cpu_topology.c   [plain text]


/*
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 * 
 * This file contains Original Code and/or Modifications of Original Code
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 * compliance with the License. The rights granted to you under the License
 * may not be used to create, or enable the creation or redistribution of,
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 * terms of an Apple operating system software license agreement.
 * 
 * Please obtain a copy of the License at
 * http://www.opensource.apple.com/apsl/ and read it before using this file.
 * 
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#include <mach/machine.h>
#include <mach/processor.h>
#include <kern/kalloc.h>
#include <i386/cpu_affinity.h>
#include <i386/cpu_topology.h>
#include <i386/cpu_threads.h>
#include <i386/machine_cpu.h>
#include <i386/lock.h>
#include <i386/cpu_data.h>
#include <i386/lapic.h>
#include <i386/machine_routines.h>

__private_extern__ void qsort(
    void * array,
    size_t nmembers,
    size_t member_size,
    int (*)(const void *, const void *));

static int lapicid_cmp(const void *x, const void *y);
static x86_affinity_set_t *find_cache_affinity(x86_cpu_cache_t *L2_cachep);

x86_affinity_set_t	*x86_affinities = NULL;
static int		x86_affinity_count = 0;

/*
 * cpu_topology_sort() is called after all processors have been registered
 * but before any non-boot processor id started.
 * We establish canonical logical processor numbering - logical cpus must be
 * contiguous, zero-based and assigned in physical (local apic id) order.
 * This step is required because the discovery/registration order is
 * non-deterministic - cores are registered in differing orders over boots.
 * Enforcing canonical numbering simplifies identification
 * of processors - in particular, for stopping/starting from CHUD.
 */ 
void
cpu_topology_sort(int ncpus)
{
	int		i;
	boolean_t	istate;
	processor_t		lprim = NULL;

	assert(machine_info.physical_cpu == 1);
	assert(machine_info.logical_cpu == 1);
	assert(master_cpu == 0);
	assert(cpu_number() == 0);
	assert(cpu_datap(0)->cpu_number == 0);

	/* Lights out for this */
	istate = ml_set_interrupts_enabled(FALSE);

	if (topo_dbg) {
		TOPO_DBG("cpu_topology_start() %d cpu%s registered\n",
			ncpus, (ncpus > 1) ? "s" : "");
		for (i = 0; i < ncpus; i++) {
			cpu_data_t	*cpup = cpu_datap(i);
			TOPO_DBG("\tcpu_data[%d]:%p local apic 0x%x\n",
				i, (void *) cpup, cpup->cpu_phys_number);
		}
	}

	/*
	 * Re-order the cpu_data_ptr vector sorting by physical id.
	 * Skip the boot processor, it's required to be correct.
	 */
	if (ncpus > 1) {
		qsort((void *) &cpu_data_ptr[1],
			ncpus - 1,
			sizeof(cpu_data_t *),
			lapicid_cmp);
	}
	if (topo_dbg) {
		TOPO_DBG("cpu_topology_start() after sorting:\n");
		for (i = 0; i < ncpus; i++) {
			cpu_data_t	*cpup = cpu_datap(i);
			TOPO_DBG("\tcpu_data[%d]:%p local apic 0x%x\n",
				i, (void *) cpup, cpup->cpu_phys_number);
		}
	}

	/*
	 * Fix up logical numbers and reset the map kept by the lapic code.
	 */
	for (i = 1; i < ncpus; i++) {
		cpu_data_t	*cpup = cpu_datap(i);
		x86_core_t	*core = cpup->lcpu.core;
		x86_die_t	*die  = cpup->lcpu.die;
		x86_pkg_t	*pkg  = cpup->lcpu.package;

		assert(core != NULL);
		assert(die != NULL);
		assert(pkg != NULL);

		if (cpup->cpu_number != i) {
			kprintf("cpu_datap(%d):%p local apic id 0x%x "
				"remapped from %d\n",
				i, cpup, cpup->cpu_phys_number,
				cpup->cpu_number);
		}
		cpup->cpu_number = i;
		cpup->lcpu.cpu_num = i;
		cpup->lcpu.pnum = cpup->cpu_phys_number;
		lapic_cpu_map(cpup->cpu_phys_number, i);
		x86_set_lcpu_numbers(&cpup->lcpu);
		x86_set_core_numbers(core, &cpup->lcpu);
		x86_set_die_numbers(die, &cpup->lcpu);
		x86_set_pkg_numbers(pkg, &cpup->lcpu);
	}

	validate_topology();

	ml_set_interrupts_enabled(istate);
	TOPO_DBG("cpu_topology_start() LLC is L%d\n", topoParms.LLCDepth + 1);

	/*
	 * Let the CPU Power Management know that the topology is stable.
	 */
	topoParms.stable = TRUE;
	pmCPUStateInit();

	/*
	 * Iterate over all logical cpus finding or creating the affinity set
	 * for their LLC cache. Each affinity set possesses a processor set
	 * into which each logical processor is added.
	 */
	TOPO_DBG("cpu_topology_start() creating affinity sets:\n");
	for (i = 0; i < ncpus; i++) {
		cpu_data_t		*cpup = cpu_datap(i);
		x86_lcpu_t		*lcpup = cpu_to_lcpu(i);
		x86_cpu_cache_t		*LLC_cachep;
		x86_affinity_set_t	*aset;

		LLC_cachep = lcpup->caches[topoParms.LLCDepth];
		assert(LLC_cachep->type == CPU_CACHE_TYPE_UNIF);
		aset = find_cache_affinity(LLC_cachep); 
		if (aset == NULL) {
			aset = (x86_affinity_set_t *) kalloc(sizeof(*aset));
			if (aset == NULL)
				panic("cpu_topology_start() failed aset alloc");
			aset->next = x86_affinities;
			x86_affinities = aset;
			aset->num = x86_affinity_count++;
			aset->cache = LLC_cachep;
			aset->pset = (i == master_cpu) ?
					processor_pset(master_processor) :
					pset_create(pset_node_root());
			if (aset->pset == PROCESSOR_SET_NULL)
				panic("cpu_topology_start: pset_create");
			TOPO_DBG("\tnew set %p(%d) pset %p for cache %p\n",
				aset, aset->num, aset->pset, aset->cache);
		}

		TOPO_DBG("\tprocessor_init set %p(%d) lcpup %p(%d) cpu %p processor %p\n",
			aset, aset->num, lcpup, lcpup->cpu_num, cpup, cpup->cpu_processor);

		if (i != master_cpu)
			processor_init(cpup->cpu_processor, i, aset->pset);

		if (lcpup->core->num_lcpus > 1) {
			if (lcpup->lnum == 0)
				lprim = cpup->cpu_processor;

			processor_meta_init(cpup->cpu_processor, lprim);
		}
	}
}

/* We got a request to start a CPU. Check that this CPU is within the
 * max cpu limit set before we do.
 */
kern_return_t
cpu_topology_start_cpu( int cpunum )
{
	int		ncpus = machine_info.max_cpus;
	int		i = cpunum;

	/* Decide whether to start a CPU, and actually start it */
	TOPO_DBG("cpu_topology_start() processor_start():\n");
	if( i < ncpus)
	{
		TOPO_DBG("\tlcpu %d\n", cpu_datap(i)->cpu_number);
		processor_start(cpu_datap(i)->cpu_processor); 
		return KERN_SUCCESS;
	}
	else
	    return KERN_FAILURE;
}

static int
lapicid_cmp(const void *x, const void *y)
{
	cpu_data_t	*cpu_x = *((cpu_data_t **)(uintptr_t)x);
	cpu_data_t	*cpu_y = *((cpu_data_t **)(uintptr_t)y);

	TOPO_DBG("lapicid_cmp(%p,%p) (%d,%d)\n",
		x, y, cpu_x->cpu_phys_number, cpu_y->cpu_phys_number);
	if (cpu_x->cpu_phys_number < cpu_y->cpu_phys_number)
		return -1;
	if (cpu_x->cpu_phys_number == cpu_y->cpu_phys_number)
		return 0;
	return 1;
}

static x86_affinity_set_t *
find_cache_affinity(x86_cpu_cache_t *l2_cachep)
{
	x86_affinity_set_t	*aset;

	for (aset = x86_affinities; aset != NULL; aset = aset->next) {
		if (l2_cachep == aset->cache)
			break;
	}
	return aset;			
}

int
ml_get_max_affinity_sets(void)
{
	return x86_affinity_count;
}

processor_set_t
ml_affinity_to_pset(uint32_t affinity_num) 
{
	x86_affinity_set_t	*aset;

	for (aset = x86_affinities; aset != NULL; aset = aset->next) {
		if (affinity_num == aset->num)
			break;
	}
	return (aset == NULL) ? PROCESSOR_SET_NULL : aset->pset;
}

uint64_t
ml_cpu_cache_size(unsigned int level)
{
	x86_cpu_cache_t	*cachep;

	if (level == 0) {
		return machine_info.max_mem;
	} else if ( 1 <= level && level <= MAX_CACHE_DEPTH) {
		cachep = current_cpu_datap()->lcpu.caches[level-1];
		return cachep ? cachep->cache_size : 0;
	} else {
		return 0;
	}
}

uint64_t
ml_cpu_cache_sharing(unsigned int level)
{
	x86_cpu_cache_t	*cachep;

	if (level == 0) {
		return machine_info.max_cpus;
	} else if ( 1 <= level && level <= MAX_CACHE_DEPTH) {
		cachep = current_cpu_datap()->lcpu.caches[level-1];
		return cachep ? cachep->nlcpus : 0;
	} else {
		return 0;
	}
}