linux-sg2042/arch/s390/numa/mode_emu.c

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/*
* NUMA support for s390
*
* NUMA emulation (aka fake NUMA) distributes the available memory to nodes
* without using real topology information about the physical memory of the
* machine.
*
* It distributes the available CPUs to nodes while respecting the original
* machine topology information. This is done by trying to avoid to separate
* CPUs which reside on the same book or even on the same MC.
*
* Because the current Linux scheduler code requires a stable cpu to node
* mapping, cores are pinned to nodes when the first CPU thread is set online.
*
* Copyright IBM Corp. 2015
*/
#define KMSG_COMPONENT "numa_emu"
#define pr_fmt(fmt) KMSG_COMPONENT ": " fmt
#include <linux/kernel.h>
#include <linux/cpumask.h>
#include <linux/memblock.h>
#include <linux/node.h>
#include <linux/memory.h>
#include <asm/smp.h>
#include <asm/topology.h>
#include "numa_mode.h"
#include "toptree.h"
/* Distances between the different system components */
#define DIST_EMPTY 0
#define DIST_CORE 1
#define DIST_MC 2
#define DIST_BOOK 3
#define DIST_MAX 4
/* Node distance reported to common code */
#define EMU_NODE_DIST 10
/* Node ID for free (not yet pinned) cores */
#define NODE_ID_FREE -1
/* Different levels of toptree */
enum toptree_level {CORE, MC, BOOK, NODE, TOPOLOGY};
/* The two toptree IDs */
enum {TOPTREE_ID_PHYS, TOPTREE_ID_NUMA};
/* Number of NUMA nodes */
static int emu_nodes = 1;
/* NUMA stripe size */
static unsigned long emu_size;
/* Pinned core to node mapping */
static int cores_to_node_id[CONFIG_NR_CPUS];
/* Total number of pinned cores */
static int cores_total;
/* Number of cores per node without extra cores */
static int cores_per_node_target;
/* Number of cores pinned to node */
static int cores_per_node[MAX_NUMNODES];
/*
* Pin a core to a node
*/
static void pin_core_to_node(int core_id, int node_id)
{
if (cores_to_node_id[core_id] == NODE_ID_FREE) {
cores_per_node[node_id]++;
cores_to_node_id[core_id] = node_id;
cores_total++;
} else {
WARN_ON(cores_to_node_id[core_id] != node_id);
}
}
/*
* Number of pinned cores of a node
*/
static int cores_pinned(struct toptree *node)
{
return cores_per_node[node->id];
}
/*
* ID of the node where the core is pinned (or NODE_ID_FREE)
*/
static int core_pinned_to_node_id(struct toptree *core)
{
return cores_to_node_id[core->id];
}
/*
* Number of cores in the tree that are not yet pinned
*/
static int cores_free(struct toptree *tree)
{
struct toptree *core;
int count = 0;
toptree_for_each(core, tree, CORE) {
if (core_pinned_to_node_id(core) == NODE_ID_FREE)
count++;
}
return count;
}
/*
* Return node of core
*/
static struct toptree *core_node(struct toptree *core)
{
return core->parent->parent->parent;
}
/*
* Return book of core
*/
static struct toptree *core_book(struct toptree *core)
{
return core->parent->parent;
}
/*
* Return mc of core
*/
static struct toptree *core_mc(struct toptree *core)
{
return core->parent;
}
/*
* Distance between two cores
*/
static int dist_core_to_core(struct toptree *core1, struct toptree *core2)
{
if (core_book(core1)->id != core_book(core2)->id)
return DIST_BOOK;
if (core_mc(core1)->id != core_mc(core2)->id)
return DIST_MC;
/* Same core or sibling on same MC */
return DIST_CORE;
}
/*
* Distance of a node to a core
*/
static int dist_node_to_core(struct toptree *node, struct toptree *core)
{
struct toptree *core_node;
int dist_min = DIST_MAX;
toptree_for_each(core_node, node, CORE)
dist_min = min(dist_min, dist_core_to_core(core_node, core));
return dist_min == DIST_MAX ? DIST_EMPTY : dist_min;
}
/*
* Unify will delete empty nodes, therefore recreate nodes.
*/
static void toptree_unify_tree(struct toptree *tree)
{
int nid;
toptree_unify(tree);
for (nid = 0; nid < emu_nodes; nid++)
toptree_get_child(tree, nid);
}
/*
* Find the best/nearest node for a given core and ensure that no node
* gets more than "cores_per_node_target + extra" cores.
*/
static struct toptree *node_for_core(struct toptree *numa, struct toptree *core,
int extra)
{
struct toptree *node, *node_best = NULL;
int dist_cur, dist_best;
dist_best = DIST_MAX;
node_best = NULL;
toptree_for_each(node, numa, NODE) {
/* Already pinned cores must use their nodes */
if (core_pinned_to_node_id(core) == node->id) {
node_best = node;
break;
}
/* Skip nodes that already have enough cores */
if (cores_pinned(node) >= cores_per_node_target + extra)
continue;
dist_cur = dist_node_to_core(node, core);
if (dist_cur < dist_best) {
dist_best = dist_cur;
node_best = node;
}
}
return node_best;
}
/*
* Find the best node for each core with respect to "extra" core count
*/
static void toptree_to_numa_single(struct toptree *numa, struct toptree *phys,
int extra)
{
struct toptree *node, *core, *tmp;
toptree_for_each_safe(core, tmp, phys, CORE) {
node = node_for_core(numa, core, extra);
if (!node)
return;
toptree_move(core, node);
pin_core_to_node(core->id, node->id);
}
}
/*
* Move structures of given level to specified NUMA node
*/
static void move_level_to_numa_node(struct toptree *node, struct toptree *phys,
enum toptree_level level, bool perfect)
{
struct toptree *cur, *tmp;
int cores_free;
toptree_for_each_safe(cur, tmp, phys, level) {
cores_free = cores_per_node_target - toptree_count(node, CORE);
if (perfect) {
if (cores_free == toptree_count(cur, CORE))
toptree_move(cur, node);
} else {
if (cores_free >= toptree_count(cur, CORE))
toptree_move(cur, node);
}
}
}
/*
* Move structures of a given level to NUMA nodes. If "perfect" is specified
* move only perfectly fitting structures. Otherwise move also smaller
* than needed structures.
*/
static void move_level_to_numa(struct toptree *numa, struct toptree *phys,
enum toptree_level level, bool perfect)
{
struct toptree *node;
toptree_for_each(node, numa, NODE)
move_level_to_numa_node(node, phys, level, perfect);
}
/*
* For the first run try to move the big structures
*/
static void toptree_to_numa_first(struct toptree *numa, struct toptree *phys)
{
struct toptree *core;
/* Always try to move perfectly fitting structures first */
move_level_to_numa(numa, phys, BOOK, true);
move_level_to_numa(numa, phys, BOOK, false);
move_level_to_numa(numa, phys, MC, true);
move_level_to_numa(numa, phys, MC, false);
/* Now pin all the moved cores */
toptree_for_each(core, numa, CORE)
pin_core_to_node(core->id, core_node(core)->id);
}
/*
* Allocate new topology and create required nodes
*/
static struct toptree *toptree_new(int id, int nodes)
{
struct toptree *tree;
int nid;
tree = toptree_alloc(TOPOLOGY, id);
if (!tree)
goto fail;
for (nid = 0; nid < nodes; nid++) {
if (!toptree_get_child(tree, nid))
goto fail;
}
return tree;
fail:
panic("NUMA emulation could not allocate topology");
}
/*
* Move cores from physical topology into NUMA target topology
* and try to keep as much of the physical topology as possible.
*/
static struct toptree *toptree_to_numa(struct toptree *phys)
{
static int first = 1;
struct toptree *numa;
cores_per_node_target = (cores_total + cores_free(phys)) / emu_nodes;
numa = toptree_new(TOPTREE_ID_NUMA, emu_nodes);
if (first) {
toptree_to_numa_first(numa, phys);
first = 0;
}
toptree_to_numa_single(numa, phys, 0);
toptree_to_numa_single(numa, phys, 1);
toptree_unify_tree(numa);
WARN_ON(cpumask_weight(&phys->mask));
return numa;
}
/*
* Create a toptree out of the physical topology that we got from the hypervisor
*/
static struct toptree *toptree_from_topology(void)
{
struct toptree *phys, *node, *book, *mc, *core;
struct cpu_topology_s390 *top;
int cpu;
phys = toptree_new(TOPTREE_ID_PHYS, 1);
for_each_online_cpu(cpu) {
top = &per_cpu(cpu_topology, cpu);
node = toptree_get_child(phys, 0);
book = toptree_get_child(node, top->book_id);
mc = toptree_get_child(book, top->socket_id);
core = toptree_get_child(mc, top->core_id);
if (!book || !mc || !core)
panic("NUMA emulation could not allocate memory");
cpumask_set_cpu(cpu, &core->mask);
toptree_update_mask(mc);
}
return phys;
}
/*
* Add toptree core to topology and create correct CPU masks
*/
static void topology_add_core(struct toptree *core)
{
struct cpu_topology_s390 *top;
int cpu;
for_each_cpu(cpu, &core->mask) {
top = &per_cpu(cpu_topology, cpu);
cpumask_copy(&top->thread_mask, &core->mask);
cpumask_copy(&top->core_mask, &core_mc(core)->mask);
cpumask_copy(&top->book_mask, &core_book(core)->mask);
cpumask_set_cpu(cpu, node_to_cpumask_map[core_node(core)->id]);
top->node_id = core_node(core)->id;
}
}
/*
* Apply toptree to topology and create CPU masks
*/
static void toptree_to_topology(struct toptree *numa)
{
struct toptree *core;
int i;
/* Clear all node masks */
for (i = 0; i < MAX_NUMNODES; i++)
cpumask_clear(node_to_cpumask_map[i]);
/* Rebuild all masks */
toptree_for_each(core, numa, CORE)
topology_add_core(core);
}
/*
* Show the node to core mapping
*/
static void print_node_to_core_map(void)
{
int nid, cid;
if (!numa_debug_enabled)
return;
printk(KERN_DEBUG "NUMA node to core mapping\n");
for (nid = 0; nid < emu_nodes; nid++) {
printk(KERN_DEBUG " node %3d: ", nid);
for (cid = 0; cid < ARRAY_SIZE(cores_to_node_id); cid++) {
if (cores_to_node_id[cid] == nid)
printk(KERN_CONT "%d ", cid);
}
printk(KERN_CONT "\n");
}
}
/*
* Transfer physical topology into a NUMA topology and modify CPU masks
* according to the NUMA topology.
*
* This function is called under the CPU hotplug lock.
*/
static void emu_update_cpu_topology(void)
{
struct toptree *phys, *numa;
phys = toptree_from_topology();
numa = toptree_to_numa(phys);
toptree_free(phys);
toptree_to_topology(numa);
toptree_free(numa);
print_node_to_core_map();
}
/*
* If emu_size is not set, use CONFIG_EMU_SIZE. Then round to minimum
* alignment (needed for memory hotplug).
*/
static unsigned long emu_setup_size_adjust(unsigned long size)
{
size = size ? : CONFIG_EMU_SIZE;
size = roundup(size, memory_block_size_bytes());
return size;
}
/*
* If we have not enough memory for the specified nodes, reduce the node count.
*/
static int emu_setup_nodes_adjust(int nodes)
{
int nodes_max;
nodes_max = memblock.memory.total_size / emu_size;
nodes_max = max(nodes_max, 1);
if (nodes_max >= nodes)
return nodes;
pr_warn("Not enough memory for %d nodes, reducing node count\n", nodes);
return nodes_max;
}
/*
* Early emu setup
*/
static void emu_setup(void)
{
int i;
emu_size = emu_setup_size_adjust(emu_size);
emu_nodes = emu_setup_nodes_adjust(emu_nodes);
for (i = 0; i < ARRAY_SIZE(cores_to_node_id); i++)
cores_to_node_id[i] = NODE_ID_FREE;
pr_info("Creating %d nodes with memory stripe size %ld MB\n",
emu_nodes, emu_size >> 20);
}
/*
* Return node id for given page number
*/
static int emu_pfn_to_nid(unsigned long pfn)
{
return (pfn / (emu_size >> PAGE_SHIFT)) % emu_nodes;
}
/*
* Return stripe size
*/
static unsigned long emu_align(void)
{
return emu_size;
}
/*
* Return distance between two nodes
*/
static int emu_distance(int node1, int node2)
{
return (node1 != node2) * EMU_NODE_DIST;
}
/*
* Define callbacks for generic s390 NUMA infrastructure
*/
const struct numa_mode numa_mode_emu = {
.name = "emu",
.setup = emu_setup,
.update_cpu_topology = emu_update_cpu_topology,
.__pfn_to_nid = emu_pfn_to_nid,
.align = emu_align,
.distance = emu_distance,
};
/*
* Kernel parameter: emu_nodes=<n>
*/
static int __init early_parse_emu_nodes(char *p)
{
int count;
if (kstrtoint(p, 0, &count) != 0 || count <= 0)
return 0;
if (count <= 0)
return 0;
emu_nodes = min(count, MAX_NUMNODES);
return 0;
}
early_param("emu_nodes", early_parse_emu_nodes);
/*
* Kernel parameter: emu_size=[<n>[k|M|G|T]]
*/
static int __init early_parse_emu_size(char *p)
{
emu_size = memparse(p, NULL);
return 0;
}
early_param("emu_size", early_parse_emu_size);