📄 sn_cpuid.h
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/* * * 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. * * Copyright (C) 2000 Silicon Graphics, Inc. * Copyright (C) 2000 by Jack Steiner (steiner@sgi.com) */#ifndef _ASM_IA64_SN_SN_CPUID_H#define _ASM_IA64_SN_SN_CPUID_H#include <linux/config.h>#include <asm/processor.h>#include <asm/sn/mmzone_sn1.h>/* * Functions for converting between cpuids, nodeids and NASIDs. * * These are for SGI platforms only. * *//* * Definitions of terms (these definitions are for IA64 ONLY. Other architectures * use cpuid/cpunum quite defferently): * * CPUID - a number in range of 0..NR_CPUS-1 that uniquely identifies * the cpu. The value cpuid has no significance on IA64 other than * the boot cpu is 0. * smp_processor_id() returns the cpuid of the current cpu. * * CPUNUM - On IA64, a cpunum and cpuid are the same. This is NOT true * on other architectures like IA32. * * CPU_PHYSICAL_ID (also known as HARD_PROCESSOR_ID) * This is the same as 31:24 of the processor LID register * hard_smp_processor_id()- cpu_physical_id of current processor * cpu_physical_id(cpuid) - convert a <cpuid> to a <physical_cpuid> * cpu_logical_id(phy_id) - convert a <physical_cpuid> to a <cpuid> * * not real efficient - dont use in perf critical code * * LID - processor defined register (see PRM V2). * 31:24 - id Contains the NASID * 23:16 - eid Contains 0-3 to identify the cpu on the node * bit 17 - synergy number * bit 16 - FSB slot number * * * * The following assumes the following mappings for LID register values: * * The macros convert between cpu physical ids & slice/fsb/synergy/nasid/cnodeid. * These terms are described below: * * * ----- ----- ----- ----- CPU * | 0 | | 1 | | 2 | | 3 | SLICE * ----- ----- ----- ----- * | | | | * | | | | * 0 | | 1 0 | | 1 FSB SLOT * ------- ------- * | | * | | * ------- ------- * | | | | * | 0 | | 1 | SYNERGY * | | | | * ------- ------- * | | * | | * ------------------------------- * | | * | BEDROCK | NASID (0..127) * | | CNODEID (0..numnodes-1) * | | * | | * ------------------------------- * | * */#ifndef CONFIG_SMP#define cpu_logical_id(cpu) 0#define cpu_physical_id(cpuid) ((ia64_get_lid() >> 16) & 0xffff)#endif#define cpu_physical_id_to_nasid(cpi) ((cpi) >> 8)#define cpu_physical_id_to_synergy(cpi) (((cpi) >> 1) & 1)#define cpu_physical_id_to_fsb_slot(cpi) ((cpi) & 1)#define cpu_physical_id_to_slice(cpi) ((cpi) & 3)/* * NOTE: id & eid refer to Intels definitions of the LID register * (id = NASID, eid = slice) * NOTE: on non-MP systems, only cpuid 0 exists */#define id_eid_to_cpu_physical_id(id,eid) (((id)<<8) | (eid))#define id_eid_to_cpuid(id,eid) (cpu_logical_id(id_eid_to_cpu_physical_id((id),(eid))))/* * The following table/struct is used for managing PTC coherency domains. */typedef struct { u8 domain; u8 reserved; u16 sapicid;} sn_sapicid_info_t;extern sn_sapicid_info_t sn_sapicid_info[]; /* indexed by cpuid *//* * cpuid_to_fsb_slot - convert a cpuid to the fsb slot number that it is in. * (there are 2 cpus per FSB. This function returns 0 or 1) */static __inline__ intcpuid_to_fsb_slot(int cpuid){ return cpu_physical_id_to_fsb_slot(cpu_physical_id(cpuid));}/* * cpuid_to_synergy - convert a cpuid to the synergy that it resides on * (there are 2 synergies per node. Function returns 0 or 1 to * specify which synergy the cpu is on) */static __inline__ intcpuid_to_synergy(int cpuid){ return cpu_physical_id_to_synergy(cpu_physical_id(cpuid));}/* * cpuid_to_slice - convert a cpuid to the slice that it resides on * There are 4 cpus per node. This function returns 0 .. 3) */static __inline__ intcpuid_to_slice(int cpuid){ return cpu_physical_id_to_slice(cpu_physical_id(cpuid));}/* * cpuid_to_nasid - convert a cpuid to the NASID that it resides on */static __inline__ intcpuid_to_nasid(int cpuid){ return cpu_physical_id_to_nasid(cpu_physical_id(cpuid));}/* * cpuid_to_cnodeid - convert a cpuid to the cnode that it resides on */static __inline__ intcpuid_to_cnodeid(int cpuid){ return nasid_map[cpuid_to_nasid(cpuid)];}/* * cnodeid_to_nasid - convert a cnodeid to a NASID */static __inline__ intcnodeid_to_nasid(int cnodeid){ if (nasid_map[cnodeid_map[cnodeid]] != cnodeid) panic("cnodeid_to_nasid, cnode = %d", cnodeid); return cnodeid_map[cnodeid];}/* * nasid_to_cnodeid - convert a NASID to a cnodeid */static __inline__ intnasid_to_cnodeid(int nasid){ if (cnodeid_map[nasid_map[nasid]] != nasid) panic("nasid_to_cnodeid"); return nasid_map[nasid];}/* * cnode_slice_to_cpuid - convert a codeid & slice to a cpuid */static __inline__ intcnode_slice_to_cpuid(int cnodeid, int slice) { return(id_eid_to_cpuid(cnodeid_to_nasid(cnodeid),slice));}/* * cpuid_to_subnode - convert a cpuid to the subnode it resides on. * slice 0 & 1 are on subnode 0 * slice 2 & 3 are on subnode 1. */static __inline__ intcpuid_to_subnode(int cpuid) { int ret = cpuid_to_slice(cpuid); if (ret < 2) return 0; else return 1;}/* * cpuid_to_localslice - convert a cpuid to a local slice * slice 0 & 2 are local slice 0 * slice 1 & 3 are local slice 1 */static __inline__ intcpuid_to_localslice(int cpuid) { return(cpuid_to_slice(cpuid) & 1);}static __inline__ intcnodeid_to_cpuid(int cnode) { int cpu; for (cpu = 0; cpu < smp_num_cpus; cpu++) { if (cpuid_to_cnodeid(cpu) == cnode) { break; } } if (cpu == smp_num_cpus) cpu = -1; return cpu;}#endif /* _ASM_IA64_SN_SN_CPUID_H */⌨️ 快捷键说明
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