi_tagprot_msb	pcp_info.tagprot_msb
#define pcpi_tagprot_lsb	pcp_info.tagprot_lsb
#define pcpi_data_bits		pcp_info.data_bits

/* Processor cache part encodings */
#define PAL_CACHE_PROT_PART_DATA	0	/* Data protection  */
#define PAL_CACHE_PROT_PART_TAG		1	/* Tag  protection */
#define PAL_CACHE_PROT_PART_TAG_DATA	2	/* Tag+data protection (tag is
						 * more significant )
						 */
#define PAL_CACHE_PROT_PART_DATA_TAG	3	/* Data+tag protection (data is
						 * more significant )
						 */
#define PAL_CACHE_PROT_PART_MAX		6


typedef struct pal_cache_protection_info_s {
	pal_status_t			pcpi_status;
	pal_cache_protection_element_t	pcp_info[PAL_CACHE_PROT_PART_MAX];
} pal_cache_protection_info_t;


/* Processor cache protection method encodings */
#define PAL_CACHE_PROT_METHOD_NONE		0	/* No protection */
#define PAL_CACHE_PROT_METHOD_ODD_PARITY	1	/* Odd parity */
#define PAL_CACHE_PROT_METHOD_EVEN_PARITY	2	/* Even parity */
#define PAL_CACHE_PROT_METHOD_ECC		3	/* ECC protection */


/* Processor cache line identification in the hierarchy */
typedef union pal_cache_line_id_u {
	u64			pclid_data;
	struct {
		u64		cache_type	: 8,	/* 7-0 cache type */
				level		: 8,	/* 15-8 level of the
							 * cache in the
							 * hierarchy.
							 */
				way		: 8,	/* 23-16 way in the set
							 */
				part		: 8,	/* 31-24 part of the
							 * cache
							 */
				reserved	: 32;	/* 63-32 is reserved*/
	} pclid_info_read;
	struct {
		u64		cache_type	: 8,	/* 7-0 cache type */
				level		: 8,	/* 15-8 level of the
							 * cache in the
							 * hierarchy.
							 */
				way		: 8,	/* 23-16 way in the set
							 */
				part		: 8,	/* 31-24 part of the
							 * cache
							 */
				mesi		: 8,	/* 39-32 cache line
							 * state
							 */
				start		: 8,	/* 47-40 lsb of data to
							 * invert
							 */
				length		: 8,	/* 55-48 #bits to
							 * invert
							 */
				trigger		: 8;	/* 63-56 Trigger error
							 * by doing a load
							 * after the write
							 */

	} pclid_info_write;
} pal_cache_line_id_u_t;

#define pclid_read_part		pclid_info_read.part
#define pclid_read_way		pclid_info_read.way
#define pclid_read_level	pclid_info_read.level
#define pclid_read_cache_type	pclid_info_read.cache_type

#define pclid_write_trigger	pclid_info_write.trigger
#define pclid_write_length	pclid_info_write.length
#define pclid_write_start	pclid_info_write.start
#define pclid_write_mesi	pclid_info_write.mesi
#define pclid_write_part	pclid_info_write.part
#define pclid_write_way		pclid_info_write.way
#define pclid_write_level	pclid_info_write.level
#define pclid_write_cache_type	pclid_info_write.cache_type

/* Processor cache line part encodings */
#define PAL_CACHE_LINE_ID_PART_DATA		0	/* Data */
#define PAL_CACHE_LINE_ID_PART_TAG		1	/* Tag */
#define PAL_CACHE_LINE_ID_PART_DATA_PROT	2	/* Data protection */
#define PAL_CACHE_LINE_ID_PART_TAG_PROT		3	/* Tag protection */
#define PAL_CACHE_LINE_ID_PART_DATA_TAG_PROT	4	/* Data+tag
							 * protection
							 */
typedef struct pal_cache_line_info_s {
	pal_status_t		pcli_status;		/* Return status of the read cache line
							 * info call.
							 */
	u64			pcli_data;		/* 64-bit data, tag, protection bits .. */
	u64			pcli_data_len;		/* data length in bits */
	pal_cache_line_state_t	pcli_cache_line_state;	/* mesi state */

} pal_cache_line_info_t;


/* Machine Check related crap */

/* Pending event status bits  */
typedef u64					pal_mc_pending_events_t;

#define PAL_MC_PENDING_MCA			(1 << 0)
#define PAL_MC_PENDING_INIT			(1 << 1)

/* Error information type */
typedef u64					pal_mc_info_index_t;

#define PAL_MC_INFO_PROCESSOR			0	/* Processor */
#define PAL_MC_INFO_CACHE_CHECK			1	/* Cache check */
#define PAL_MC_INFO_TLB_CHECK			2	/* Tlb check */
#define PAL_MC_INFO_BUS_CHECK			3	/* Bus check */
#define PAL_MC_INFO_REQ_ADDR			4	/* Requestor address */
#define PAL_MC_INFO_RESP_ADDR			5	/* Responder address */
#define PAL_MC_INFO_TARGET_ADDR			6	/* Target address */
#define PAL_MC_INFO_IMPL_DEP			7	/* Implementation
							 * dependent
							 */

#define PAL_TLB_CHECK_OP_PURGE			8

typedef struct pal_process_state_info_s {
	u64		reserved1	: 2,
			rz		: 1,	/* PAL_CHECK processor
						 * rendezvous
						 * successful.
						 */

			ra		: 1,	/* PAL_CHECK attempted
						 * a rendezvous.
						 */
			me		: 1,	/* Distinct multiple
						 * errors occurred
						 */

			mn		: 1,	/* Min. state save
						 * area has been
						 * registered with PAL
						 */

			sy		: 1,	/* Storage integrity
						 * synched
						 */


			co		: 1,	/* Continuable */
			ci		: 1,	/* MC isolated */
			us		: 1,	/* Uncontained storage
						 * damage.
						 */


			hd		: 1,	/* Non-essential hw
						 * lost (no loss of
						 * functionality)
						 * causing the
						 * processor to run in
						 * degraded mode.
						 */

			tl		: 1,	/* 1 => MC occurred
						 * after an instr was
						 * executed but before
						 * the trap that
						 * resulted from instr
						 * execution was
						 * generated.
						 * (Trap Lost )
						 */
			mi		: 1,	/* More information available
						 * call PAL_MC_ERROR_INFO
						 */
			pi		: 1,	/* Precise instruction pointer */
			pm		: 1,	/* Precise min-state save area */

			dy		: 1,	/* Processor dynamic
						 * state valid
						 */


			in		: 1,	/* 0 = MC, 1 = INIT */
			rs		: 1,	/* RSE valid */
			cm		: 1,	/* MC corrected */
			ex		: 1,	/* MC is expected */
			cr		: 1,	/* Control regs valid*/
			pc		: 1,	/* Perf cntrs valid */
			dr		: 1,	/* Debug regs valid */
			tr		: 1,	/* Translation regs
						 * valid
						 */
			rr		: 1,	/* Region regs valid */
			ar		: 1,	/* App regs valid */
			br		: 1,	/* Branch regs valid */
			pr		: 1,	/* Predicate registers
						 * valid
						 */

			fp		: 1,	/* fp registers valid*/
			b1		: 1,	/* Preserved bank one
						 * general registers
						 * are valid
						 */
			b0		: 1,	/* Preserved bank zero
						 * general registers
						 * are valid
						 */
			gr		: 1,	/* General registers
						 * are valid
						 * (excl. banked regs)
						 */
			dsize		: 16,	/* size of dynamic
						 * state returned
						 * by the processor
						 */

			se		: 1,	/* Shared error.  MCA in a
						   shared structure */
			reserved2	: 10,
			cc		: 1,	/* Cache check */
			tc		: 1,	/* TLB check */
			bc		: 1,	/* Bus check */
			rc		: 1,	/* Register file check */
			uc		: 1;	/* Uarch check */

} pal_processor_state_info_t;

typedef struct pal_cache_check_info_s {
	u64		op		: 4,	/* Type of cache
						 * operation that
						 * caused the machine
						 * check.
						 */
			level		: 2,	/* Cache level */
			reserved1	: 2,
			dl		: 1,	/* Failure in data part
						 * of cache line
						 */
			tl		: 1,	/* Failure in tag part
						 * of cache line
						 */
			dc		: 1,	/* Failure in dcache */
			ic		: 1,	/* Failure in icache */
			mesi		: 3,	/* Cache line state */
			mv		: 1,	/* mesi valid */
			way		: 5,	/* Way in which the
						 * error occurred
						 */
			wiv		: 1,	/* Way field valid */
			reserved2	: 1,
			dp		: 1,	/* Data poisoned on MBE */
			reserved3	: 6,
			hlth		: 2,	/* Health indicator */

			index		: 20,	/* Cache line index */
			reserved4	: 2,

			is		: 1,	/* instruction set (1 == ia32) */
			iv		: 1,	/* instruction set field valid */
			pl		: 2,	/* privilege level */
			pv		: 1,	/* privilege level field valid */
			mcc		: 1,	/* Machine check corrected */
			tv		: 1,	/* Target address
						 * structure is valid
						 */
			rq		: 1,	/* Requester identifier
						 * structure is valid
						 */
			rp		: 1,	/* Responder identifier
						 * structure is valid
						 */
			pi		: 1;	/* Precise instruction pointer
						 * structure is valid
						 */
} pal_cache_check_info_t;

typedef struct pal_tlb_check_info_s {

	u64		tr_slot		: 8,	/* Slot# of TR where
						 * error occurred
						 */
			trv		: 1,	/* tr_slot field is valid */
			reserved1	: 1,
			level		: 2,	/* TLB level where failure occurred */
			reserved2	: 4,
			dtr		: 1,	/* Fail in data TR */
			itr		: 1,	/* Fail in inst TR */
			dtc		: 1,	/* Fail in data TC */
			itc		: 1,	/* Fail in inst. TC */
			op		: 4,	/* Cache operation */
			reserved3	: 6,
			hlth		: 2,	/* Health indicator */
			reserved4	: 22,

			is		: 1,	/* instruction set (1 == ia32) */
			iv		: 1,	/* instruction set field valid */
			pl		: 2,	/* privilege level */
			pv		: 1,	/* privilege level field valid */
			mcc		: 1,	/* Machine check corrected */
			tv		: 1,	/* Target address
						 * structure is valid
						 */
			rq		: 1,	/* Requester identifier
						 * structure is valid
						 */
			rp		: 1,	/* Responder identifier
						 * structure is valid
						 */
			pi		: 1;	/* Precise instruction pointer
						 * structure is valid
						 */
} pal_tlb_check_info_t;

typedef struct pal_bus_check_info_s {
	u64		size		: 5,	/* Xaction size */
			ib		: 1,	/* Internal bus error */
			eb		: 1,	/* External bus error */
			cc		: 1,	/* Error occurred
						 * during cache-cache
						 * transfer.
						 */
			type		: 8,	/* Bus xaction type*/
			sev		: 5,	/* Bus error severity*/
			hier		: 2,	/* Bus hierarchy level */
			dp		: 1,	/* Data poisoned on MBE */
			bsi		: 8,	/* Bus error status
						 * info
						 */
			reserved2	: 22,

			is		: 1,	/* instruction set (1 == ia32) */
			iv		: 1,	/* instruction set field valid */
			pl		: 2,	/* privilege level */
			pv		: 1,	/* privilege level field valid */
			mcc		: 1,	/* Machine check corrected */
			tv		: 1,	/* Target address
						 * structure is valid
						 */
			rq		: 1,	/* Requester identifier
						 * structure is valid
						 */
			rp		: 1,	/* Responder identifier
						 * structure is valid
						 */
			pi		: 1;	/* Precise instruction pointer
						 * structure is valid
						 */
} pal_bus_check_info_t;

typedef struct pal_reg_file_check_info_s {
	u64		id		: 4,	/* Register file identifier */
			op		: 4,	/* Type of register
						 * operation that
						 * caused the machine
						 * check.
						 */
			reg_num		: 7,	/* Register number */
			rnv		: 1,	/* reg_num valid */
			reserved2	: 38,

			is		: 1,	/* instruction set (1 == ia32) */
			iv		: 1,	/* instruction set field valid */
			pl		: 2,	/* privilege level */
			pv		: 1,	/* privilege level field valid */
			mcc		: 1,	/* Machine check corrected */
			reserved3	: 3,
			pi		: 1;	/* Precise instruction pointer
						 * structure is valid
						 */
} pal_reg_file_check_info_t;

typedef struct pal_uarch_check_info_s {
	u64		sid		: 5,	/* Structure identification */
			level		: 3,	/* Level of failure */
			array_id	: 4,	/* Array identification */
			op		: 4,	/* Type of
						 * operation that
						 * caused the machine
						 * check.
						 */
			way		: 6,	/* Way of structure */
			wv		: 1,	/* way valid */
			xv		: 1,	/* index valid */
			reserved1	: 6,
			hlth		: 2,	/* Health indicator */
			index		: 8,	/* Index or set of the uarch
						 * structure that failed.
						 */
			reserved2	: 24,

			is		: 1,	/* instruction set (1 == ia32) */
			iv		: 1,	/* instruction set field valid */
			pl		: 2,	/* privilege level */
			pv		: 1,	/* privilege level field valid */
			mcc		: 1,	/* Machine check corrected */
			tv		: 1,	/* Target address
						 * structure is valid
						 */
			rq		: 1,	/* Requester identifier
						 * structure is valid
						 */
			rp		: 1,	/* Responder identifier
						 * structure is valid
						 */
			pi		: 1;	/* Precise instruction pointer
						 * structure is valid
						 */
} pal_uarch_check_info_t;

typedef union pal_mc_error_info_u {
	u64				pmei_data;
	pal_processor_state_info_t	pme_processor;
	pal_cache_check_info_t		pme_cache;
	pal_tlb_check_info_t		pme_tlb;
	pal_bus_check_info_t		pme_bus;
	pal_reg_file_check_info_t	pme_reg_file;
	pal_uarch_check_info_t		pme_uarch;
} pal_mc_error_info_t;

#define pmci_proc_unknown_check			pme_processor.uc
#define pmci_proc_bus_check			pme_processor.bc
#define pmci_proc_tlb_check			pme_processor.tc
#define pmci_proc_cache_check			pme_processor.cc
#define pmci_proc_dynamic_state_size		pme_processor.dsize
#define pmci_proc_gpr_valid			pme_processor.gr
#define pmci_proc_preserved_bank0_gpr_valid	pme_processor.b0
#define pmci_proc_preserved_bank1_gpr_valid	pme_processor.b1
#define pmci_proc_fp_valid			pme_processor.fp
#define pmci_proc_predicate_regs_valid		pme_processor.pr
#define pmci_proc_branch_regs_valid		pme_processor.br
#define pmci_proc_app_regs_valid		pme_processor.ar
#define pmci_proc_region_regs_valid		pme_processor.rr
#define pmci_proc_translation_regs_valid	pme_processor.tr
#define pmci_proc_debug_regs_valid		pme_processor.dr
#define pmci_proc_perf_counters_valid		pme_processor.pc
#define pmci_proc_control_regs_valid		pme_processor.cr
#define pmci_proc_machine_check_expected	pme_processor.ex
#define pmci_proc_machine_check_corrected	pme_processor.cm
#define pmci_proc_rse_valid			pme_processor.rs
#define pmci_proc_machine_check_or_init		pme_processor.in
#define pmci_proc_dynamic_state_valid		pme_processor.dy
#define pmci_proc_operation			pme_processor.op
#define pmci_proc_trap_lost			pme_processor.tl
#define pmci_proc_hardware_damage		pme_processor.hd
#define pmci_proc_uncontained_storage_damage	pme_processor.us
#define pmci_proc_machine_check_isolated	pme_processor.ci
#define pmci_proc_continuable			pme_processor.co
#define pmci_proc_storage_intergrity_synced	pme_processor.sy
#define pmci_proc_min_state_save_area_regd	pme_processor.mn
#define	pmci_proc_distinct_multiple_errors	pme_processor.me
#define pmci_proc_pal_attempted_rendezvous	pme_processor.ra
#define pmci_proc_pal_rendezvous_complete	pme_processor.rz


#define pmci_cache_level			pme_cache.level
#define pmci_cache_line_state			pme_cache.mesi
#define pmci_cache_line_state_valid		pme_cache.mv
#define pmci_cache_line_index			pme_cache.index
#define pmci_cache_instr_cache_fail		pme_cache.ic
#define pmci_cache_data_cache_fail		pme_cache.dc
#define pmci_cache_line_tag_fail		pme_cache.tl
#define pmci_cache_line_data_fail		pme_cache.dl
#define pmci_cache_operation			pme_cache.op
#define pmci_cache_way_valid			pme_cache.wv
#define pmci_cache_target_address_valid		pme_cache.tv
#define pmci_cache_way				pme_cache.way
#define pmci_cache_mc				pme_cache.mc

#define pmci_tlb_instr_translation_cache_fail	pme_tlb.itc
#define pmci_tlb_data_translation_cache_fail	pme_tlb.dtc
#define pmci_tlb_instr_translation_reg_fail	pme_tlb.itr
#define pmci_tlb_data_translation_reg_fail	pme_tlb.dtr
#define pmci_tlb_translation_reg_slot		pme_tlb.tr_slot
#define pmci_tlb_mc				pme_tlb.mc

#define pmci_bus_status_info			pme_bus.bsi
#define pmci_bus_req_address_valid		pme_bus.rq
#define pmci_bus_resp_address_valid		pme_bus.rp
#define pmci_bus_target_address_valid		pme_bus.tv
#define pmci_bus_error_severity			pme_bus.sev
#define pmci_bus_transaction_type		pme_bus.type
#define pmci_bus_cache_cache_transfer		pme_bus.cc
#define pmci_bus_transaction_size		pme_bus.size
#define pmci_bus_internal_error			pme_bus.ib
#define pmci_bus_external_error			pme_bus.eb
#define pmci_bus_mc				pme_bus.mc

/*
 * NOTE: this min_state_save area struct only includes the 1KB
 * architectural state save area.  The other 3 KB is scratch space
 * for PAL.
 */

typedef struct pal_min_state_area_s {
	u64	pmsa_nat_bits;		/* nat bits for saved GRs  */
	u64	pmsa_gr[15];		/* GR1	- GR15		   */
	u64	pmsa_bank0_gr[16];	/* GR16 - GR31		   */
	u64	pmsa_bank1_gr[16];	/* GR16 - GR31		   */
	u64	pmsa_pr;		/* predicate registers	   */
	u64	pmsa_br0;		/* branch register 0	   */
	u64	pmsa_rsc;		/* ar.rsc		   */
	u64	pmsa_iip;		/* cr.iip		   */
	u64	pmsa_ipsr;		/* cr.ipsr		   */
	u64	pmsa_ifs;		/* cr.ifs		   */
	u64	pmsa_xip;		/* previous iip		   */
	u64	pmsa_xpsr;		/* previous psr		   */
	u64	pmsa_xfs;		/* previous ifs		   */
	u64	pmsa_br1;		/* branch register 1	   */
	u64	pmsa_reserved[70];	/* pal_min_state_area should total to 1KB */
} pal_min_state_area_t;


struct ia64_pal_retval {
	/*
	 * A zero status value indicates call completed without error.
	 * A negative status value indicates reason of call failure.
	 * A positive status value indicates success but an
	 * informational value should be printed (e.g., "reboot for
	 * change to take effect").
	 */
	s64 status;
	u64 v0;
	u64 v1;
	u64 v2;
};

/*
 * Note: Currently unused PAL arguments are generally labeled
 * "reserved" so the value specified in the PAL documentation
 * (generally 0) MUST be passed.  Reserved parameters are not optional
 * parameters.
 */
extern struct ia64_pal_retval ia64_pal_call_static (u64, u64, u64, u64);
extern struct ia64_pal_retval ia64_pal_call_stacked (u64, u64, u64, u64);
extern struct ia64_pal_retval ia64_pal_call_phys_static (u64, u64, u64, u64);
extern struct ia64_pal_retval ia64_pal_call_phys_stacked (u64, u64, u64, u64);
extern void ia64_save_scratch_fpregs (struct ia64_fpreg *);
extern void ia64_load_scratch_fpregs (struct ia64_fpreg *);

#define PAL_CALL(iprv,a0,a1,a2,a3) do {			\
	struct ia64_fpreg fr[6];			\
	ia64_save_scratch_fpregs(fr);			\
	iprv = ia64_pal_call_static(a0, a1, a2, a3);	\
	ia64_load_scratch_fpregs(fr);			\
} while (0)

#define PAL_CALL_STK(iprv,a0,a1,a2,a3) do {		\
	struct ia64_fpreg fr[6];			\
	ia64_save_scratch_fpregs(fr);			\
	iprv = ia64_pal_call_stacked(a0, a1, a2, a3);	\
	ia64_load_scratch_fpregs(fr);			\
} while (0)

#define PAL_CALL_PHYS(iprv,a0,a1,a2,a3) do {			\
	struct ia64_fpreg fr[6];				\
	ia64_save_scratch_fpregs(fr);				\
	iprv = ia64_pal_call_phys_static(a0, a1, a2, a3);	\
	ia64_load_scratch_fpregs(fr);				\
} while (0)

#define PAL_CALL_PHYS_STK(iprv,a0,a1,a2,a3) do {		\
	struct ia64_fpreg fr[6];				\
	ia64_save_scratch_fpregs(fr);				\
	iprv = ia64_pal_call_phys_stacked(a0, a1, a2, a3);	\
	ia64_load_scratch_fpregs(fr);				\
} while (0)

typedef int (*ia64_pal_handler) (u64, ...);
extern ia64_pal_handler ia64_pal;
extern void ia64_pal_handler_init (void *);

extern ia64_pal_handler ia64_pal;

extern pal_cache_config_info_t		l0d_cache_config_info;
extern pal_cache_config_info_t		l0i_cache_config_info;
extern pal_cache_config_info_t		l1_cache_config_info;
extern pal_cache_config_info_t		l2_cache_config_info;

extern pal_cache_protection_info_t	l0d_cache_protection_info;
extern pal_cache_protection_info_t	l0i_cache_protection_info;
extern pal_cache_protection_info_t	l1_cache_protection_info;
extern pal_cache_protection_info_t	l2_cache_protection_info;

extern pal_cache_config_info_t		pal_cache_config_info_get(pal_cache_level_t,
								  pal_cache_type_t);

extern pal_cache_protection_info_t	pal_cache_protection_info_get(pal_cache_level_t,
								      pal_cache_type_t);


extern void				pal_error(int);


/* Useful wrappers for the current list of pal procedures */

typedef union pal_bus_features_u {
	u64	pal_bus_features_val;
	struct {
		u64	pbf_reserved1				:	29;
		u64	pbf_req_bus_parking			:	1;
		u64	pbf_bus_lock_mask			:	1;
		u64	pbf_enable_half_xfer_rate		:	1;
		u64	pbf_reserved2				:	20;
		u64	pbf_enable_shared_line_replace		:	1;
		u64	pbf_enable_exclusive_line_replace	:	1;
		u64	pbf_disable_xaction_queueing		:	1;
		u64	pbf_disable_resp_err_check		:	1;
		u64	pbf_disable_berr_check			:	1;
		u64	pbf_disable_bus_req_internal_err_signal	:	1;
		u64	pbf_disable_bus_req_berr_signal		:	1;
		u64	pbf_disable_bus_init_event_check	:	1;
		u64	pbf_disable_bus_init_event_signal	:	1;
		u64	pbf_disable_bus_addr_err_check		:	1;
		u64	pbf_disable_bus_addr_err_signal		:	1;
		u64	pbf_disable_bus_data_err_check		:	1;
	} pal_bus_features_s;
} pal_bus_features_u_t;

extern void pal_bus_features_print (u64);

/* Provide information about configurable processor bus features */
static inline s64
ia64_pal_bus_get_features (pal_bus_features_u_t *features_avail,
			   pal_bus_features_u_t *features_status,
			   pal_bus_features_u_t *features_control)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS(iprv, PAL_BUS_GET_FEATURES, 0, 0, 0);
	if (features_avail)
		features_avail->pal_bus_features_val = iprv.v0;
	if (features_status)
		features_status->pal_bus_features_val = iprv.v1;
	if (features_control)
		features_control->pal_bus_features_val = iprv.v2;
	return iprv.status;
}

/* Enables/disables specific processor bus features */
static inline s64
ia64_pal_bus_set_features (pal_bus_features_u_t feature_select)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS(iprv, PAL_BUS_SET_FEATURES, feature_select.pal_bus_features_val, 0, 0);
	return iprv.status;
}

/* Get detailed cache information */
static inline s64
ia64_pal_cache_config_info (u64 cache_level, u64 cache_type, pal_cache_config_info_t *conf)
{
	struct ia64_pal_retval iprv;

	PAL_CALL(iprv, PAL_CACHE_INFO, cache_level, cache_type, 0);

	if (iprv.status == 0) {
		conf->pcci_status                 = iprv.status;
		conf->pcci_info_1.pcci1_data      = iprv.v0;
		conf->pcci_info_2.pcci2_data      = iprv.v1;
		conf->pcci_reserved               = iprv.v2;
	}
	return iprv.status;

}

/* Get detailed cche protection information */
static inline s64
ia64_pal_cache_prot_info (u64 cache_level, u64 cache_type, pal_cache_protection_info_t *prot)
{
	struct ia64_pal_retval iprv;

	PAL_CALL(iprv, PAL_CACHE_PROT_INFO, cache_level, cache_type, 0);

	if (iprv.status == 0) {
		prot->pcpi_status           = iprv.status;
		prot->pcp_info[0].pcpi_data = iprv.v0 & 0xffffffff;
		prot->pcp_info[1].pcpi_data = iprv.v0 >> 32;
		prot->pcp_info[2].pcpi_data = iprv.v1 & 0xffffffff;
		prot->pcp_info[3].pcpi_data = iprv.v1 >> 32;
		prot->pcp_info[4].pcpi_data = iprv.v2 & 0xffffffff;
		prot->pcp_info[5].pcpi_data = iprv.v2 >> 32;
	}
	return iprv.status;
}

/*
 * Flush the processor instruction or data caches.  *PROGRESS must be
 * initialized to zero before calling this for the first time..
 */
static inline s64
ia64_pal_cache_flush (u64 cache_type, u64 invalidate, u64 *progress, u64 *vector)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_CACHE_FLUSH, cache_type, invalidate, *progress);
	if (vector)
		*vector = iprv.v0;
	*progress = iprv.v1;
	return iprv.status;
}


/* Initialize the processor controlled caches */
static inline s64
ia64_pal_cache_init (u64 level, u64 cache_type, u64 rest)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_CACHE_INIT, level, cache_type, rest);
	return iprv.status;
}

/* Initialize the tags and data of a data or unified cache line of
 * processor controlled cache to known values without the availability
 * of backing memory.
 */
static inline s64
ia64_pal_cache_line_init (u64 physical_addr, u64 data_value)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_CACHE_LINE_INIT, physical_addr, data_value, 0);
	return iprv.status;
}


/* Read the data and tag of a processor controlled cache line for diags */
static inline s64
ia64_pal_cache_read (pal_cache_line_id_u_t line_id, u64 physical_addr)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS_STK(iprv, PAL_CACHE_READ, line_id.pclid_data,
				physical_addr, 0);
	return iprv.status;
}

/* Return summary information about the hierarchy of caches controlled by the processor */
static inline long ia64_pal_cache_summary(unsigned long *cache_levels,
						unsigned long *unique_caches)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_CACHE_SUMMARY, 0, 0, 0);
	if (cache_levels)
		*cache_levels = iprv.v0;
	if (unique_caches)
		*unique_caches = iprv.v1;
	return iprv.status;
}

/* Write the data and tag of a processor-controlled cache line for diags */
static inline s64
ia64_pal_cache_write (pal_cache_line_id_u_t line_id, u64 physical_addr, u64 data)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS_STK(iprv, PAL_CACHE_WRITE, line_id.pclid_data,
				physical_addr, data);
	return iprv.status;
}


/* Return the parameters needed to copy relocatable PAL procedures from ROM to memory */
static inline s64
ia64_pal_copy_info (u64 copy_type, u64 num_procs, u64 num_iopics,
		    u64 *buffer_size, u64 *buffer_align)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_COPY_INFO, copy_type, num_procs, num_iopics);
	if (buffer_size)
		*buffer_size = iprv.v0;
	if (buffer_align)
		*buffer_align = iprv.v1;
	return iprv.status;
}

/* Copy relocatable PAL procedures from ROM to memory */
static inline s64
ia64_pal_copy_pal (u64 target_addr, u64 alloc_size, u64 processor, u64 *pal_proc_offset)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_COPY_PAL, target_addr, alloc_size, processor);
	if (pal_proc_offset)
		*pal_proc_offset = iprv.v0;
	return iprv.status;
}

/* Return the number of instruction and data debug register pairs */
static inline long ia64_pal_debug_info(unsigned long *inst_regs,
						unsigned long *data_regs)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_DEBUG_INFO, 0, 0, 0);
	if (inst_regs)
		*inst_regs = iprv.v0;
	if (data_regs)
		*data_regs = iprv.v1;

	return iprv.status;
}

#ifdef TBD
/* Switch from IA64-system environment to IA-32 system environment */
static inline s64
ia64_pal_enter_ia32_env (ia32_env1, ia32_env2, ia32_env3)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_ENTER_IA_32_ENV, ia32_env1, ia32_env2, ia32_env3);
	return iprv.status;
}
#endif

/* Get unique geographical address of this processor on its bus */
static inline s64
ia64_pal_fixed_addr (u64 *global_unique_addr)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_FIXED_ADDR, 0, 0, 0);
	if (global_unique_addr)
		*global_unique_addr = iprv.v0;
	return iprv.status;
}

/* Get base frequency of the platform if generated by the processor */
static inline long ia64_pal_freq_base(unsigned long *platform_base_freq)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_FREQ_BASE, 0, 0, 0);
	if (platform_base_freq)
		*platform_base_freq = iprv.v0;
	return iprv.status;
}

/*
 * Get the ratios for processor frequency, bus frequency and interval timer to
 * to base frequency of the platform
 */
static inline s64
ia64_pal_freq_ratios (struct pal_freq_ratio *proc_ratio, struct pal_freq_ratio *bus_ratio,
		      struct pal_freq_ratio *itc_ratio)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_FREQ_RATIOS, 0, 0, 0);
	if (proc_ratio)
		*(u64 *)proc_ratio = iprv.v0;
	if (bus_ratio)
		*(u64 *)bus_ratio = iprv.v1;
	if (itc_ratio)
		*(u64 *)itc_ratio = iprv.v2;
	return iprv.status;
}

/*
 * Get the current hardware resource sharing policy of the processor
 */
static inline s64
ia64_pal_get_hw_policy (u64 proc_num, u64 *cur_policy, u64 *num_impacted,
			u64 *la)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_GET_HW_POLICY, proc_num, 0, 0);
	if (cur_policy)
		*cur_policy = iprv.v0;
	if (num_impacted)
		*num_impacted = iprv.v1;
	if (la)
		*la = iprv.v2;
	return iprv.status;
}

/* Make the processor enter HALT or one of the implementation dependent low
 * power states where prefetching and execution are suspended and cache and
 * TLB coherency is not maintained.
 */
static inline s64
ia64_pal_halt (u64 halt_state)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_HALT, halt_state, 0, 0);
	return iprv.status;
}

typedef union pal_power_mgmt_info_u {
	u64			ppmi_data;
	struct {
	       u64		exit_latency		: 16,
				entry_latency		: 16,
				power_consumption	: 28,
				im			: 1,
				co			: 1,
				reserved		: 2;
	} pal_power_mgmt_info_s;
} pal_power_mgmt_info_u_t;

/* Return information about processor's optional power management capabilities. */
static inline s64
ia64_pal_halt_info (pal_power_mgmt_info_u_t *power_buf)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_STK(iprv, PAL_HALT_INFO, (unsigned long) power_buf, 0, 0);
	return iprv.status;
}

/* Get the current P-state information */
static inline s64
ia64_pal_get_pstate (u64 *pstate_index, unsigned long type)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_STK(iprv, PAL_GET_PSTATE, type, 0, 0);
	*pstate_index = iprv.v0;
	return iprv.status;
}

/* Set the P-state */
static inline s64
ia64_pal_set_pstate (u64 pstate_index)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_STK(iprv, PAL_SET_PSTATE, pstate_index, 0, 0);
	return iprv.status;
}

/* Processor branding information*/
static inline s64
ia64_pal_get_brand_info (char *brand_info)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_STK(iprv, PAL_BRAND_INFO, 0, (u64)brand_info, 0);
	return iprv.status;
}

/* Cause the processor to enter LIGHT HALT state, where prefetching and execution are
 * suspended, but cache and TLB coherency is maintained.
 */
static inline s64
ia64_pal_halt_light (void)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_HALT_LIGHT, 0, 0, 0);
	return iprv.status;
}

/* Clear all the processor error logging   registers and reset the indicator that allows
 * the error logging registers to be written. This procedure also checks the pending
 * machine check bit and pending INIT bit and reports their states.
 */
static inline s64
ia64_pal_mc_clear_log (u64 *pending_vector)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_CLEAR_LOG, 0, 0, 0);
	if (pending_vector)
		*pending_vector = iprv.v0;
	return iprv.status;
}

/* Ensure that all outstanding transactions in a processor are completed or that any
 * MCA due to thes outstanding transaction is taken.
 */
static inline s64
ia64_pal_mc_drain (void)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_DRAIN, 0, 0, 0);
	return iprv.status;
}

/* Return the machine check dynamic processor state */
static inline s64
ia64_pal_mc_dynamic_state (u64 info_type, u64 dy_buffer, u64 *size)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_DYNAMIC_STATE, info_type, dy_buffer, 0);
	if (size)
		*size = iprv.v0;
	return iprv.status;
}

/* Return processor machine check information */
static inline s64
ia64_pal_mc_error_info (u64 info_index, u64 type_index, u64 *size, u64 *error_info)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_ERROR_INFO, info_index, type_index, 0);
	if (size)
		*size = iprv.v0;
	if (error_info)
		*error_info = iprv.v1;
	return iprv.status;
}

/* Injects the requested processor error or returns info on
 * supported injection capabilities for current processor implementation
 */
static inline s64
ia64_pal_mc_error_inject_phys (u64 err_type_info, u64 err_struct_info,
			u64 err_data_buffer, u64 *capabilities, u64 *resources)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS_STK(iprv, PAL_MC_ERROR_INJECT, err_type_info,
			  err_struct_info, err_data_buffer);
	if (capabilities)
		*capabilities= iprv.v0;
	if (resources)
		*resources= iprv.v1;
	return iprv.status;
}

static inline s64
ia64_pal_mc_error_inject_virt (u64 err_type_info, u64 err_struct_info,
			u64 err_data_buffer, u64 *capabilities, u64 *resources)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_STK(iprv, PAL_MC_ERROR_INJECT, err_type_info,
			  err_struct_info, err_data_buffer);
	if (capabilities)
		*capabilities= iprv.v0;
	if (resources)
		*resources= iprv.v1;
	return iprv.status;
}

/* Inform PALE_CHECK whether a machine check is expected so that PALE_CHECK willnot
 * attempt to correct any expected machine checks.
 */
static inline s64
ia64_pal_mc_expected (u64 expected, u64 *previous)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_EXPECTED, expected, 0, 0);
	if (previous)
		*previous = iprv.v0;
	return iprv.status;
}

typedef union pal_hw_tracking_u {
	u64			pht_data;
	struct {
		u64		itc	:4,	/* Instruction cache tracking */
				dct	:4,	/* Date cache tracking */
				itt	:4,	/* Instruction TLB tracking */
				ddt	:4,	/* Data TLB tracking */
				reserved:48;
	} pal_hw_tracking_s;
} pal_hw_tracking_u_t;

/*
 * Hardware tracking status.
 */
static inline s64
ia64_pal_mc_hw_tracking (u64 *status)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_HW_TRACKING, 0, 0, 0);
	if (status)
		*status = iprv.v0;
	return iprv.status;
}

/* Register a platform dependent location with PAL to which it can save
 * minimal processor state in the event of a machine check or initialization
 * event.
 */
static inline s64
ia64_pal_mc_register_mem (u64 physical_addr, u64 size, u64 *req_size)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_REGISTER_MEM, physical_addr, size, 0);
	if (req_size)
		*req_size = iprv.v0;
	return iprv.status;
}

/* Restore minimal architectural processor state, set CMC interrupt if necessary
 * and resume execution
 */
static inline s64
ia64_pal_mc_resume (u64 set_cmci, u64 save_ptr)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MC_RESUME, set_cmci, save_ptr, 0);
	return iprv.status;
}

/* Return the memory attributes implemented by the processor */
static inline s64
ia64_pal_mem_attrib (u64 *mem_attrib)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MEM_ATTRIB, 0, 0, 0);
	if (mem_attrib)
		*mem_attrib = iprv.v0 & 0xff;
	return iprv.status;
}

/* Return the amount of memory needed for second phase of processor
 * self-test and the required alignment of memory.
 */
static inline s64
ia64_pal_mem_for_test (u64 *bytes_needed, u64 *alignment)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_MEM_FOR_TEST, 0, 0, 0);
	if (bytes_needed)
		*bytes_needed = iprv.v0;
	if (alignment)
		*alignment = iprv.v1;
	return iprv.status;
}

typedef union pal_perf_mon_info_u {
	u64			  ppmi_data;
	struct {
	       u64		generic		: 8,
				width		: 8,
				cycles		: 8,
				retired		: 8,
				reserved	: 32;
	} pal_perf_mon_info_s;
} pal_perf_mon_info_u_t;

/* Return the performance monitor information about what can be counted
 * and how to configure the monitors to count the desired events.
 */
static inline s64
ia64_pal_perf_mon_info (u64 *pm_buffer, pal_perf_mon_info_u_t *pm_info)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_PERF_MON_INFO, (unsigned long) pm_buffer, 0, 0);
	if (pm_info)
		pm_info->ppmi_data = iprv.v0;
	return iprv.status;
}

/* Specifies the physical address of the processor interrupt block
 * and I/O port space.
 */
static inline s64
ia64_pal_platform_addr (u64 type, u64 physical_addr)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_PLATFORM_ADDR, type, physical_addr, 0);
	return iprv.status;
}

/* Set the SAL PMI entrypoint in memory */
static inline s64
ia64_pal_pmi_entrypoint (u64 sal_pmi_entry_addr)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_PMI_ENTRYPOINT, sal_pmi_entry_addr, 0, 0);
	return iprv.status;
}

struct pal_features_s;
/* Provide information about configurable processor features */
static inline s64
ia64_pal_proc_get_features (u64 *features_avail,
			    u64 *features_status,
			    u64 *features_control,
			    u64 features_set)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS(iprv, PAL_PROC_GET_FEATURES, 0, features_set, 0);
	if (iprv.status == 0) {
		*features_avail   = iprv.v0;
		*features_status  = iprv.v1;
		*features_control = iprv.v2;
	}
	return iprv.status;
}

/* Enable/disable processor dependent features */
static inline s64
ia64_pal_proc_set_features (u64 feature_select)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS(iprv, PAL_PROC_SET_FEATURES, feature_select, 0, 0);
	return iprv.status;
}

/*
 * Put everything in a struct so we avoid the global offset table whenever
 * possible.
 */
typedef struct ia64_ptce_info_s {
	unsigned long	base;
	u32		count[2];
	u32		stride[2];
} ia64_ptce_info_t;

/* Return the information required for the architected loop used to purge
 * (initialize) the entire TC
 */
static inline s64
ia64_get_ptce (ia64_ptce_info_t *ptce)
{
	struct ia64_pal_retval iprv;

	if (!ptce)
		return -1;

	PAL_CALL(iprv, PAL_PTCE_INFO, 0, 0, 0);
	if (iprv.status == 0) {
		ptce->base = iprv.v0;
		ptce->count[0] = iprv.v1 >> 32;
		ptce->count[1] = iprv.v1 & 0xffffffff;
		ptce->stride[0] = iprv.v2 >> 32;
		ptce->stride[1] = iprv.v2 & 0xffffffff;
	}
	return iprv.status;
}

/* Return info about implemented application and control registers. */
static inline s64
ia64_pal_register_info (u64 info_request, u64 *reg_info_1, u64 *reg_info_2)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_REGISTER_INFO, info_request, 0, 0);
	if (reg_info_1)
		*reg_info_1 = iprv.v0;
	if (reg_info_2)
		*reg_info_2 = iprv.v1;
	return iprv.status;
}

typedef union pal_hints_u {
	unsigned long		ph_data;
	struct {
	       unsigned long	si		: 1,
				li		: 1,
				reserved	: 62;
	} pal_hints_s;
} pal_hints_u_t;

/* Return information about the register stack and RSE for this processor
 * implementation.
 */
static inline long ia64_pal_rse_info(unsigned long *num_phys_stacked,
							pal_hints_u_t *hints)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_RSE_INFO, 0, 0, 0);
	if (num_phys_stacked)
		*num_phys_stacked = iprv.v0;
	if (hints)
		hints->ph_data = iprv.v1;
	return iprv.status;
}

/*
 * Set the current hardware resource sharing policy of the processor
 */
static inline s64
ia64_pal_set_hw_policy (u64 policy)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_SET_HW_POLICY, policy, 0, 0);
	return iprv.status;
}

/* Cause the processor to enter	SHUTDOWN state, where prefetching and execution are
 * suspended, but cause cache and TLB coherency to be maintained.
 * This is usually called in IA-32 mode.
 */
static inline s64
ia64_pal_shutdown (void)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_SHUTDOWN, 0, 0, 0);
	return iprv.status;
}

/* Perform the second phase of processor self-test. */
static inline s64
ia64_pal_test_proc (u64 test_addr, u64 test_size, u64 attributes, u64 *self_test_state)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_TEST_PROC, test_addr, test_size, attributes);
	if (self_test_state)
		*self_test_state = iprv.v0;
	return iprv.status;
}

typedef union  pal_version_u {
	u64	pal_version_val;
	struct {
		u64	pv_pal_b_rev		:	8;
		u64	pv_pal_b_model		:	8;
		u64	pv_reserved1		:	8;
		u64	pv_pal_vendor		:	8;
		u64	pv_pal_a_rev		:	8;
		u64	pv_pal_a_model		:	8;
		u64	pv_reserved2		:	16;
	} pal_version_s;
} pal_version_u_t;


/*
 * Return PAL version information.  While the documentation states that
 * PAL_VERSION can be called in either physical or virtual mode, some
 * implementations only allow physical calls.  We don't call it very often,
 * so the overhead isn't worth eliminating.
 */
static inline s64
ia64_pal_version (pal_version_u_t *pal_min_version, pal_version_u_t *pal_cur_version)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS(iprv, PAL_VERSION, 0, 0, 0);
	if (pal_min_version)
		pal_min_version->pal_version_val = iprv.v0;

	if (pal_cur_version)
		pal_cur_version->pal_version_val = iprv.v1;

	return iprv.status;
}

typedef union pal_tc_info_u {
	u64			pti_val;
	struct {
	       u64		num_sets	:	8,
				associativity	:	8,
				num_entries	:	16,
				pf		:	1,
				unified		:	1,
				reduce_tr	:	1,
				reserved	:	29;
	} pal_tc_info_s;
} pal_tc_info_u_t;

#define tc_reduce_tr		pal_tc_info_s.reduce_tr
#define tc_unified		pal_tc_info_s.unified
#define tc_pf			pal_tc_info_s.pf
#define tc_num_entries		pal_tc_info_s.num_entries
#define tc_associativity	pal_tc_info_s.associativity
#define tc_num_sets		pal_tc_info_s.num_sets


/* Return information about the virtual memory characteristics of the processor
 * implementation.
 */
static inline s64
ia64_pal_vm_info (u64 tc_level, u64 tc_type,  pal_tc_info_u_t *tc_info, u64 *tc_pages)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_VM_INFO, tc_level, tc_type, 0);
	if (tc_info)
		tc_info->pti_val = iprv.v0;
	if (tc_pages)
		*tc_pages = iprv.v1;
	return iprv.status;
}

/* Get page size information about the virtual memory characteristics of the processor
 * implementation.
 */
static inline s64 ia64_pal_vm_page_size(u64 *tr_pages, u64 *vw_pages)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_VM_PAGE_SIZE, 0, 0, 0);
	if (tr_pages)
		*tr_pages = iprv.v0;
	if (vw_pages)
		*vw_pages = iprv.v1;
	return iprv.status;
}

typedef union pal_vm_info_1_u {
	u64			pvi1_val;
	struct {
		u64		vw		: 1,
				phys_add_size	: 7,
				key_size	: 8,
				max_pkr		: 8,
				hash_tag_id	: 8,
				max_dtr_entry	: 8,
				max_itr_entry	: 8,
				max_unique_tcs	: 8,
				num_tc_levels	: 8;
	} pal_vm_info_1_s;
} pal_vm_info_1_u_t;

#define PAL_MAX_PURGES		0xFFFF		/* all ones is means unlimited */

typedef union pal_vm_info_2_u {
	u64			pvi2_val;
	struct {
		u64		impl_va_msb	: 8,
				rid_size	: 8,
				max_purges	: 16,
				reserved	: 32;
	} pal_vm_info_2_s;
} pal_vm_info_2_u_t;

/* Get summary information about the virtual memory characteristics of the processor
 * implementation.
 */
static inline s64
ia64_pal_vm_summary (pal_vm_info_1_u_t *vm_info_1, pal_vm_info_2_u_t *vm_info_2)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_VM_SUMMARY, 0, 0, 0);
	if (vm_info_1)
		vm_info_1->pvi1_val = iprv.v0;
	if (vm_info_2)
		vm_info_2->pvi2_val = iprv.v1;
	return iprv.status;
}

typedef union pal_vp_info_u {
	u64			pvi_val;
	struct {
		u64		index:		48,	/* virtual feature set info */
				vmm_id:		16;	/* feature set id */
	} pal_vp_info_s;
} pal_vp_info_u_t;

/*
 * Returns information about virtual processor features
 */
static inline s64
ia64_pal_vp_info (u64 feature_set, u64 vp_buffer, u64 *vp_info, u64 *vmm_id)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_VP_INFO, feature_set, vp_buffer, 0);
	if (vp_info)
		*vp_info = iprv.v0;
	if (vmm_id)
		*vmm_id = iprv.v1;
	return iprv.status;
}

typedef union pal_itr_valid_u {
	u64			piv_val;
	struct {
	       u64		access_rights_valid	: 1,
				priv_level_valid	: 1,
				dirty_bit_valid		: 1,
				mem_attr_valid		: 1,
				reserved		: 60;
	} pal_tr_valid_s;
} pal_tr_valid_u_t;

/* Read a translation register */
static inline s64
ia64_pal_tr_read (u64 reg_num, u64 tr_type, u64 *tr_buffer, pal_tr_valid_u_t *tr_valid)
{
	struct ia64_pal_retval iprv;
	PAL_CALL_PHYS_STK(iprv, PAL_VM_TR_READ, reg_num, tr_type,(u64)ia64_tpa(tr_buffer));
	if (tr_valid)
		tr_valid->piv_val = iprv.v0;
	return iprv.status;
}

/*
 * PAL_PREFETCH_VISIBILITY transaction types
 */
#define PAL_VISIBILITY_VIRTUAL		0
#define PAL_VISIBILITY_PHYSICAL		1

/*
 * PAL_PREFETCH_VISIBILITY return codes
 */
#define PAL_VISIBILITY_OK		1
#define PAL_VISIBILITY_OK_REMOTE_NEEDED	0
#define PAL_VISIBILITY_INVAL_ARG	-2
#define PAL_VISIBILITY_ERROR		-3

static inline s64
ia64_pal_prefetch_visibility (s64 trans_type)
{
	struct ia64_pal_retval iprv;
	PAL_CALL(iprv, PAL_PREFETCH_VISIBILITY, trans_type, 0, 0);
	return iprv.status;
}

/* data structure for getting information on logical to physical mappings */
typedef union pal_log_overview_u {
	struct {
		u64	num_log		:16,	/* Total number of logical
						 * processors on this die
						 */
			tpc		:8,	/* Threads per core */
			reserved3	:8,	/* Reserved */
			cpp		:8,	/* Cores per processor */
			reserved2	:8,	/* Reserved */
			ppid		:8,	/* Physical processor ID */
			reserved1	:8;	/* Reserved */
	} overview_bits;
	u64 overview_data;
} pal_log_overview_t;

typedef union pal_proc_n_log_info1_u{
	struct {
		u64	tid		:16,	/* Thread id */
			reserved2	:16,	/* Reserved */
			cid		:16,	/* Core id */
			reserved1	:16;	/* Reserved */
	} ppli1_bits;
	u64	ppli1_data;
} pal_proc_n_log_info1_t;

typedef union pal_proc_n_log_info2_u {
	struct {
		u64	la		:16,	/* Logical address */
			reserved	:48;	/* Reserved */
	} ppli2_bits;
	u64	ppli2_data;
} pal_proc_n_log_info2_t;

typedef struct pal_logical_to_physical_s
{
	pal_log_overview_t overview;
	pal_proc_n_log_info1_t ppli1;
	pal_proc_n_log_info2_t ppli2;
} pal_logical_to_physical_t;

#define overview_num_log	overview.overview_bits.num_log
#define overview_tpc		overview.overview_bits.tpc
#define overview_cpp		overview.overview_bits.cpp
#define overview_ppid		overview.overview_bits.ppid
#define log1_tid		ppli1.ppli1_bits.tid
#define log1_cid		ppli1.ppli1_bits.cid
#define log2_la			ppli2.ppli2_bits.la

/* Get information on logical to physical processor mappings. */
static inline s64
ia64_pal_logical_to_phys(u64 proc_number, pal_logical_to_physical_t *mapping)
{
	struct ia64_pal_retval iprv;

	PAL_CALL(iprv, PAL_LOGICAL_TO_PHYSICAL, proc_number, 0, 0);

	if (iprv.status == PAL_STATUS_SUCCESS)
	{
		mapping->overview.overview_data = iprv.v0;
		mapping->ppli1.ppli1_data = iprv.v1;
		mapping->ppli2.ppli2_data = iprv.v2;
	}

	return iprv.status;
}

typedef struct pal_cache_shared_info_s
{
	u64 num_shared;
	pal_proc_n_log_info1_t ppli1;
	pal_proc_n_log_info2_t ppli2;
} pal_cache_shared_info_t;

/* Get information on logical to physical processor mappings. */
static inline s64
ia64_pal_cache_shared_info(u64 level,
		u64 type,
		u64 proc_number,
		pal_cache_shared_info_t *info)
{
	struct ia64_pal_retval iprv;

	PAL_CALL(iprv, PAL_CACHE_SHARED_INFO, level, type, proc_number);

	if (iprv.status == PAL_STATUS_SUCCESS) {
		info->num_shared = iprv.v0;
		info->ppli1.ppli1_data = iprv.v1;
		info->ppli2.ppli2_data = iprv.v2;
	}

	return iprv.status;
}
#endif /* __ASSEMBLY__ */

#endif /* _ASM_IA64_PAL_H */

Filemanager

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native Folder 0755
sn Folder 0755
uv Folder 0755
Kbuild File 224 B 0644
acenv.h File 1.27 KB 0644
acpi-ext.h File 590 B 0644
acpi.h File 4.1 KB 0644
agp.h File 857 B 0644
asm-offsets.h File 35 B 0644
asm-prototypes.h File 890 B 0644
asmmacro.h File 3.29 KB 0644
atomic.h File 9.47 KB 0644
barrier.h File 2.36 KB 0644
bitops.h File 10.84 KB 0644
bug.h File 404 B 0644
bugs.h File 436 B 0644
cache.h File 771 B 0644
cacheflush.h File 1.71 KB 0644
checksum.h File 2.1 KB 0644
clocksource.h File 276 B 0644
cpu.h File 456 B 0644
cputime.h File 855 B 0644
current.h File 418 B 0644
cyclone.h File 442 B 0644
delay.h File 1.7 KB 0644
device.h File 323 B 0644
div64.h File 31 B 0644
dma-mapping.h File 1.17 KB 0644
dma.h File 466 B 0644
dmi.h File 343 B 0644
early_ioremap.h File 428 B 0644
elf.h File 9.83 KB 0644
emergency-restart.h File 149 B 0644
esi.h File 887 B 0644
exception.h File 1.13 KB 0644
export.h File 115 B 0644
extable.h File 330 B 0644
fb.h File 569 B 0644
fpswa.h File 1.88 KB 0644
ftrace.h File 748 B 0644
futex.h File 2.56 KB 0644
gcc_intrin.h File 368 B 0644
hardirq.h File 564 B 0644
hpsim.h File 364 B 0644
hugetlb.h File 1.67 KB 0644
hw_irq.h File 6.33 KB 0644
idle.h File 200 B 0644
intrinsics.h File 306 B 0644
io.h File 11.77 KB 0644
iommu.h File 555 B 0644
iommu_table.h File 175 B 0644
iosapic.h File 3.16 KB 0644
irq.h File 1.02 KB 0644
irq_regs.h File 34 B 0644
irq_remapping.h File 142 B 0644
irqflags.h File 2.11 KB 0644
kdebug.h File 1.64 KB 0644
kexec.h File 1.57 KB 0644
kmap_types.h File 260 B 0644
kprobes.h File 3.82 KB 0644
kregs.h File 6.73 KB 0644
libata-portmap.h File 225 B 0644
linkage.h File 398 B 0644
local.h File 31 B 0644
local64.h File 33 B 0644
machvec.h File 12.1 KB 0644
machvec_dig.h File 449 B 0644
machvec_dig_vtd.h File 558 B 0644
machvec_hpsim.h File 544 B 0644
machvec_hpzx1.h File 544 B 0644
machvec_hpzx1_swiotlb.h File 632 B 0644
machvec_init.h File 1.33 KB 0644
machvec_sn2.h File 4.71 KB 0644
machvec_uv.h File 684 B 0644
mca.h File 5.91 KB 0644
mca_asm.h File 7.18 KB 0644
meminit.h File 2.24 KB 0644
mman.h File 432 B 0644
mmu.h File 374 B 0644
mmu_context.h File 5.29 KB 0644
mmzone.h File 1.1 KB 0644
module.h File 1.1 KB 0644
msidef.h File 1.4 KB 0644
nodedata.h File 1.85 KB 0644
numa.h File 2.18 KB 0644
page.h File 6.49 KB 0644
pal.h File 53.39 KB 0644
param.h File 439 B 0644
parport.h File 534 B 0644
patch.h File 1.19 KB 0644
pci.h File 2.83 KB 0644
percpu.h File 1.32 KB 0644
perfmon.h File 4.33 KB 0644
pgalloc.h File 2.84 KB 0644
pgtable.h File 20.92 KB 0644
processor.h File 17.98 KB 0644
ptrace.h File 5.2 KB 0644
rwsem.h File 3.82 KB 0644
sal.h File 26.51 KB 0644
sections.h File 1.35 KB 0644
segment.h File 162 B 0644
serial.h File 446 B 0644
shmparam.h File 445 B 0644
signal.h File 749 B 0644
smp.h File 3.21 KB 0644
sparsemem.h File 621 B 0644
spinlock.h File 6.92 KB 0644
spinlock_types.h File 475 B 0644
string.h File 659 B 0644
swiotlb.h File 344 B 0644
switch_to.h File 2.89 KB 0644
syscall.h File 2.06 KB 0644
termios.h File 1.88 KB 0644
thread_info.h File 4.66 KB 0644
timex.h File 1.47 KB 0644
tlb.h File 8.42 KB 0644
tlbflush.h File 2.33 KB 0644
topology.h File 1.58 KB 0644
types.h File 828 B 0644
uaccess.h File 9.86 KB 0644
unaligned.h File 337 B 0644
uncached.h File 463 B 0644
unistd.h File 1.45 KB 0644
unwind.h File 5.74 KB 0644
user.h File 2.25 KB 0644
ustack.h File 403 B 0644
vga.h File 657 B 0644
xor.h File 1.12 KB 0644