arch/x86/include/asm/uv/uv_hub.h - maze/linux - Git at Google

 /*
  * This file is subject to the terms and conditions of the GNU General Public
  * License.  See the file "COPYING" in the main directory of this archive
  * for more details.
  *
  * SGI UV architectural definitions
  *
  * Copyright (C) 2007-2010 Silicon Graphics, Inc. All rights reserved.
  */

 #ifndef _ASM_X86_UV_UV_HUB_H
 #define _ASM_X86_UV_UV_HUB_H

 #ifdef CONFIG_X86_64
 #include <linux/numa.h>
 #include <linux/percpu.h>
 #include <linux/timer.h>
 #include <linux/io.h>
 #include <asm/types.h>
 #include <asm/percpu.h>
 #include <asm/uv/uv_mmrs.h>
 #include <asm/irq_vectors.h>
 #include <asm/io_apic.h>


 /*
  * Addressing Terminology
  *
  *	M       - The low M bits of a physical address represent the offset
  *		  into the blade local memory. RAM memory on a blade is physically
  *		  contiguous (although various IO spaces may punch holes in
  *		  it)..
  *
  *	N	- Number of bits in the node portion of a socket physical
  *		  address.
  *
  *	NASID   - network ID of a router, Mbrick or Cbrick. Nasid values of
  *		  routers always have low bit of 1, C/MBricks have low bit
  *		  equal to 0. Most addressing macros that target UV hub chips
  *		  right shift the NASID by 1 to exclude the always-zero bit.
  *		  NASIDs contain up to 15 bits.
  *
  *	GNODE   - NASID right shifted by 1 bit. Most mmrs contain gnodes instead
  *		  of nasids.
  *
  *	PNODE   - the low N bits of the GNODE. The PNODE is the most useful variant
  *		  of the nasid for socket usage.
  *
  *	GPA	- (global physical address) a socket physical address converted
  *		  so that it can be used by the GRU as a global address. Socket
  *		  physical addresses 1) need additional NASID (node) bits added
  *		  to the high end of the address, and 2) unaliased if the
  *		  partition does not have a physical address 0. In addition, on
  *		  UV2 rev 1, GPAs need the gnode left shifted to bits 39 or 40.
  *
  *
  *  NumaLink Global Physical Address Format:
  *  +--------------------------------+---------------------+
  *  |00..000|      GNODE             |      NodeOffset     |
  *  +--------------------------------+---------------------+
  *          |<-------53 - M bits --->|<--------M bits ----->
  *
  *	M - number of node offset bits (35 .. 40)
  *
  *
  *  Memory/UV-HUB Processor Socket Address Format:
  *  +----------------+---------------+---------------------+
  *  |00..000000000000|   PNODE       |      NodeOffset     |
  *  +----------------+---------------+---------------------+
  *                   <--- N bits --->|<--------M bits ----->
  *
  *	M - number of node offset bits (35 .. 40)
  *	N - number of PNODE bits (0 .. 10)
  *
  *		Note: M + N cannot currently exceed 44 (x86_64) or 46 (IA64).
  *		The actual values are configuration dependent and are set at
  *		boot time. M & N values are set by the hardware/BIOS at boot.
  *
  *
  * APICID format
  *	NOTE!!!!!! This is the current format of the APICID. However, code
  *	should assume that this will change in the future. Use functions
  *	in this file for all APICID bit manipulations and conversion.
  *
  *		1111110000000000
  *		5432109876543210
  *		pppppppppplc0cch	Nehalem-EX (12 bits in hdw reg)
  *		ppppppppplcc0cch	Westmere-EX (12 bits in hdw reg)
  *		pppppppppppcccch	SandyBridge (15 bits in hdw reg)
  *		sssssssssss
  *
  *			p  = pnode bits
  *			l =  socket number on board
  *			c  = core
  *			h  = hyperthread
  *			s  = bits that are in the SOCKET_ID CSR
  *
  *	Note: Processor may support fewer bits in the APICID register. The ACPI
  *	      tables hold all 16 bits. Software needs to be aware of this.
  *
  *	      Unless otherwise specified, all references to APICID refer to
  *	      the FULL value contained in ACPI tables, not the subset in the
  *	      processor APICID register.
  */


 /*
  * Maximum number of bricks in all partitions and in all coherency domains.
  * This is the total number of bricks accessible in the numalink fabric. It
  * includes all C & M bricks. Routers are NOT included.
  *
  * This value is also the value of the maximum number of non-router NASIDs
  * in the numalink fabric.
  *
  * NOTE: a brick may contain 1 or 2 OS nodes. Don't get these confused.
  */
 #define UV_MAX_NUMALINK_BLADES	16384

 /*
  * Maximum number of C/Mbricks within a software SSI (hardware may support
  * more).
  */
 #define UV_MAX_SSI_BLADES	256

 /*
  * The largest possible NASID of a C or M brick (+ 2)
  */
 #define UV_MAX_NASID_VALUE	(UV_MAX_NUMALINK_BLADES * 2)

 struct uv_scir_s {
 	struct timer_list timer;
 	unsigned long	offset;
 	unsigned long	last;
 	unsigned long	idle_on;
 	unsigned long	idle_off;
 	unsigned char	state;
 	unsigned char	enabled;
 };

 /*
  * The following defines attributes of the HUB chip. These attributes are
  * frequently referenced and are kept in the per-cpu data areas of each cpu.
  * They are kept together in a struct to minimize cache misses.
  */
 struct uv_hub_info_s {
 	unsigned long		global_mmr_base;
 	unsigned long		gpa_mask;
 	unsigned int		gnode_extra;
 	unsigned char		hub_revision;
 	unsigned char		apic_pnode_shift;
 	unsigned char		m_shift;
 	unsigned char		n_lshift;
 	unsigned long		gnode_upper;
 	unsigned long		lowmem_remap_top;
 	unsigned long		lowmem_remap_base;
 	unsigned short		pnode;
 	unsigned short		pnode_mask;
 	unsigned short		coherency_domain_number;
 	unsigned short		numa_blade_id;
 	unsigned char		blade_processor_id;
 	unsigned char		m_val;
 	unsigned char		n_val;
 	struct uv_scir_s	scir;
 };

 DECLARE_PER_CPU(struct uv_hub_info_s, __uv_hub_info);
 #define uv_hub_info		(&__get_cpu_var(__uv_hub_info))
 #define uv_cpu_hub_info(cpu)	(&per_cpu(__uv_hub_info, cpu))

 /*
  * Hub revisions less than UV2_HUB_REVISION_BASE are UV1 hubs. All UV2
  * hubs have revision numbers greater than or equal to UV2_HUB_REVISION_BASE.
  * This is a software convention - NOT the hardware revision numbers in
  * the hub chip.
  */
 #define UV1_HUB_REVISION_BASE		1
 #define UV2_HUB_REVISION_BASE		3

 static inline int is_uv1_hub(void)
 {
 	return uv_hub_info->hub_revision < UV2_HUB_REVISION_BASE;
 }

 static inline int is_uv2_hub(void)
 {
 	return uv_hub_info->hub_revision >= UV2_HUB_REVISION_BASE;
 }

 static inline int is_uv2_1_hub(void)
 {
 	return uv_hub_info->hub_revision == UV2_HUB_REVISION_BASE;
 }

 static inline int is_uv2_2_hub(void)
 {
 	return uv_hub_info->hub_revision == UV2_HUB_REVISION_BASE + 1;
 }

 union uvh_apicid {
     unsigned long       v;
     struct uvh_apicid_s {
         unsigned long   local_apic_mask  : 24;
         unsigned long   local_apic_shift :  5;
         unsigned long   unused1          :  3;
         unsigned long   pnode_mask       : 24;
         unsigned long   pnode_shift      :  5;
         unsigned long   unused2          :  3;
     } s;
 };

 /*
  * Local & Global MMR space macros.
  *	Note: macros are intended to be used ONLY by inline functions
  *	in this file - not by other kernel code.
  *		n -  NASID (full 15-bit global nasid)
  *		g -  GNODE (full 15-bit global nasid, right shifted 1)
  *		p -  PNODE (local part of nsids, right shifted 1)
  */
 #define UV_NASID_TO_PNODE(n)		(((n) >> 1) & uv_hub_info->pnode_mask)
 #define UV_PNODE_TO_GNODE(p)		((p) |uv_hub_info->gnode_extra)
 #define UV_PNODE_TO_NASID(p)		(UV_PNODE_TO_GNODE(p) << 1)

 #define UV1_LOCAL_MMR_BASE		0xf4000000UL
 #define UV1_GLOBAL_MMR32_BASE		0xf8000000UL
 #define UV1_LOCAL_MMR_SIZE		(64UL * 1024 * 1024)
 #define UV1_GLOBAL_MMR32_SIZE		(64UL * 1024 * 1024)

 #define UV2_LOCAL_MMR_BASE		0xfa000000UL
 #define UV2_GLOBAL_MMR32_BASE		0xfc000000UL
 #define UV2_LOCAL_MMR_SIZE		(32UL * 1024 * 1024)
 #define UV2_GLOBAL_MMR32_SIZE		(32UL * 1024 * 1024)

 #define UV_LOCAL_MMR_BASE		(is_uv1_hub() ? UV1_LOCAL_MMR_BASE     \
 						: UV2_LOCAL_MMR_BASE)
 #define UV_GLOBAL_MMR32_BASE		(is_uv1_hub() ? UV1_GLOBAL_MMR32_BASE  \
 						: UV2_GLOBAL_MMR32_BASE)
 #define UV_LOCAL_MMR_SIZE		(is_uv1_hub() ? UV1_LOCAL_MMR_SIZE :   \
 						UV2_LOCAL_MMR_SIZE)
 #define UV_GLOBAL_MMR32_SIZE		(is_uv1_hub() ? UV1_GLOBAL_MMR32_SIZE :\
 						UV2_GLOBAL_MMR32_SIZE)
 #define UV_GLOBAL_MMR64_BASE		(uv_hub_info->global_mmr_base)

 #define UV_GLOBAL_GRU_MMR_BASE		0x4000000

 #define UV_GLOBAL_MMR32_PNODE_SHIFT	15
 #define UV_GLOBAL_MMR64_PNODE_SHIFT	26

 #define UV_GLOBAL_MMR32_PNODE_BITS(p)	((p) << (UV_GLOBAL_MMR32_PNODE_SHIFT))

 #define UV_GLOBAL_MMR64_PNODE_BITS(p)					\
 	(((unsigned long)(p)) << UV_GLOBAL_MMR64_PNODE_SHIFT)

 #define UVH_APICID		0x002D0E00L
 #define UV_APIC_PNODE_SHIFT	6

 #define UV_APICID_HIBIT_MASK	0xffff0000

 /* Local Bus from cpu's perspective */
 #define LOCAL_BUS_BASE		0x1c00000
 #define LOCAL_BUS_SIZE		(4 * 1024 * 1024)

 /*
  * System Controller Interface Reg
  *
  * Note there are NO leds on a UV system.  This register is only
  * used by the system controller to monitor system-wide operation.
  * There are 64 regs per node.  With Nahelem cpus (2 cores per node,
  * 8 cpus per core, 2 threads per cpu) there are 32 cpu threads on
  * a node.
  *
  * The window is located at top of ACPI MMR space
  */
 #define SCIR_WINDOW_COUNT	64
 #define SCIR_LOCAL_MMR_BASE	(LOCAL_BUS_BASE + \
 				 LOCAL_BUS_SIZE - \
 				 SCIR_WINDOW_COUNT)

 #define SCIR_CPU_HEARTBEAT	0x01	/* timer interrupt */
 #define SCIR_CPU_ACTIVITY	0x02	/* not idle */
 #define SCIR_CPU_HB_INTERVAL	(HZ)	/* once per second */

 /* Loop through all installed blades */
 #define for_each_possible_blade(bid)		\
 	for ((bid) = 0; (bid) < uv_num_possible_blades(); (bid)++)

 /*
  * Macros for converting between kernel virtual addresses, socket local physical
  * addresses, and UV global physical addresses.
  *	Note: use the standard __pa() & __va() macros for converting
  *	      between socket virtual and socket physical addresses.
  */

 /* socket phys RAM --> UV global physical address */
 static inline unsigned long uv_soc_phys_ram_to_gpa(unsigned long paddr)
 {
 	if (paddr < uv_hub_info->lowmem_remap_top)
 		paddr |= uv_hub_info->lowmem_remap_base;
 	paddr |= uv_hub_info->gnode_upper;
 	paddr = ((paddr << uv_hub_info->m_shift) >> uv_hub_info->m_shift) |
 		((paddr >> uv_hub_info->m_val) << uv_hub_info->n_lshift);
 	return paddr;
 }


 /* socket virtual --> UV global physical address */
 static inline unsigned long uv_gpa(void *v)
 {
 	return uv_soc_phys_ram_to_gpa(__pa(v));
 }

 /* Top two bits indicate the requested address is in MMR space.  */
 static inline int
 uv_gpa_in_mmr_space(unsigned long gpa)
 {
 	return (gpa >> 62) == 0x3UL;
 }

 /* UV global physical address --> socket phys RAM */
 static inline unsigned long uv_gpa_to_soc_phys_ram(unsigned long gpa)
 {
 	unsigned long paddr;
 	unsigned long remap_base = uv_hub_info->lowmem_remap_base;
 	unsigned long remap_top =  uv_hub_info->lowmem_remap_top;

 	gpa = ((gpa << uv_hub_info->m_shift) >> uv_hub_info->m_shift) |
 		((gpa >> uv_hub_info->n_lshift) << uv_hub_info->m_val);
 	paddr = gpa & uv_hub_info->gpa_mask;
 	if (paddr >= remap_base && paddr < remap_base + remap_top)
 		paddr -= remap_base;
 	return paddr;
 }


 /* gpa -> pnode */
 static inline unsigned long uv_gpa_to_gnode(unsigned long gpa)
 {
 	return gpa >> uv_hub_info->n_lshift;
 }

 /* gpa -> pnode */
 static inline int uv_gpa_to_pnode(unsigned long gpa)
 {
 	unsigned long n_mask = (1UL << uv_hub_info->n_val) - 1;

 	return uv_gpa_to_gnode(gpa) & n_mask;
 }

 /* gpa -> node offset*/
 static inline unsigned long uv_gpa_to_offset(unsigned long gpa)
 {
 	return (gpa << uv_hub_info->m_shift) >> uv_hub_info->m_shift;
 }

 /* pnode, offset --> socket virtual */
 static inline void *uv_pnode_offset_to_vaddr(int pnode, unsigned long offset)
 {
 	return __va(((unsigned long)pnode << uv_hub_info->m_val) | offset);
 }


 /*
  * Extract a PNODE from an APICID (full apicid, not processor subset)
  */
 static inline int uv_apicid_to_pnode(int apicid)
 {
 	return (apicid >> uv_hub_info->apic_pnode_shift);
 }

 /*
  * Convert an apicid to the socket number on the blade
  */
 static inline int uv_apicid_to_socket(int apicid)
 {
 	if (is_uv1_hub())
 		return (apicid >> (uv_hub_info->apic_pnode_shift - 1)) & 1;
 	else
 		return 0;
 }

 /*
  * Access global MMRs using the low memory MMR32 space. This region supports
  * faster MMR access but not all MMRs are accessible in this space.
  */
 static inline unsigned long *uv_global_mmr32_address(int pnode, unsigned long offset)
 {
 	return __va(UV_GLOBAL_MMR32_BASE |
 		       UV_GLOBAL_MMR32_PNODE_BITS(pnode) | offset);
 }

 static inline void uv_write_global_mmr32(int pnode, unsigned long offset, unsigned long val)
 {
 	writeq(val, uv_global_mmr32_address(pnode, offset));
 }

 static inline unsigned long uv_read_global_mmr32(int pnode, unsigned long offset)
 {
 	return readq(uv_global_mmr32_address(pnode, offset));
 }

 /*
  * Access Global MMR space using the MMR space located at the top of physical
  * memory.
  */
 static inline volatile void __iomem *uv_global_mmr64_address(int pnode, unsigned long offset)
 {
 	return __va(UV_GLOBAL_MMR64_BASE |
 		    UV_GLOBAL_MMR64_PNODE_BITS(pnode) | offset);
 }

 static inline void uv_write_global_mmr64(int pnode, unsigned long offset, unsigned long val)
 {
 	writeq(val, uv_global_mmr64_address(pnode, offset));
 }

 static inline unsigned long uv_read_global_mmr64(int pnode, unsigned long offset)
 {
 	return readq(uv_global_mmr64_address(pnode, offset));
 }

 /*
  * Global MMR space addresses when referenced by the GRU. (GRU does
  * NOT use socket addressing).
  */
 static inline unsigned long uv_global_gru_mmr_address(int pnode, unsigned long offset)
 {
 	return UV_GLOBAL_GRU_MMR_BASE | offset |
 		((unsigned long)pnode << uv_hub_info->m_val);
 }

 static inline void uv_write_global_mmr8(int pnode, unsigned long offset, unsigned char val)
 {
 	writeb(val, uv_global_mmr64_address(pnode, offset));
 }

 static inline unsigned char uv_read_global_mmr8(int pnode, unsigned long offset)
 {
 	return readb(uv_global_mmr64_address(pnode, offset));
 }

 /*
  * Access hub local MMRs. Faster than using global space but only local MMRs
  * are accessible.
  */
 static inline unsigned long *uv_local_mmr_address(unsigned long offset)
 {
 	return __va(UV_LOCAL_MMR_BASE | offset);
 }

 static inline unsigned long uv_read_local_mmr(unsigned long offset)
 {
 	return readq(uv_local_mmr_address(offset));
 }

 static inline void uv_write_local_mmr(unsigned long offset, unsigned long val)
 {
 	writeq(val, uv_local_mmr_address(offset));
 }

 static inline unsigned char uv_read_local_mmr8(unsigned long offset)
 {
 	return readb(uv_local_mmr_address(offset));
 }

 static inline void uv_write_local_mmr8(unsigned long offset, unsigned char val)
 {
 	writeb(val, uv_local_mmr_address(offset));
 }

 /*
  * Structures and definitions for converting between cpu, node, pnode, and blade
  * numbers.
  */
 struct uv_blade_info {
 	unsigned short	nr_possible_cpus;
 	unsigned short	nr_online_cpus;
 	unsigned short	pnode;
 	short		memory_nid;
 	spinlock_t	nmi_lock;
 	unsigned long	nmi_count;
 };
 extern struct uv_blade_info *uv_blade_info;
 extern short *uv_node_to_blade;
 extern short *uv_cpu_to_blade;
 extern short uv_possible_blades;

 /* Blade-local cpu number of current cpu. Numbered 0 .. <# cpus on the blade> */
 static inline int uv_blade_processor_id(void)
 {
 	return uv_hub_info->blade_processor_id;
 }

 /* Blade number of current cpu. Numnbered 0 .. <#blades -1> */
 static inline int uv_numa_blade_id(void)
 {
 	return uv_hub_info->numa_blade_id;
 }

 /* Convert a cpu number to the the UV blade number */
 static inline int uv_cpu_to_blade_id(int cpu)
 {
 	return uv_cpu_to_blade[cpu];
 }

 /* Convert linux node number to the UV blade number */
 static inline int uv_node_to_blade_id(int nid)
 {
 	return uv_node_to_blade[nid];
 }

 /* Convert a blade id to the PNODE of the blade */
 static inline int uv_blade_to_pnode(int bid)
 {
 	return uv_blade_info[bid].pnode;
 }

 /* Nid of memory node on blade. -1 if no blade-local memory */
 static inline int uv_blade_to_memory_nid(int bid)
 {
 	return uv_blade_info[bid].memory_nid;
 }

 /* Determine the number of possible cpus on a blade */
 static inline int uv_blade_nr_possible_cpus(int bid)
 {
 	return uv_blade_info[bid].nr_possible_cpus;
 }

 /* Determine the number of online cpus on a blade */
 static inline int uv_blade_nr_online_cpus(int bid)
 {
 	return uv_blade_info[bid].nr_online_cpus;
 }

 /* Convert a cpu id to the PNODE of the blade containing the cpu */
 static inline int uv_cpu_to_pnode(int cpu)
 {
 	return uv_blade_info[uv_cpu_to_blade_id(cpu)].pnode;
 }

 /* Convert a linux node number to the PNODE of the blade */
 static inline int uv_node_to_pnode(int nid)
 {
 	return uv_blade_info[uv_node_to_blade_id(nid)].pnode;
 }

 /* Maximum possible number of blades */
 static inline int uv_num_possible_blades(void)
 {
 	return uv_possible_blades;
 }

 /* Update SCIR state */
 static inline void uv_set_scir_bits(unsigned char value)
 {
 	if (uv_hub_info->scir.state != value) {
 		uv_hub_info->scir.state = value;
 		uv_write_local_mmr8(uv_hub_info->scir.offset, value);
 	}
 }

 static inline unsigned long uv_scir_offset(int apicid)
 {
 	return SCIR_LOCAL_MMR_BASE | (apicid & 0x3f);
 }

 static inline void uv_set_cpu_scir_bits(int cpu, unsigned char value)
 {
 	if (uv_cpu_hub_info(cpu)->scir.state != value) {
 		uv_write_global_mmr8(uv_cpu_to_pnode(cpu),
 				uv_cpu_hub_info(cpu)->scir.offset, value);
 		uv_cpu_hub_info(cpu)->scir.state = value;
 	}
 }

 extern unsigned int uv_apicid_hibits;
 static unsigned long uv_hub_ipi_value(int apicid, int vector, int mode)
 {
 	apicid |= uv_apicid_hibits;
 	return (1UL << UVH_IPI_INT_SEND_SHFT) |
 			((apicid) << UVH_IPI_INT_APIC_ID_SHFT) |
 			(mode << UVH_IPI_INT_DELIVERY_MODE_SHFT) |
 			(vector << UVH_IPI_INT_VECTOR_SHFT);
 }

 static inline void uv_hub_send_ipi(int pnode, int apicid, int vector)
 {
 	unsigned long val;
 	unsigned long dmode = dest_Fixed;

 	if (vector == NMI_VECTOR)
 		dmode = dest_NMI;

 	val = uv_hub_ipi_value(apicid, vector, dmode);
 	uv_write_global_mmr64(pnode, UVH_IPI_INT, val);
 }

 /*
  * Get the minimum revision number of the hub chips within the partition.
  *     1 - UV1 rev 1.0 initial silicon
  *     2 - UV1 rev 2.0 production silicon
  *     3 - UV2 rev 1.0 initial silicon
  */
 static inline int uv_get_min_hub_revision_id(void)
 {
 	return uv_hub_info->hub_revision;
 }

 #endif /* CONFIG_X86_64 */
 #endif /* _ASM_X86_UV_UV_HUB_H */
	/*
	* This file is subject to the terms and conditions of the GNU General Public
	* License. See the file "COPYING" in the main directory of this archive
	* for more details.
	*
	* SGI UV architectural definitions
	*
	* Copyright (C) 2007-2010 Silicon Graphics, Inc. All rights reserved.
	*/

	#ifndef _ASM_X86_UV_UV_HUB_H
	#define _ASM_X86_UV_UV_HUB_H

	#ifdef CONFIG_X86_64
	#include <linux/numa.h>
	#include <linux/percpu.h>
	#include <linux/timer.h>
	#include <linux/io.h>
	#include <asm/types.h>
	#include <asm/percpu.h>
	#include <asm/uv/uv_mmrs.h>
	#include <asm/irq_vectors.h>
	#include <asm/io_apic.h>


	/*
	* Addressing Terminology
	*
	* M - The low M bits of a physical address represent the offset
	* into the blade local memory. RAM memory on a blade is physically
	* contiguous (although various IO spaces may punch holes in
	* it)..
	*
	* N - Number of bits in the node portion of a socket physical
	* address.
	*
	* NASID - network ID of a router, Mbrick or Cbrick. Nasid values of
	* routers always have low bit of 1, C/MBricks have low bit
	* equal to 0. Most addressing macros that target UV hub chips
	* right shift the NASID by 1 to exclude the always-zero bit.
	* NASIDs contain up to 15 bits.
	*
	* GNODE - NASID right shifted by 1 bit. Most mmrs contain gnodes instead
	* of nasids.
	*
	* PNODE - the low N bits of the GNODE. The PNODE is the most useful variant
	* of the nasid for socket usage.
	*
	* GPA - (global physical address) a socket physical address converted
	* so that it can be used by the GRU as a global address. Socket
	* physical addresses 1) need additional NASID (node) bits added
	* to the high end of the address, and 2) unaliased if the
	* partition does not have a physical address 0. In addition, on
	* UV2 rev 1, GPAs need the gnode left shifted to bits 39 or 40.
	*
	*
	* NumaLink Global Physical Address Format:
	* +--------------------------------+---------------------+
	* \|00..000\| GNODE \| NodeOffset \|
	* +--------------------------------+---------------------+
	* \|<-------53 - M bits --->\|<--------M bits ----->
	*
	* M - number of node offset bits (35 .. 40)
	*
	*
	* Memory/UV-HUB Processor Socket Address Format:
	* +----------------+---------------+---------------------+
	* \|00..000000000000\| PNODE \| NodeOffset \|
	* +----------------+---------------+---------------------+
	* <--- N bits --->\|<--------M bits ----->
	*
	* M - number of node offset bits (35 .. 40)
	* N - number of PNODE bits (0 .. 10)
	*
	* Note: M + N cannot currently exceed 44 (x86_64) or 46 (IA64).
	* The actual values are configuration dependent and are set at
	* boot time. M & N values are set by the hardware/BIOS at boot.
	*
	*
	* APICID format
	* NOTE!!!!!! This is the current format of the APICID. However, code
	* should assume that this will change in the future. Use functions
	* in this file for all APICID bit manipulations and conversion.
	*
	* 1111110000000000
	* 5432109876543210
	* pppppppppplc0cch Nehalem-EX (12 bits in hdw reg)
	* ppppppppplcc0cch Westmere-EX (12 bits in hdw reg)
	* pppppppppppcccch SandyBridge (15 bits in hdw reg)
	* sssssssssss
	*
	* p = pnode bits
	* l = socket number on board
	* c = core
	* h = hyperthread
	* s = bits that are in the SOCKET_ID CSR
	*
	* Note: Processor may support fewer bits in the APICID register. The ACPI
	* tables hold all 16 bits. Software needs to be aware of this.
	*
	* Unless otherwise specified, all references to APICID refer to
	* the FULL value contained in ACPI tables, not the subset in the
	* processor APICID register.
	*/


	/*
	* Maximum number of bricks in all partitions and in all coherency domains.
	* This is the total number of bricks accessible in the numalink fabric. It
	* includes all C & M bricks. Routers are NOT included.
	*
	* This value is also the value of the maximum number of non-router NASIDs
	* in the numalink fabric.
	*
	* NOTE: a brick may contain 1 or 2 OS nodes. Don't get these confused.
	*/
	#define UV_MAX_NUMALINK_BLADES 16384

	/*
	* Maximum number of C/Mbricks within a software SSI (hardware may support
	* more).
	*/
	#define UV_MAX_SSI_BLADES 256

	/*
	* The largest possible NASID of a C or M brick (+ 2)
	*/
	#define UV_MAX_NASID_VALUE (UV_MAX_NUMALINK_BLADES * 2)

	struct uv_scir_s {
	struct timer_list timer;
	unsigned long offset;
	unsigned long last;
	unsigned long idle_on;
	unsigned long idle_off;
	unsigned char state;
	unsigned char enabled;
	};

	/*
	* The following defines attributes of the HUB chip. These attributes are
	* frequently referenced and are kept in the per-cpu data areas of each cpu.
	* They are kept together in a struct to minimize cache misses.
	*/
	struct uv_hub_info_s {
	unsigned long global_mmr_base;
	unsigned long gpa_mask;
	unsigned int gnode_extra;
	unsigned char hub_revision;
	unsigned char apic_pnode_shift;
	unsigned char m_shift;
	unsigned char n_lshift;
	unsigned long gnode_upper;
	unsigned long lowmem_remap_top;
	unsigned long lowmem_remap_base;
	unsigned short pnode;
	unsigned short pnode_mask;
	unsigned short coherency_domain_number;
	unsigned short numa_blade_id;
	unsigned char blade_processor_id;
	unsigned char m_val;
	unsigned char n_val;
	struct uv_scir_s scir;
	};

	DECLARE_PER_CPU(struct uv_hub_info_s, __uv_hub_info);
	#define uv_hub_info (&__get_cpu_var(__uv_hub_info))
	#define uv_cpu_hub_info(cpu) (&per_cpu(__uv_hub_info, cpu))

	/*
	* Hub revisions less than UV2_HUB_REVISION_BASE are UV1 hubs. All UV2
	* hubs have revision numbers greater than or equal to UV2_HUB_REVISION_BASE.
	* This is a software convention - NOT the hardware revision numbers in
	* the hub chip.
	*/
	#define UV1_HUB_REVISION_BASE 1
	#define UV2_HUB_REVISION_BASE 3

	static inline int is_uv1_hub(void)
	{
	return uv_hub_info->hub_revision < UV2_HUB_REVISION_BASE;
	}

	static inline int is_uv2_hub(void)
	{
	return uv_hub_info->hub_revision >= UV2_HUB_REVISION_BASE;
	}

	static inline int is_uv2_1_hub(void)
	{
	return uv_hub_info->hub_revision == UV2_HUB_REVISION_BASE;
	}

	static inline int is_uv2_2_hub(void)
	{
	return uv_hub_info->hub_revision == UV2_HUB_REVISION_BASE + 1;
	}

	union uvh_apicid {
	unsigned long v;
	struct uvh_apicid_s {
	unsigned long local_apic_mask : 24;
	unsigned long local_apic_shift : 5;
	unsigned long unused1 : 3;
	unsigned long pnode_mask : 24;
	unsigned long pnode_shift : 5;
	unsigned long unused2 : 3;
	} s;
	};

	/*
	* Local & Global MMR space macros.
	* Note: macros are intended to be used ONLY by inline functions
	* in this file - not by other kernel code.
	* n - NASID (full 15-bit global nasid)
	* g - GNODE (full 15-bit global nasid, right shifted 1)
	* p - PNODE (local part of nsids, right shifted 1)
	*/
	#define UV_NASID_TO_PNODE(n) (((n) >> 1) & uv_hub_info->pnode_mask)
	#define UV_PNODE_TO_GNODE(p) ((p) \|uv_hub_info->gnode_extra)
	#define UV_PNODE_TO_NASID(p) (UV_PNODE_TO_GNODE(p) << 1)

	#define UV1_LOCAL_MMR_BASE 0xf4000000UL
	#define UV1_GLOBAL_MMR32_BASE 0xf8000000UL
	#define UV1_LOCAL_MMR_SIZE (64UL * 1024 * 1024)
	#define UV1_GLOBAL_MMR32_SIZE (64UL * 1024 * 1024)

	#define UV2_LOCAL_MMR_BASE 0xfa000000UL
	#define UV2_GLOBAL_MMR32_BASE 0xfc000000UL
	#define UV2_LOCAL_MMR_SIZE (32UL * 1024 * 1024)
	#define UV2_GLOBAL_MMR32_SIZE (32UL * 1024 * 1024)

	#define UV_LOCAL_MMR_BASE (is_uv1_hub() ? UV1_LOCAL_MMR_BASE \
	: UV2_LOCAL_MMR_BASE)
	#define UV_GLOBAL_MMR32_BASE (is_uv1_hub() ? UV1_GLOBAL_MMR32_BASE \
	: UV2_GLOBAL_MMR32_BASE)
	#define UV_LOCAL_MMR_SIZE (is_uv1_hub() ? UV1_LOCAL_MMR_SIZE : \
	UV2_LOCAL_MMR_SIZE)
	#define UV_GLOBAL_MMR32_SIZE (is_uv1_hub() ? UV1_GLOBAL_MMR32_SIZE :\
	UV2_GLOBAL_MMR32_SIZE)
	#define UV_GLOBAL_MMR64_BASE (uv_hub_info->global_mmr_base)

	#define UV_GLOBAL_GRU_MMR_BASE 0x4000000

	#define UV_GLOBAL_MMR32_PNODE_SHIFT 15
	#define UV_GLOBAL_MMR64_PNODE_SHIFT 26

	#define UV_GLOBAL_MMR32_PNODE_BITS(p) ((p) << (UV_GLOBAL_MMR32_PNODE_SHIFT))

	#define UV_GLOBAL_MMR64_PNODE_BITS(p) \
	(((unsigned long)(p)) << UV_GLOBAL_MMR64_PNODE_SHIFT)

	#define UVH_APICID 0x002D0E00L
	#define UV_APIC_PNODE_SHIFT 6

	#define UV_APICID_HIBIT_MASK 0xffff0000

	/* Local Bus from cpu's perspective */
	#define LOCAL_BUS_BASE 0x1c00000
	#define LOCAL_BUS_SIZE (4 * 1024 * 1024)

	/*
	* System Controller Interface Reg
	*
	* Note there are NO leds on a UV system. This register is only
	* used by the system controller to monitor system-wide operation.
	* There are 64 regs per node. With Nahelem cpus (2 cores per node,
	* 8 cpus per core, 2 threads per cpu) there are 32 cpu threads on
	* a node.
	*
	* The window is located at top of ACPI MMR space
	*/
	#define SCIR_WINDOW_COUNT 64
	#define SCIR_LOCAL_MMR_BASE (LOCAL_BUS_BASE + \
	LOCAL_BUS_SIZE - \
	SCIR_WINDOW_COUNT)

	#define SCIR_CPU_HEARTBEAT 0x01 /* timer interrupt */
	#define SCIR_CPU_ACTIVITY 0x02 /* not idle */
	#define SCIR_CPU_HB_INTERVAL (HZ) /* once per second */

	/* Loop through all installed blades */
	#define for_each_possible_blade(bid) \
	for ((bid) = 0; (bid) < uv_num_possible_blades(); (bid)++)

	/*
	* Macros for converting between kernel virtual addresses, socket local physical
	* addresses, and UV global physical addresses.
	* Note: use the standard __pa() & __va() macros for converting
	* between socket virtual and socket physical addresses.
	*/

	/* socket phys RAM --> UV global physical address */
	static inline unsigned long uv_soc_phys_ram_to_gpa(unsigned long paddr)
	{
	if (paddr < uv_hub_info->lowmem_remap_top)
	paddr \|= uv_hub_info->lowmem_remap_base;
	paddr \|= uv_hub_info->gnode_upper;
	paddr = ((paddr << uv_hub_info->m_shift) >> uv_hub_info->m_shift) \|
	((paddr >> uv_hub_info->m_val) << uv_hub_info->n_lshift);
	return paddr;
	}


	/* socket virtual --> UV global physical address */
	static inline unsigned long uv_gpa(void *v)
	{
	return uv_soc_phys_ram_to_gpa(__pa(v));
	}

	/* Top two bits indicate the requested address is in MMR space. */
	static inline int
	uv_gpa_in_mmr_space(unsigned long gpa)
	{
	return (gpa >> 62) == 0x3UL;
	}

	/* UV global physical address --> socket phys RAM */
	static inline unsigned long uv_gpa_to_soc_phys_ram(unsigned long gpa)
	{
	unsigned long paddr;
	unsigned long remap_base = uv_hub_info->lowmem_remap_base;
	unsigned long remap_top = uv_hub_info->lowmem_remap_top;

	gpa = ((gpa << uv_hub_info->m_shift) >> uv_hub_info->m_shift) \|
	((gpa >> uv_hub_info->n_lshift) << uv_hub_info->m_val);
	paddr = gpa & uv_hub_info->gpa_mask;
	if (paddr >= remap_base && paddr < remap_base + remap_top)
	paddr -= remap_base;
	return paddr;
	}


	/* gpa -> pnode */
	static inline unsigned long uv_gpa_to_gnode(unsigned long gpa)
	{
	return gpa >> uv_hub_info->n_lshift;
	}

	/* gpa -> pnode */
	static inline int uv_gpa_to_pnode(unsigned long gpa)
	{
	unsigned long n_mask = (1UL << uv_hub_info->n_val) - 1;

	return uv_gpa_to_gnode(gpa) & n_mask;
	}

	/* gpa -> node offset*/
	static inline unsigned long uv_gpa_to_offset(unsigned long gpa)
	{
	return (gpa << uv_hub_info->m_shift) >> uv_hub_info->m_shift;
	}

	/* pnode, offset --> socket virtual */
	static inline void *uv_pnode_offset_to_vaddr(int pnode, unsigned long offset)
	{
	return __va(((unsigned long)pnode << uv_hub_info->m_val) \| offset);
	}


	/*
	* Extract a PNODE from an APICID (full apicid, not processor subset)
	*/
	static inline int uv_apicid_to_pnode(int apicid)
	{
	return (apicid >> uv_hub_info->apic_pnode_shift);
	}

	/*
	* Convert an apicid to the socket number on the blade
	*/
	static inline int uv_apicid_to_socket(int apicid)
	{
	if (is_uv1_hub())
	return (apicid >> (uv_hub_info->apic_pnode_shift - 1)) & 1;
	else
	return 0;
	}

	/*
	* Access global MMRs using the low memory MMR32 space. This region supports
	* faster MMR access but not all MMRs are accessible in this space.
	*/
	static inline unsigned long *uv_global_mmr32_address(int pnode, unsigned long offset)
	{
	return __va(UV_GLOBAL_MMR32_BASE \|
	UV_GLOBAL_MMR32_PNODE_BITS(pnode) \| offset);
	}

	static inline void uv_write_global_mmr32(int pnode, unsigned long offset, unsigned long val)
	{
	writeq(val, uv_global_mmr32_address(pnode, offset));
	}

	static inline unsigned long uv_read_global_mmr32(int pnode, unsigned long offset)
	{
	return readq(uv_global_mmr32_address(pnode, offset));
	}

	/*
	* Access Global MMR space using the MMR space located at the top of physical
	* memory.
	*/
	static inline volatile void __iomem *uv_global_mmr64_address(int pnode, unsigned long offset)
	{
	return __va(UV_GLOBAL_MMR64_BASE \|
	UV_GLOBAL_MMR64_PNODE_BITS(pnode) \| offset);
	}

	static inline void uv_write_global_mmr64(int pnode, unsigned long offset, unsigned long val)
	{
	writeq(val, uv_global_mmr64_address(pnode, offset));
	}

	static inline unsigned long uv_read_global_mmr64(int pnode, unsigned long offset)
	{
	return readq(uv_global_mmr64_address(pnode, offset));
	}

	/*
	* Global MMR space addresses when referenced by the GRU. (GRU does
	* NOT use socket addressing).
	*/
	static inline unsigned long uv_global_gru_mmr_address(int pnode, unsigned long offset)
	{
	return UV_GLOBAL_GRU_MMR_BASE \| offset \|
	((unsigned long)pnode << uv_hub_info->m_val);
	}

	static inline void uv_write_global_mmr8(int pnode, unsigned long offset, unsigned char val)
	{
	writeb(val, uv_global_mmr64_address(pnode, offset));
	}

	static inline unsigned char uv_read_global_mmr8(int pnode, unsigned long offset)
	{
	return readb(uv_global_mmr64_address(pnode, offset));
	}

	/*
	* Access hub local MMRs. Faster than using global space but only local MMRs
	* are accessible.
	*/
	static inline unsigned long *uv_local_mmr_address(unsigned long offset)
	{
	return __va(UV_LOCAL_MMR_BASE \| offset);
	}

	static inline unsigned long uv_read_local_mmr(unsigned long offset)
	{
	return readq(uv_local_mmr_address(offset));
	}

	static inline void uv_write_local_mmr(unsigned long offset, unsigned long val)
	{
	writeq(val, uv_local_mmr_address(offset));
	}

	static inline unsigned char uv_read_local_mmr8(unsigned long offset)
	{
	return readb(uv_local_mmr_address(offset));
	}

	static inline void uv_write_local_mmr8(unsigned long offset, unsigned char val)
	{
	writeb(val, uv_local_mmr_address(offset));
	}

	/*
	* Structures and definitions for converting between cpu, node, pnode, and blade
	* numbers.
	*/
	struct uv_blade_info {
	unsigned short nr_possible_cpus;
	unsigned short nr_online_cpus;
	unsigned short pnode;
	short memory_nid;
	spinlock_t nmi_lock;
	unsigned long nmi_count;
	};
	extern struct uv_blade_info *uv_blade_info;
	extern short *uv_node_to_blade;
	extern short *uv_cpu_to_blade;
	extern short uv_possible_blades;

	/* Blade-local cpu number of current cpu. Numbered 0 .. <# cpus on the blade> */
	static inline int uv_blade_processor_id(void)
	{
	return uv_hub_info->blade_processor_id;
	}

	/* Blade number of current cpu. Numnbered 0 .. <#blades -1> */
	static inline int uv_numa_blade_id(void)
	{
	return uv_hub_info->numa_blade_id;
	}

	/* Convert a cpu number to the the UV blade number */
	static inline int uv_cpu_to_blade_id(int cpu)
	{
	return uv_cpu_to_blade[cpu];
	}

	/* Convert linux node number to the UV blade number */
	static inline int uv_node_to_blade_id(int nid)
	{
	return uv_node_to_blade[nid];
	}

	/* Convert a blade id to the PNODE of the blade */
	static inline int uv_blade_to_pnode(int bid)
	{
	return uv_blade_info[bid].pnode;
	}

	/* Nid of memory node on blade. -1 if no blade-local memory */
	static inline int uv_blade_to_memory_nid(int bid)
	{
	return uv_blade_info[bid].memory_nid;
	}

	/* Determine the number of possible cpus on a blade */
	static inline int uv_blade_nr_possible_cpus(int bid)
	{
	return uv_blade_info[bid].nr_possible_cpus;
	}

	/* Determine the number of online cpus on a blade */
	static inline int uv_blade_nr_online_cpus(int bid)
	{
	return uv_blade_info[bid].nr_online_cpus;
	}

	/* Convert a cpu id to the PNODE of the blade containing the cpu */
	static inline int uv_cpu_to_pnode(int cpu)
	{
	return uv_blade_info[uv_cpu_to_blade_id(cpu)].pnode;
	}

	/* Convert a linux node number to the PNODE of the blade */
	static inline int uv_node_to_pnode(int nid)
	{
	return uv_blade_info[uv_node_to_blade_id(nid)].pnode;
	}

	/* Maximum possible number of blades */
	static inline int uv_num_possible_blades(void)
	{
	return uv_possible_blades;
	}

	/* Update SCIR state */
	static inline void uv_set_scir_bits(unsigned char value)
	{
	if (uv_hub_info->scir.state != value) {
	uv_hub_info->scir.state = value;
	uv_write_local_mmr8(uv_hub_info->scir.offset, value);
	}
	}

	static inline unsigned long uv_scir_offset(int apicid)
	{
	return SCIR_LOCAL_MMR_BASE \| (apicid & 0x3f);
	}

	static inline void uv_set_cpu_scir_bits(int cpu, unsigned char value)
	{
	if (uv_cpu_hub_info(cpu)->scir.state != value) {
	uv_write_global_mmr8(uv_cpu_to_pnode(cpu),
	uv_cpu_hub_info(cpu)->scir.offset, value);
	uv_cpu_hub_info(cpu)->scir.state = value;
	}
	}

	extern unsigned int uv_apicid_hibits;
	static unsigned long uv_hub_ipi_value(int apicid, int vector, int mode)
	{
	apicid \|= uv_apicid_hibits;
	return (1UL << UVH_IPI_INT_SEND_SHFT) \|
	((apicid) << UVH_IPI_INT_APIC_ID_SHFT) \|
	(mode << UVH_IPI_INT_DELIVERY_MODE_SHFT) \|
	(vector << UVH_IPI_INT_VECTOR_SHFT);
	}

	static inline void uv_hub_send_ipi(int pnode, int apicid, int vector)
	{
	unsigned long val;
	unsigned long dmode = dest_Fixed;

	if (vector == NMI_VECTOR)
	dmode = dest_NMI;

	val = uv_hub_ipi_value(apicid, vector, dmode);
	uv_write_global_mmr64(pnode, UVH_IPI_INT, val);
	}

	/*
	* Get the minimum revision number of the hub chips within the partition.
	* 1 - UV1 rev 1.0 initial silicon
	* 2 - UV1 rev 2.0 production silicon
	* 3 - UV2 rev 1.0 initial silicon
	*/
	static inline int uv_get_min_hub_revision_id(void)
	{
	return uv_hub_info->hub_revision;
	}

	#endif /* CONFIG_X86_64 */
	#endif /* _ASM_X86_UV_UV_HUB_H */