arch/ia64: remove references to cpu_*_map

[deliverable/linux.git] / arch / ia64 / kernel / topology.c

/*
 * 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.
 *
 * This file contains NUMA specific variables and functions which can
 * be split away from DISCONTIGMEM and are used on NUMA machines with
 * contiguous memory.
 *              2002/08/07 Erich Focht <efocht@ess.nec.de>
 * Populate cpu entries in sysfs for non-numa systems as well
 *      Intel Corporation - Ashok Raj
 * 02/27/2006 Zhang, Yanmin
 *      Populate cpu cache entries in sysfs for cpu cache info
 */

#include <linux/cpu.h>
#include <linux/kernel.h>
#include <linux/mm.h>
#include <linux/node.h>
#include <linux/slab.h>
#include <linux/init.h>
#include <linux/bootmem.h>
#include <linux/nodemask.h>
#include <linux/notifier.h>
#include <linux/export.h>
#include <asm/mmzone.h>
#include <asm/numa.h>
#include <asm/cpu.h>

static struct ia64_cpu *sysfs_cpus;

void arch_fix_phys_package_id(int num, u32 slot)
{
#ifdef CONFIG_SMP
        if (cpu_data(num)->socket_id == -1)
                cpu_data(num)->socket_id = slot;
#endif
}
EXPORT_SYMBOL_GPL(arch_fix_phys_package_id);


#ifdef CONFIG_HOTPLUG_CPU
int __ref arch_register_cpu(int num)
{
#ifdef CONFIG_ACPI
        /*
         * If CPEI can be re-targeted or if this is not
         * CPEI target, then it is hotpluggable
         */
        if (can_cpei_retarget() || !is_cpu_cpei_target(num))
                sysfs_cpus[num].cpu.hotpluggable = 1;
        map_cpu_to_node(num, node_cpuid[num].nid);
#endif
        return register_cpu(&sysfs_cpus[num].cpu, num);
}
EXPORT_SYMBOL(arch_register_cpu);

void __ref arch_unregister_cpu(int num)
{
        unregister_cpu(&sysfs_cpus[num].cpu);
#ifdef CONFIG_ACPI
        unmap_cpu_from_node(num, cpu_to_node(num));
#endif
}
EXPORT_SYMBOL(arch_unregister_cpu);
#else
static int __init arch_register_cpu(int num)
{
        return register_cpu(&sysfs_cpus[num].cpu, num);
}
#endif /*CONFIG_HOTPLUG_CPU*/


static int __init topology_init(void)
{
        int i, err = 0;

#ifdef CONFIG_NUMA
        /*
         * MCD - Do we want to register all ONLINE nodes, or all POSSIBLE nodes?
         */
        for_each_online_node(i) {
                if ((err = register_one_node(i)))
                        goto out;
        }
#endif

        sysfs_cpus = kzalloc(sizeof(struct ia64_cpu) * NR_CPUS, GFP_KERNEL);
        if (!sysfs_cpus)
                panic("kzalloc in topology_init failed - NR_CPUS too big?");

        for_each_present_cpu(i) {
                if((err = arch_register_cpu(i)))
                        goto out;
        }
out:
        return err;
}

subsys_initcall(topology_init);


/*
 * Export cpu cache information through sysfs
 */

/*
 *  A bunch of string array to get pretty printing
 */
static const char *cache_types[] = {
        "",                     /* not used */
        "Instruction",
        "Data",
        "Unified"       /* unified */
};

static const char *cache_mattrib[]={
        "WriteThrough",
        "WriteBack",
        "",             /* reserved */
        ""              /* reserved */
};

struct cache_info {
        pal_cache_config_info_t cci;
        cpumask_t shared_cpu_map;
        int level;
        int type;
        struct kobject kobj;
};

struct cpu_cache_info {
        struct cache_info *cache_leaves;
        int     num_cache_leaves;
        struct kobject kobj;
};

static struct cpu_cache_info    all_cpu_cache_info[NR_CPUS] __cpuinitdata;
#define LEAF_KOBJECT_PTR(x,y)    (&all_cpu_cache_info[x].cache_leaves[y])

#ifdef CONFIG_SMP
static void __cpuinit cache_shared_cpu_map_setup( unsigned int cpu,
                struct cache_info * this_leaf)
{
        pal_cache_shared_info_t csi;
        int num_shared, i = 0;
        unsigned int j;

        if (cpu_data(cpu)->threads_per_core <= 1 &&
                cpu_data(cpu)->cores_per_socket <= 1) {
                cpu_set(cpu, this_leaf->shared_cpu_map);
                return;
        }

        if (ia64_pal_cache_shared_info(this_leaf->level,
                                        this_leaf->type,
                                        0,
                                        &csi) != PAL_STATUS_SUCCESS)
                return;

        num_shared = (int) csi.num_shared;
        do {
                for_each_possible_cpu(j)
                        if (cpu_data(cpu)->socket_id == cpu_data(j)->socket_id
                                && cpu_data(j)->core_id == csi.log1_cid
                                && cpu_data(j)->thread_id == csi.log1_tid)
                                cpu_set(j, this_leaf->shared_cpu_map);

                i++;
        } while (i < num_shared &&
                ia64_pal_cache_shared_info(this_leaf->level,
                                this_leaf->type,
                                i,
                                &csi) == PAL_STATUS_SUCCESS);
}
#else
static void __cpuinit cache_shared_cpu_map_setup(unsigned int cpu,
                struct cache_info * this_leaf)
{
        cpu_set(cpu, this_leaf->shared_cpu_map);
        return;
}
#endif

static ssize_t show_coherency_line_size(struct cache_info *this_leaf,
                                        char *buf)
{
        return sprintf(buf, "%u\n", 1 << this_leaf->cci.pcci_line_size);
}

static ssize_t show_ways_of_associativity(struct cache_info *this_leaf,
                                        char *buf)
{
        return sprintf(buf, "%u\n", this_leaf->cci.pcci_assoc);
}

static ssize_t show_attributes(struct cache_info *this_leaf, char *buf)
{
        return sprintf(buf,
                        "%s\n",
                        cache_mattrib[this_leaf->cci.pcci_cache_attr]);
}

static ssize_t show_size(struct cache_info *this_leaf, char *buf)
{
        return sprintf(buf, "%uK\n", this_leaf->cci.pcci_cache_size / 1024);
}

static ssize_t show_number_of_sets(struct cache_info *this_leaf, char *buf)
{
        unsigned number_of_sets = this_leaf->cci.pcci_cache_size;
        number_of_sets /= this_leaf->cci.pcci_assoc;
        number_of_sets /= 1 << this_leaf->cci.pcci_line_size;

        return sprintf(buf, "%u\n", number_of_sets);
}

static ssize_t show_shared_cpu_map(struct cache_info *this_leaf, char *buf)
{
        ssize_t len;
        cpumask_t shared_cpu_map;

        cpumask_and(&shared_cpu_map,
                                &this_leaf->shared_cpu_map, cpu_online_mask);
        len = cpumask_scnprintf(buf, NR_CPUS+1, &shared_cpu_map);
        len += sprintf(buf+len, "\n");
        return len;
}

static ssize_t show_type(struct cache_info *this_leaf, char *buf)
{
        int type = this_leaf->type + this_leaf->cci.pcci_unified;
        return sprintf(buf, "%s\n", cache_types[type]);
}

static ssize_t show_level(struct cache_info *this_leaf, char *buf)
{
        return sprintf(buf, "%u\n", this_leaf->level);
}

struct cache_attr {
        struct attribute attr;
        ssize_t (*show)(struct cache_info *, char *);
        ssize_t (*store)(struct cache_info *, const char *, size_t count);
};

#ifdef define_one_ro
        #undef define_one_ro
#endif
#define define_one_ro(_name) \
        static struct cache_attr _name = \
__ATTR(_name, 0444, show_##_name, NULL)

define_one_ro(level);
define_one_ro(type);
define_one_ro(coherency_line_size);
define_one_ro(ways_of_associativity);
define_one_ro(size);
define_one_ro(number_of_sets);
define_one_ro(shared_cpu_map);
define_one_ro(attributes);

static struct attribute * cache_default_attrs[] = {
        &type.attr,
        &level.attr,
        &coherency_line_size.attr,
        &ways_of_associativity.attr,
        &attributes.attr,
        &size.attr,
        &number_of_sets.attr,
        &shared_cpu_map.attr,
        NULL
};

#define to_object(k) container_of(k, struct cache_info, kobj)
#define to_attr(a) container_of(a, struct cache_attr, attr)

static ssize_t cache_show(struct kobject * kobj, struct attribute * attr, char * buf)
{
        struct cache_attr *fattr = to_attr(attr);
        struct cache_info *this_leaf = to_object(kobj);
        ssize_t ret;

        ret = fattr->show ? fattr->show(this_leaf, buf) : 0;
        return ret;
}

static const struct sysfs_ops cache_sysfs_ops = {
        .show   = cache_show
};

static struct kobj_type cache_ktype = {
        .sysfs_ops      = &cache_sysfs_ops,
        .default_attrs  = cache_default_attrs,
};

static struct kobj_type cache_ktype_percpu_entry = {
        .sysfs_ops      = &cache_sysfs_ops,
};

static void __cpuinit cpu_cache_sysfs_exit(unsigned int cpu)
{
        kfree(all_cpu_cache_info[cpu].cache_leaves);
        all_cpu_cache_info[cpu].cache_leaves = NULL;
        all_cpu_cache_info[cpu].num_cache_leaves = 0;
        memset(&all_cpu_cache_info[cpu].kobj, 0, sizeof(struct kobject));
        return;
}

static int __cpuinit cpu_cache_sysfs_init(unsigned int cpu)
{
        unsigned long i, levels, unique_caches;
        pal_cache_config_info_t cci;
        int j;
        long status;
        struct cache_info *this_cache;
        int num_cache_leaves = 0;

        if ((status = ia64_pal_cache_summary(&levels, &unique_caches)) != 0) {
                printk(KERN_ERR "ia64_pal_cache_summary=%ld\n", status);
                return -1;
        }

        this_cache=kzalloc(sizeof(struct cache_info)*unique_caches,
                        GFP_KERNEL);
        if (this_cache == NULL)
                return -ENOMEM;

        for (i=0; i < levels; i++) {
                for (j=2; j >0 ; j--) {
                        if ((status=ia64_pal_cache_config_info(i,j, &cci)) !=
                                        PAL_STATUS_SUCCESS)
                                continue;

                        this_cache[num_cache_leaves].cci = cci;
                        this_cache[num_cache_leaves].level = i + 1;
                        this_cache[num_cache_leaves].type = j;

                        cache_shared_cpu_map_setup(cpu,
                                        &this_cache[num_cache_leaves]);
                        num_cache_leaves ++;
                }
        }

        all_cpu_cache_info[cpu].cache_leaves = this_cache;
        all_cpu_cache_info[cpu].num_cache_leaves = num_cache_leaves;

        memset(&all_cpu_cache_info[cpu].kobj, 0, sizeof(struct kobject));

        return 0;
}

/* Add cache interface for CPU device */
static int __cpuinit cache_add_dev(struct device * sys_dev)
{
        unsigned int cpu = sys_dev->id;
        unsigned long i, j;
        struct cache_info *this_object;
        int retval = 0;
        cpumask_t oldmask;

        if (all_cpu_cache_info[cpu].kobj.parent)
                return 0;

        oldmask = current->cpus_allowed;
        retval = set_cpus_allowed_ptr(current, cpumask_of(cpu));
        if (unlikely(retval))
                return retval;

        retval = cpu_cache_sysfs_init(cpu);
        set_cpus_allowed_ptr(current, &oldmask);
        if (unlikely(retval < 0))
                return retval;

        retval = kobject_init_and_add(&all_cpu_cache_info[cpu].kobj,
                                      &cache_ktype_percpu_entry, &sys_dev->kobj,
                                      "%s", "cache");
        if (unlikely(retval < 0)) {
                cpu_cache_sysfs_exit(cpu);
                return retval;
        }

        for (i = 0; i < all_cpu_cache_info[cpu].num_cache_leaves; i++) {
                this_object = LEAF_KOBJECT_PTR(cpu,i);
                retval = kobject_init_and_add(&(this_object->kobj),
                                              &cache_ktype,
                                              &all_cpu_cache_info[cpu].kobj,
                                              "index%1lu", i);
                if (unlikely(retval)) {
                        for (j = 0; j < i; j++) {
                                kobject_put(&(LEAF_KOBJECT_PTR(cpu,j)->kobj));
                        }
                        kobject_put(&all_cpu_cache_info[cpu].kobj);
                        cpu_cache_sysfs_exit(cpu);
                        return retval;
                }
                kobject_uevent(&(this_object->kobj), KOBJ_ADD);
        }
        kobject_uevent(&all_cpu_cache_info[cpu].kobj, KOBJ_ADD);
        return retval;
}

/* Remove cache interface for CPU device */
static int __cpuinit cache_remove_dev(struct device * sys_dev)
{
        unsigned int cpu = sys_dev->id;
        unsigned long i;

        for (i = 0; i < all_cpu_cache_info[cpu].num_cache_leaves; i++)
                kobject_put(&(LEAF_KOBJECT_PTR(cpu,i)->kobj));

        if (all_cpu_cache_info[cpu].kobj.parent) {
                kobject_put(&all_cpu_cache_info[cpu].kobj);
                memset(&all_cpu_cache_info[cpu].kobj,
                        0,
                        sizeof(struct kobject));
        }

        cpu_cache_sysfs_exit(cpu);

        return 0;
}

/*
 * When a cpu is hot-plugged, do a check and initiate
 * cache kobject if necessary
 */
static int __cpuinit cache_cpu_callback(struct notifier_block *nfb,
                unsigned long action, void *hcpu)
{
        unsigned int cpu = (unsigned long)hcpu;
        struct device *sys_dev;

        sys_dev = get_cpu_device(cpu);
        switch (action) {
        case CPU_ONLINE:
        case CPU_ONLINE_FROZEN:
                cache_add_dev(sys_dev);
                break;
        case CPU_DEAD:
        case CPU_DEAD_FROZEN:
                cache_remove_dev(sys_dev);
                break;
        }
        return NOTIFY_OK;
}

static struct notifier_block __cpuinitdata cache_cpu_notifier =
{
        .notifier_call = cache_cpu_callback
};

static int __init cache_sysfs_init(void)
{
        int i;

        for_each_online_cpu(i) {
                struct device *sys_dev = get_cpu_device((unsigned int)i);
                cache_add_dev(sys_dev);
        }

        register_hotcpu_notifier(&cache_cpu_notifier);

        return 0;
}

device_initcall(cache_sysfs_init);