dev/acpi/acpi_srat.c

1.3  jruoho /* $NetBSD: acpi_srat.c,v 1.3 2010/03/05 14:00:17 jruoho Exp $ */
1.1  cegger
1.1  cegger /*
1.1  cegger  * Copyright (c) 2009 The NetBSD Foundation, Inc.
1.1  cegger  * All rights reserved.
1.1  cegger  *
1.1  cegger  * This code is derived from software contributed to The NetBSD Foundation
1.1  cegger  * by Christoph Egger.
1.1  cegger  *
1.1  cegger  * Redistribution and use in source and binary forms, with or without
1.1  cegger  * modification, are permitted provided that the following conditions
1.1  cegger  * are met:
1.1  cegger  * 1. Redistributions of source code must retain the above copyright
1.1  cegger  *    notice, this list of conditions and the following disclaimer.
1.1  cegger  * 2. Redistributions in binary form must reproduce the above copyright
1.1  cegger  *    notice, this list of conditions and the following disclaimer in the
1.1  cegger  *    documentation and/or other materials provided with the distribution.
1.1  cegger  *
1.1  cegger  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1  cegger  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  cegger  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  cegger  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  cegger  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  cegger  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  cegger  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  cegger  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  cegger  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  cegger  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  cegger  * POSSIBILITY OF SUCH DAMAGE.
1.1  cegger  */
1.1  cegger
1.1  cegger #include <sys/cdefs.h>
1.3  jruoho __KERNEL_RCSID(0, "$NetBSD: acpi_srat.c,v 1.3 2010/03/05 14:00:17 jruoho Exp $");
1.1  cegger
1.1  cegger #include <sys/param.h>
1.3  jruoho #include <sys/kmem.h>
1.1  cegger #include <sys/systm.h>
1.1  cegger
1.1  cegger #include <dev/acpi/acpivar.h>
1.1  cegger #include <dev/acpi/acpi_srat.h>
1.1  cegger
1.1  cegger static ACPI_TABLE_SRAT *srat;
1.1  cegger
1.1  cegger struct acpisrat_node {
1.1  cegger 	acpisrat_nodeid_t nodeid;
1.1  cegger 	uint32_t ncpus; /* Number of cpus in this node */
1.1  cegger 	struct acpisrat_cpu **cpu; /* Array of cpus */
1.1  cegger 	uint32_t nmems; /* Number of memory ranges in this node */
1.1  cegger 	struct acpisrat_mem **mem; /* Array of memory ranges */
1.1  cegger };
1.1  cegger
1.1  cegger static uint32_t nnodes; /* Number of NUMA nodes */
1.1  cegger static struct acpisrat_node *node_array; /* Array of NUMA nodes */
1.1  cegger static uint32_t ncpus; /* Number of CPUs */
1.1  cegger static struct acpisrat_cpu *cpu_array; /* Array of cpus */
1.1  cegger static uint32_t nmems; /* Number of Memory ranges */
1.1  cegger static struct acpisrat_mem *mem_array;
1.1  cegger
1.1  cegger
1.1  cegger struct cpulist {
1.1  cegger 	struct acpisrat_cpu cpu;
1.1  cegger 	TAILQ_ENTRY(cpulist) entry;
1.1  cegger };
1.1  cegger
1.1  cegger static TAILQ_HEAD(, cpulist) cpulisthead;
1.1  cegger
1.1  cegger #define CPU_INIT		TAILQ_INIT(&cpulisthead);
1.1  cegger #define CPU_FOREACH(cpu)	TAILQ_FOREACH(cpu, &cpulisthead, entry)
1.1  cegger #define CPU_ADD(cpu)		TAILQ_INSERT_TAIL(&cpulisthead, cpu, entry)
1.1  cegger #define CPU_REM(cpu)		TAILQ_REMOVE(&cpulisthead, cpu, entry)
1.1  cegger #define CPU_FIRST		TAILQ_FIRST(&cpulisthead)
1.1  cegger
1.1  cegger
1.1  cegger struct memlist {
1.1  cegger 	struct acpisrat_mem mem;
1.1  cegger 	TAILQ_ENTRY(memlist) entry;
1.1  cegger };
1.1  cegger
1.1  cegger static TAILQ_HEAD(, memlist) memlisthead;
1.1  cegger
1.1  cegger #define MEM_INIT		TAILQ_INIT(&memlisthead)
1.1  cegger #define MEM_FOREACH(mem)	TAILQ_FOREACH(mem, &memlisthead, entry)
1.1  cegger #define MEM_ADD(mem)		TAILQ_INSERT_TAIL(&memlisthead, mem, entry)
1.1  cegger #define MEM_ADD_BEFORE(mem, b)	TAILQ_INSERT_BEFORE(b, mem, entry)
1.1  cegger #define MEM_REM(mem)		TAILQ_REMOVE(&memlisthead, mem, entry)
1.1  cegger #define MEM_FIRST		TAILQ_FIRST(&memlisthead)
1.1  cegger
1.1  cegger
1.1  cegger static struct cpulist *
1.1  cegger cpu_alloc(void)
1.1  cegger {
1.1  cegger 	return kmem_zalloc(sizeof(struct cpulist), KM_NOSLEEP);
1.1  cegger }
1.1  cegger
1.1  cegger static void
1.1  cegger cpu_free(struct cpulist *c)
1.1  cegger {
1.1  cegger 	kmem_free(c, sizeof(struct cpulist));
1.1  cegger }
1.1  cegger
1.1  cegger #if 0
1.1  cegger static struct cpulist *
1.1  cegger cpu_get(acpisrat_nodeid_t nodeid)
1.1  cegger {
1.1  cegger 	struct cpulist *tmp;
1.1  cegger
1.1  cegger 	CPU_FOREACH(tmp) {
1.1  cegger 		if (tmp->cpu.nodeid == nodeid)
1.1  cegger 			return tmp;
1.1  cegger 	}
1.1  cegger
1.1  cegger 	return NULL;
1.1  cegger }
1.1  cegger #endif
1.1  cegger
1.1  cegger static struct memlist *
1.1  cegger mem_alloc(void)
1.1  cegger {
1.1  cegger 	return kmem_zalloc(sizeof(struct memlist), KM_NOSLEEP);
1.1  cegger }
1.1  cegger
1.1  cegger static void
1.1  cegger mem_free(struct memlist *m)
1.1  cegger {
1.1  cegger 	kmem_free(m, sizeof(struct memlist));
1.1  cegger }
1.1  cegger
1.1  cegger static struct memlist *
1.1  cegger mem_get(acpisrat_nodeid_t nodeid)
1.1  cegger {
1.1  cegger 	struct memlist *tmp;
1.1  cegger
1.1  cegger 	MEM_FOREACH(tmp) {
1.1  cegger 		if (tmp->mem.nodeid == nodeid)
1.1  cegger 			return tmp;
1.1  cegger 	}
1.1  cegger
1.1  cegger 	return NULL;
1.1  cegger }
1.1  cegger
1.1  cegger
1.1  cegger bool
1.1  cegger acpisrat_exist(void)
1.1  cegger {
1.1  cegger 	ACPI_TABLE_HEADER *table;
1.1  cegger 	ACPI_STATUS rv;
1.1  cegger
1.1  cegger 	rv = AcpiGetTable(ACPI_SIG_SRAT, 1, (ACPI_TABLE_HEADER **)&table);
1.1  cegger 	if (ACPI_FAILURE(rv))
1.1  cegger 		return false;
1.1  cegger
1.1  cegger 	/* Check if header is valid */
1.1  cegger 	if (table == NULL)
1.1  cegger 		return false;
1.1  cegger
1.1  cegger 	if (table->Length == 0xffffffff)
1.1  cegger 		return false;
1.1  cegger
1.1  cegger 	srat = (ACPI_TABLE_SRAT *)table;
1.1  cegger
1.1  cegger 	return true;
1.1  cegger }
1.1  cegger
1.1  cegger static int
1.1  cegger acpisrat_parse(void)
1.1  cegger {
1.1  cegger 	ACPI_SUBTABLE_HEADER *subtable;
1.1  cegger 	ACPI_SRAT_CPU_AFFINITY *srat_cpu;
1.1  cegger 	ACPI_SRAT_MEM_AFFINITY *srat_mem;
1.1  cegger 	ACPI_SRAT_X2APIC_CPU_AFFINITY *srat_x2apic;
1.1  cegger
1.1  cegger 	acpisrat_nodeid_t nodeid;
1.1  cegger 	struct cpulist *cpuentry = NULL;
1.1  cegger 	struct memlist *mementry;
1.1  cegger 	uint32_t srat_pos;
1.1  cegger 	bool ignore_cpu_affinity = false;
1.1  cegger
1.1  cegger 	KASSERT(srat != NULL);
1.1  cegger
1.1  cegger 	/* Content starts right after the header */
1.1  cegger 	srat_pos = sizeof(ACPI_TABLE_SRAT);
1.1  cegger
1.1  cegger 	while (srat_pos < srat->Header.Length) {
1.1  cegger 		subtable = (ACPI_SUBTABLE_HEADER *)((char *)srat + srat_pos);
1.1  cegger 		srat_pos += subtable->Length;
1.1  cegger
1.1  cegger 		switch (subtable->Type) {
1.1  cegger 		case ACPI_SRAT_TYPE_CPU_AFFINITY:
1.1  cegger 			if (ignore_cpu_affinity)
1.1  cegger 				continue;
1.1  cegger
1.1  cegger 			srat_cpu = (ACPI_SRAT_CPU_AFFINITY *)subtable;
1.1  cegger 			nodeid = (srat_cpu->ProximityDomainHi[2] << 24) |
1.1  cegger 			    (srat_cpu->ProximityDomainHi[1] << 16) |
1.1  cegger 			    (srat_cpu->ProximityDomainHi[0] << 8) |
1.1  cegger 			    (srat_cpu->ProximityDomainLo);
1.1  cegger
1.1  cegger 			cpuentry = cpu_alloc();
1.1  cegger 			if (cpuentry == NULL)
1.1  cegger 				return ENOMEM;
1.1  cegger 			CPU_ADD(cpuentry);
1.1  cegger
1.1  cegger 			cpuentry->cpu.nodeid = nodeid;
1.1  cegger 			cpuentry->cpu.apicid = srat_cpu->ApicId;
1.1  cegger 			cpuentry->cpu.sapiceid = srat_cpu->LocalSapicEid;
1.1  cegger 			cpuentry->cpu.flags = srat_cpu->Flags;
1.1  cegger 			cpuentry->cpu.clockdomain = srat_cpu->ClockDomain;
1.1  cegger 			break;
1.1  cegger
1.1  cegger 		case ACPI_SRAT_TYPE_MEMORY_AFFINITY:
1.1  cegger 			srat_mem = (ACPI_SRAT_MEM_AFFINITY *)subtable;
1.1  cegger 			nodeid = srat_mem->ProximityDomain;
1.1  cegger
1.1  cegger 			mementry = mem_alloc();
1.1  cegger 			if (mementry == NULL)
1.1  cegger 				return ENOMEM;
1.1  cegger 			MEM_ADD(mementry);
1.1  cegger
1.1  cegger 			mementry->mem.nodeid = nodeid;
1.1  cegger 			mementry->mem.baseaddress = srat_mem->BaseAddress;
1.1  cegger 			mementry->mem.length = srat_mem->Length;
1.1  cegger 			mementry->mem.flags = srat_mem->Flags;
1.1  cegger 			break;
1.1  cegger
1.1  cegger 		case ACPI_SRAT_TYPE_X2APIC_CPU_AFFINITY:
1.1  cegger 			srat_x2apic = (ACPI_SRAT_X2APIC_CPU_AFFINITY *)subtable;
1.1  cegger 			nodeid = srat_x2apic->ProximityDomain;
1.1  cegger
1.1  cegger 			/* This table entry overrides
1.1  cegger 			 * ACPI_SRAT_TYPE_CPU_AFFINITY.
1.1  cegger 			 */
1.1  cegger 			if (!ignore_cpu_affinity) {
1.1  cegger 				struct cpulist *citer;
1.1  cegger 				while ((citer = CPU_FIRST) != NULL) {
1.1  cegger 					CPU_REM(citer);
1.1  cegger 					cpu_free(citer);
1.1  cegger 				}
1.1  cegger 				ignore_cpu_affinity = true;
1.1  cegger 			}
1.1  cegger
1.1  cegger 			cpuentry = cpu_alloc();
1.1  cegger 			if (cpuentry == NULL)
1.1  cegger 				return ENOMEM;
1.1  cegger 			CPU_ADD(cpuentry);
1.1  cegger
1.1  cegger 			cpuentry->cpu.nodeid = nodeid;
1.1  cegger 			cpuentry->cpu.apicid = srat_x2apic->ApicId;
1.1  cegger 			cpuentry->cpu.clockdomain = srat_x2apic->ClockDomain;
1.1  cegger 			cpuentry->cpu.flags = srat_x2apic->Flags;
1.1  cegger 			break;
1.1  cegger
1.1  cegger 		case ACPI_SRAT_TYPE_RESERVED:
1.1  cegger 			printf("ACPI SRAT subtable reserved, length: 0x%x\n",
1.1  cegger 				subtable->Length);
1.1  cegger 			break;
1.1  cegger 		}
1.1  cegger 	}
1.1  cegger
1.1  cegger 	return 0;
1.1  cegger }
1.1  cegger
1.1  cegger static int
1.1  cegger acpisrat_quirks(void)
1.1  cegger {
1.1  cegger 	struct cpulist *citer;
1.1  cegger 	struct memlist *mem, *miter;
1.1  cegger
1.1  cegger 	/* Some sanity checks. */
1.1  cegger
1.1  cegger 	/* Deal with holes in the memory nodes.
1.1  cegger 	 * BIOS doesn't enlist memory nodes which
1.1  cegger 	 * don't have any memory modules plugged in.
1.1  cegger 	 * This behaviour has been observed on AMD machines.
1.1  cegger 	 *
1.1  cegger 	 * Do that by searching for CPUs in NUMA nodes
1.1  cegger 	 * which don't exist in the memory and then insert
1.1  cegger 	 * a zero memory range for the missing node.
1.1  cegger 	 */
1.1  cegger 	CPU_FOREACH(citer) {
1.1  cegger 		mem = mem_get(citer->cpu.nodeid);
1.1  cegger 		if (mem != NULL)
1.1  cegger 			continue;
1.1  cegger 		mem = mem_alloc();
1.1  cegger 		if (mem == NULL)
1.1  cegger 			return ENOMEM;
1.1  cegger 		mem->mem.nodeid = citer->cpu.nodeid;
1.1  cegger 		/* all other fields are already zero filled */
1.1  cegger
1.1  cegger 		MEM_FOREACH(miter) {
1.1  cegger 			if (miter->mem.nodeid < citer->cpu.nodeid)
1.1  cegger 				continue;
1.1  cegger 			MEM_ADD_BEFORE(mem, miter);
1.1  cegger 			break;
1.1  cegger 		}
1.1  cegger 	}
1.1  cegger
1.1  cegger 	return 0;
1.1  cegger }
1.1  cegger
1.1  cegger int
1.1  cegger acpisrat_init(void)
1.1  cegger {
1.1  cegger 	if (!acpisrat_exist())
1.1  cegger 		return EEXIST;
1.1  cegger 	return acpisrat_refresh();
1.1  cegger }
1.1  cegger
1.1  cegger int
1.1  cegger acpisrat_refresh(void)
1.1  cegger {
1.1  cegger 	int rc, i, j, k;
1.1  cegger 	struct cpulist *citer;
1.1  cegger 	struct memlist *miter;
1.1  cegger 	uint32_t cnodes = 0, mnodes = 0;
1.1  cegger
1.1  cegger 	CPU_INIT;
1.1  cegger 	MEM_INIT;
1.1  cegger
1.1  cegger 	rc = acpisrat_parse();
1.1  cegger 	if (rc)
1.1  cegger 		return rc;
1.1  cegger
1.1  cegger 	rc = acpisrat_quirks();
1.1  cegger 	if (rc)
1.1  cegger 		return rc;
1.1  cegger
1.1  cegger 	/* cleanup resources */
1.1  cegger 	rc = acpisrat_exit();
1.1  cegger 	if (rc)
1.1  cegger 		return rc;
1.1  cegger
1.1  cegger 	nnodes = 0;
1.1  cegger 	ncpus = 0;
1.1  cegger 	CPU_FOREACH(citer) {
1.1  cegger 		cnodes = MAX(citer->cpu.nodeid, cnodes);
1.1  cegger 		ncpus++;
1.1  cegger 	}
1.1  cegger
1.1  cegger 	nmems = 0;
1.1  cegger 	MEM_FOREACH(miter) {
1.1  cegger 		mnodes = MAX(miter->mem.nodeid, mnodes);
1.1  cegger 		nmems++;
1.1  cegger 	}
1.1  cegger
1.1  cegger 	nnodes = MAX(cnodes, mnodes) + 1;
1.1  cegger
1.1  cegger 	node_array = kmem_zalloc(nnodes * sizeof(struct acpisrat_node),
1.1  cegger 	    KM_NOSLEEP);
1.1  cegger 	if (node_array == NULL)
1.1  cegger 		return ENOMEM;
1.1  cegger
1.1  cegger 	cpu_array = kmem_zalloc(ncpus * sizeof(struct acpisrat_cpu),
1.1  cegger 	    KM_NOSLEEP);
1.1  cegger 	if (cpu_array == NULL)
1.1  cegger 		return ENOMEM;
1.1  cegger
1.1  cegger 	mem_array = kmem_zalloc(nmems * sizeof(struct acpisrat_mem),
1.1  cegger 	    KM_NOSLEEP);
1.1  cegger 	if (mem_array == NULL)
1.1  cegger 		return ENOMEM;
1.1  cegger
1.1  cegger 	i = 0;
1.1  cegger 	CPU_FOREACH(citer) {
1.1  cegger 		memcpy(&cpu_array[i], &citer->cpu, sizeof(struct acpisrat_cpu));
1.1  cegger 		i++;
1.1  cegger 		node_array[citer->cpu.nodeid].ncpus++;
1.1  cegger 	}
1.1  cegger
1.1  cegger 	i = 0;
1.1  cegger 	MEM_FOREACH(miter) {
1.1  cegger 		memcpy(&mem_array[i], &miter->mem, sizeof(struct acpisrat_mem));
1.1  cegger 		i++;
1.1  cegger 		node_array[miter->mem.nodeid].nmems++;
1.1  cegger 	}
1.1  cegger
1.1  cegger 	for (i = 0; i < nnodes; i++) {
1.1  cegger 		node_array[i].nodeid = i;
1.1  cegger
1.1  cegger 		node_array[i].cpu = kmem_zalloc(node_array[i].ncpus *
1.1  cegger 		    sizeof(struct acpisrat_cpu *), KM_NOSLEEP);
1.1  cegger 		node_array[i].mem = kmem_zalloc(node_array[i].nmems *
1.1  cegger 		    sizeof(struct acpisrat_mem *), KM_NOSLEEP);
1.1  cegger
1.1  cegger 		k = 0;
1.1  cegger 		for (j = 0; j < ncpus; j++) {
1.1  cegger 			if (cpu_array[j].nodeid != i)
1.1  cegger 				continue;
1.1  cegger 			node_array[i].cpu[k] = &cpu_array[j];
1.1  cegger 			k++;
1.1  cegger 		}
1.1  cegger
1.1  cegger 		k = 0;
1.1  cegger 		for (j = 0; j < nmems; j++) {
1.1  cegger 			if (mem_array[j].nodeid != i)
1.1  cegger 				continue;
1.1  cegger 			node_array[i].mem[k] = &mem_array[j];
1.1  cegger 			k++;
1.1  cegger 		}
1.1  cegger 	}
1.1  cegger
1.1  cegger 	while ((citer = CPU_FIRST) != NULL) {
1.1  cegger 		CPU_REM(citer);
1.1  cegger 		cpu_free(citer);
1.1  cegger 	}
1.1  cegger
1.1  cegger 	while ((miter = MEM_FIRST) != NULL) {
1.1  cegger 		MEM_REM(miter);
1.1  cegger 		mem_free(miter);
1.1  cegger 	}
1.1  cegger
1.1  cegger 	return 0;
1.1  cegger }
1.1  cegger
1.1  cegger
1.1  cegger int
1.1  cegger acpisrat_exit(void)
1.1  cegger {
1.1  cegger 	int i;
1.1  cegger
1.1  cegger 	if (node_array) {
1.1  cegger 		for (i = 0; i < nnodes; i++) {
1.1  cegger 			if (node_array[i].cpu)
1.1  cegger 				kmem_free(node_array[i].cpu,
1.1  cegger 				    node_array[i].ncpus * sizeof(struct acpisrat_cpu *));
1.1  cegger 			if (node_array[i].mem)
1.1  cegger 				kmem_free(node_array[i].mem,
1.1  cegger 				    node_array[i].nmems * sizeof(struct acpisrat_mem *));
1.1  cegger 		}
1.1  cegger 		kmem_free(node_array, nnodes * sizeof(struct acpisrat_node));
1.1  cegger 	}
1.1  cegger 	node_array = NULL;
1.1  cegger
1.1  cegger 	if (cpu_array)
1.1  cegger 		kmem_free(cpu_array, ncpus * sizeof(struct acpisrat_cpu));
1.1  cegger 	cpu_array = NULL;
1.1  cegger
1.1  cegger 	if (mem_array)
1.1  cegger 		kmem_free(mem_array, nmems * sizeof(struct acpisrat_mem));
1.1  cegger 	mem_array = NULL;
1.1  cegger
1.1  cegger 	nnodes = 0;
1.1  cegger 	ncpus = 0;
1.1  cegger 	nmems = 0;
1.1  cegger
1.1  cegger 	return 0;
1.1  cegger }
1.1  cegger
1.1  cegger
1.1  cegger void
1.1  cegger acpisrat_dump(void)
1.1  cegger {
1.1  cegger 	uint32_t i, j, nn, nc, nm;
1.1  cegger 	struct acpisrat_cpu c;
1.1  cegger 	struct acpisrat_mem m;
1.1  cegger
1.1  cegger 	nn = acpisrat_nodes();
1.1  cegger 	aprint_debug("SRAT: %u NUMA nodes\n", nn);
1.1  cegger 	for (i = 0; i < nn; i++) {
1.1  cegger 		nc = acpisrat_node_cpus(i);
1.1  cegger 		for (j = 0; j < nc; j++) {
1.1  cegger 			acpisrat_cpu(i, j, &c);
1.1  cegger 			aprint_debug("SRAT: node %u cpu %u "
1.1  cegger 			    "(apic %u, sapic %u, flags %u, clockdomain %u)\n",
1.1  cegger 			    c.nodeid, j, c.apicid, c.sapiceid, c.flags,
1.1  cegger 			    c.clockdomain);
1.1  cegger 		}
1.1  cegger
1.1  cegger 		nm = acpisrat_node_memoryranges(i);
1.1  cegger 		for (j = 0; j < nm; j++) {
1.1  cegger 			acpisrat_mem(i, j, &m);
1.1  cegger 			aprint_debug("SRAT: node %u memory range %u (0x%"
1.1  cegger 			    PRIx64" - 0x%"PRIx64" flags %u)\n",
1.1  cegger 			    m.nodeid, j, m.baseaddress,
1.1  cegger 			    m.baseaddress + m.length, m.flags);
1.1  cegger 		}
1.1  cegger 	}
1.1  cegger }
1.1  cegger
1.1  cegger uint32_t
1.1  cegger acpisrat_nodes(void)
1.1  cegger {
1.1  cegger 	return nnodes;
1.1  cegger }
1.1  cegger
1.1  cegger uint32_t
1.1  cegger acpisrat_node_cpus(acpisrat_nodeid_t nodeid)
1.1  cegger {
1.1  cegger 	return node_array[nodeid].ncpus;
1.1  cegger }
1.1  cegger
1.1  cegger uint32_t
1.1  cegger acpisrat_node_memoryranges(acpisrat_nodeid_t nodeid)
1.1  cegger {
1.1  cegger 	return node_array[nodeid].nmems;
1.1  cegger }
1.1  cegger
1.1  cegger void
1.1  cegger acpisrat_cpu(acpisrat_nodeid_t nodeid, uint32_t cpunum,
1.1  cegger     struct acpisrat_cpu *c)
1.1  cegger {
1.1  cegger 	memcpy(c, node_array[nodeid].cpu[cpunum],
1.1  cegger 	    sizeof(struct acpisrat_cpu));
1.1  cegger }
1.1  cegger
1.1  cegger void
1.1  cegger acpisrat_mem(acpisrat_nodeid_t nodeid, uint32_t memrange,
1.1  cegger     struct acpisrat_mem *mem)
1.1  cegger {
1.1  cegger 	memcpy(mem, node_array[nodeid].mem[memrange],
1.1  cegger 	    sizeof(struct acpisrat_mem));
1.1  cegger }