linux_dsm_epyc7002/arch/x86/platform/uv/tlb_uv.c
Cliff Wickman 77ed23f8d9 x86: Fix UV BAU for non-consecutive nasids
This is a fix for the SGI Altix-UV Broadcast Assist Unit code,
which is used for TLB flushing.

Certain hardware configurations (that customers are ordering)
cause nasids (numa address space id's) to be non-consecutive.
Specifically, once you have more than 4 blades in a IRU
(Individual Rack Unit - or 1/2 rack) but less than the maximum
of 16, the nasid numbering becomes non-consecutive.  This
currently results in a 'catastrophic error' (CATERR) detected by
the firmware during OS boot.  The BAU is generating an 'INTD'
request that is targeting a non-existent nasid value. Such
configurations may also occur when a blade is configured off
because of hardware errors. (There is one UV hub per blade.)

This patch is required to support such configurations.

The problem with the tlb_uv.c code is that is using the
consecutive hub numbers as indices to the BAU distribution bit
map. These are simply the ordinal position of the hub or blade
within its partition.  It should be using physical node numbers
(pnodes), which correspond to the physical nasid values. Use of
the hub number only works as long as the nasids in the partition
are consecutive and increase with a stride of 1.

This patch changes the index to be the pnode number, thus
allowing nasids to be non-consecutive.
It also provides a table in local memory for each cpu to
translate target cpu number to target pnode and nasid.
And it improves naming to properly reflect 'node' and 'uvhub'
versus 'nasid'.

Signed-off-by: Cliff Wickman <cpw@sgi.com>
Cc: <stable@kernel.org>
Link: http://lkml.kernel.org/r/E1QJmxX-0002Mz-Fk@eag09.americas.sgi.com
Signed-off-by: Ingo Molnar <mingo@elte.hu>
2011-05-12 23:45:42 +02:00

1710 lines
46 KiB
C

/*
* SGI UltraViolet TLB flush routines.
*
* (c) 2008-2010 Cliff Wickman <cpw@sgi.com>, SGI.
*
* This code is released under the GNU General Public License version 2 or
* later.
*/
#include <linux/seq_file.h>
#include <linux/proc_fs.h>
#include <linux/debugfs.h>
#include <linux/kernel.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <asm/mmu_context.h>
#include <asm/uv/uv.h>
#include <asm/uv/uv_mmrs.h>
#include <asm/uv/uv_hub.h>
#include <asm/uv/uv_bau.h>
#include <asm/apic.h>
#include <asm/idle.h>
#include <asm/tsc.h>
#include <asm/irq_vectors.h>
#include <asm/timer.h>
/* timeouts in nanoseconds (indexed by UVH_AGING_PRESCALE_SEL urgency7 30:28) */
static int timeout_base_ns[] = {
20,
160,
1280,
10240,
81920,
655360,
5242880,
167772160
};
static int timeout_us;
static int nobau;
static int baudisabled;
static spinlock_t disable_lock;
static cycles_t congested_cycles;
/* tunables: */
static int max_bau_concurrent = MAX_BAU_CONCURRENT;
static int max_bau_concurrent_constant = MAX_BAU_CONCURRENT;
static int plugged_delay = PLUGGED_DELAY;
static int plugsb4reset = PLUGSB4RESET;
static int timeoutsb4reset = TIMEOUTSB4RESET;
static int ipi_reset_limit = IPI_RESET_LIMIT;
static int complete_threshold = COMPLETE_THRESHOLD;
static int congested_response_us = CONGESTED_RESPONSE_US;
static int congested_reps = CONGESTED_REPS;
static int congested_period = CONGESTED_PERIOD;
static struct dentry *tunables_dir;
static struct dentry *tunables_file;
static int __init setup_nobau(char *arg)
{
nobau = 1;
return 0;
}
early_param("nobau", setup_nobau);
/* base pnode in this partition */
static int uv_partition_base_pnode __read_mostly;
/* position of pnode (which is nasid>>1): */
static int uv_nshift __read_mostly;
static unsigned long uv_mmask __read_mostly;
static DEFINE_PER_CPU(struct ptc_stats, ptcstats);
static DEFINE_PER_CPU(struct bau_control, bau_control);
static DEFINE_PER_CPU(cpumask_var_t, uv_flush_tlb_mask);
/*
* Determine the first node on a uvhub. 'Nodes' are used for kernel
* memory allocation.
*/
static int __init uvhub_to_first_node(int uvhub)
{
int node, b;
for_each_online_node(node) {
b = uv_node_to_blade_id(node);
if (uvhub == b)
return node;
}
return -1;
}
/*
* Determine the apicid of the first cpu on a uvhub.
*/
static int __init uvhub_to_first_apicid(int uvhub)
{
int cpu;
for_each_present_cpu(cpu)
if (uvhub == uv_cpu_to_blade_id(cpu))
return per_cpu(x86_cpu_to_apicid, cpu);
return -1;
}
/*
* Free a software acknowledge hardware resource by clearing its Pending
* bit. This will return a reply to the sender.
* If the message has timed out, a reply has already been sent by the
* hardware but the resource has not been released. In that case our
* clear of the Timeout bit (as well) will free the resource. No reply will
* be sent (the hardware will only do one reply per message).
*/
static inline void uv_reply_to_message(struct msg_desc *mdp,
struct bau_control *bcp)
{
unsigned long dw;
struct bau_payload_queue_entry *msg;
msg = mdp->msg;
if (!msg->canceled) {
dw = (msg->sw_ack_vector << UV_SW_ACK_NPENDING) |
msg->sw_ack_vector;
uv_write_local_mmr(
UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE_ALIAS, dw);
}
msg->replied_to = 1;
msg->sw_ack_vector = 0;
}
/*
* Process the receipt of a RETRY message
*/
static inline void uv_bau_process_retry_msg(struct msg_desc *mdp,
struct bau_control *bcp)
{
int i;
int cancel_count = 0;
int slot2;
unsigned long msg_res;
unsigned long mmr = 0;
struct bau_payload_queue_entry *msg;
struct bau_payload_queue_entry *msg2;
struct ptc_stats *stat;
msg = mdp->msg;
stat = bcp->statp;
stat->d_retries++;
/*
* cancel any message from msg+1 to the retry itself
*/
for (msg2 = msg+1, i = 0; i < DEST_Q_SIZE; msg2++, i++) {
if (msg2 > mdp->va_queue_last)
msg2 = mdp->va_queue_first;
if (msg2 == msg)
break;
/* same conditions for cancellation as uv_do_reset */
if ((msg2->replied_to == 0) && (msg2->canceled == 0) &&
(msg2->sw_ack_vector) && ((msg2->sw_ack_vector &
msg->sw_ack_vector) == 0) &&
(msg2->sending_cpu == msg->sending_cpu) &&
(msg2->msg_type != MSG_NOOP)) {
slot2 = msg2 - mdp->va_queue_first;
mmr = uv_read_local_mmr
(UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE);
msg_res = msg2->sw_ack_vector;
/*
* This is a message retry; clear the resources held
* by the previous message only if they timed out.
* If it has not timed out we have an unexpected
* situation to report.
*/
if (mmr & (msg_res << UV_SW_ACK_NPENDING)) {
/*
* is the resource timed out?
* make everyone ignore the cancelled message.
*/
msg2->canceled = 1;
stat->d_canceled++;
cancel_count++;
uv_write_local_mmr(
UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE_ALIAS,
(msg_res << UV_SW_ACK_NPENDING) |
msg_res);
}
}
}
if (!cancel_count)
stat->d_nocanceled++;
}
/*
* Do all the things a cpu should do for a TLB shootdown message.
* Other cpu's may come here at the same time for this message.
*/
static void uv_bau_process_message(struct msg_desc *mdp,
struct bau_control *bcp)
{
int msg_ack_count;
short socket_ack_count = 0;
struct ptc_stats *stat;
struct bau_payload_queue_entry *msg;
struct bau_control *smaster = bcp->socket_master;
/*
* This must be a normal message, or retry of a normal message
*/
msg = mdp->msg;
stat = bcp->statp;
if (msg->address == TLB_FLUSH_ALL) {
local_flush_tlb();
stat->d_alltlb++;
} else {
__flush_tlb_one(msg->address);
stat->d_onetlb++;
}
stat->d_requestee++;
/*
* One cpu on each uvhub has the additional job on a RETRY
* of releasing the resource held by the message that is
* being retried. That message is identified by sending
* cpu number.
*/
if (msg->msg_type == MSG_RETRY && bcp == bcp->uvhub_master)
uv_bau_process_retry_msg(mdp, bcp);
/*
* This is a sw_ack message, so we have to reply to it.
* Count each responding cpu on the socket. This avoids
* pinging the count's cache line back and forth between
* the sockets.
*/
socket_ack_count = atomic_add_short_return(1, (struct atomic_short *)
&smaster->socket_acknowledge_count[mdp->msg_slot]);
if (socket_ack_count == bcp->cpus_in_socket) {
/*
* Both sockets dump their completed count total into
* the message's count.
*/
smaster->socket_acknowledge_count[mdp->msg_slot] = 0;
msg_ack_count = atomic_add_short_return(socket_ack_count,
(struct atomic_short *)&msg->acknowledge_count);
if (msg_ack_count == bcp->cpus_in_uvhub) {
/*
* All cpus in uvhub saw it; reply
*/
uv_reply_to_message(mdp, bcp);
}
}
return;
}
/*
* Determine the first cpu on a uvhub.
*/
static int uvhub_to_first_cpu(int uvhub)
{
int cpu;
for_each_present_cpu(cpu)
if (uvhub == uv_cpu_to_blade_id(cpu))
return cpu;
return -1;
}
/*
* Last resort when we get a large number of destination timeouts is
* to clear resources held by a given cpu.
* Do this with IPI so that all messages in the BAU message queue
* can be identified by their nonzero sw_ack_vector field.
*
* This is entered for a single cpu on the uvhub.
* The sender want's this uvhub to free a specific message's
* sw_ack resources.
*/
static void
uv_do_reset(void *ptr)
{
int i;
int slot;
int count = 0;
unsigned long mmr;
unsigned long msg_res;
struct bau_control *bcp;
struct reset_args *rap;
struct bau_payload_queue_entry *msg;
struct ptc_stats *stat;
bcp = &per_cpu(bau_control, smp_processor_id());
rap = (struct reset_args *)ptr;
stat = bcp->statp;
stat->d_resets++;
/*
* We're looking for the given sender, and
* will free its sw_ack resource.
* If all cpu's finally responded after the timeout, its
* message 'replied_to' was set.
*/
for (msg = bcp->va_queue_first, i = 0; i < DEST_Q_SIZE; msg++, i++) {
/* uv_do_reset: same conditions for cancellation as
uv_bau_process_retry_msg() */
if ((msg->replied_to == 0) &&
(msg->canceled == 0) &&
(msg->sending_cpu == rap->sender) &&
(msg->sw_ack_vector) &&
(msg->msg_type != MSG_NOOP)) {
/*
* make everyone else ignore this message
*/
msg->canceled = 1;
slot = msg - bcp->va_queue_first;
count++;
/*
* only reset the resource if it is still pending
*/
mmr = uv_read_local_mmr
(UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE);
msg_res = msg->sw_ack_vector;
if (mmr & msg_res) {
stat->d_rcanceled++;
uv_write_local_mmr(
UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE_ALIAS,
(msg_res << UV_SW_ACK_NPENDING) |
msg_res);
}
}
}
return;
}
/*
* Use IPI to get all target uvhubs to release resources held by
* a given sending cpu number.
*/
static void uv_reset_with_ipi(struct bau_target_uvhubmask *distribution,
int sender)
{
int uvhub;
int cpu;
cpumask_t mask;
struct reset_args reset_args;
reset_args.sender = sender;
cpus_clear(mask);
/* find a single cpu for each uvhub in this distribution mask */
for (uvhub = 0;
uvhub < sizeof(struct bau_target_uvhubmask) * BITSPERBYTE;
uvhub++) {
if (!bau_uvhub_isset(uvhub, distribution))
continue;
/* find a cpu for this uvhub */
cpu = uvhub_to_first_cpu(uvhub);
cpu_set(cpu, mask);
}
/* IPI all cpus; Preemption is already disabled */
smp_call_function_many(&mask, uv_do_reset, (void *)&reset_args, 1);
return;
}
static inline unsigned long
cycles_2_us(unsigned long long cyc)
{
unsigned long long ns;
unsigned long us;
ns = (cyc * per_cpu(cyc2ns, smp_processor_id()))
>> CYC2NS_SCALE_FACTOR;
us = ns / 1000;
return us;
}
/*
* wait for all cpus on this hub to finish their sends and go quiet
* leaves uvhub_quiesce set so that no new broadcasts are started by
* bau_flush_send_and_wait()
*/
static inline void
quiesce_local_uvhub(struct bau_control *hmaster)
{
atomic_add_short_return(1, (struct atomic_short *)
&hmaster->uvhub_quiesce);
}
/*
* mark this quiet-requestor as done
*/
static inline void
end_uvhub_quiesce(struct bau_control *hmaster)
{
atomic_add_short_return(-1, (struct atomic_short *)
&hmaster->uvhub_quiesce);
}
/*
* Wait for completion of a broadcast software ack message
* return COMPLETE, RETRY(PLUGGED or TIMEOUT) or GIVEUP
*/
static int uv_wait_completion(struct bau_desc *bau_desc,
unsigned long mmr_offset, int right_shift, int this_cpu,
struct bau_control *bcp, struct bau_control *smaster, long try)
{
unsigned long descriptor_status;
cycles_t ttime;
struct ptc_stats *stat = bcp->statp;
struct bau_control *hmaster;
hmaster = bcp->uvhub_master;
/* spin on the status MMR, waiting for it to go idle */
while ((descriptor_status = (((unsigned long)
uv_read_local_mmr(mmr_offset) >>
right_shift) & UV_ACT_STATUS_MASK)) !=
DESC_STATUS_IDLE) {
/*
* Our software ack messages may be blocked because there are
* no swack resources available. As long as none of them
* has timed out hardware will NACK our message and its
* state will stay IDLE.
*/
if (descriptor_status == DESC_STATUS_SOURCE_TIMEOUT) {
stat->s_stimeout++;
return FLUSH_GIVEUP;
} else if (descriptor_status ==
DESC_STATUS_DESTINATION_TIMEOUT) {
stat->s_dtimeout++;
ttime = get_cycles();
/*
* Our retries may be blocked by all destination
* swack resources being consumed, and a timeout
* pending. In that case hardware returns the
* ERROR that looks like a destination timeout.
*/
if (cycles_2_us(ttime - bcp->send_message) <
timeout_us) {
bcp->conseccompletes = 0;
return FLUSH_RETRY_PLUGGED;
}
bcp->conseccompletes = 0;
return FLUSH_RETRY_TIMEOUT;
} else {
/*
* descriptor_status is still BUSY
*/
cpu_relax();
}
}
bcp->conseccompletes++;
return FLUSH_COMPLETE;
}
static inline cycles_t
sec_2_cycles(unsigned long sec)
{
unsigned long ns;
cycles_t cyc;
ns = sec * 1000000000;
cyc = (ns << CYC2NS_SCALE_FACTOR)/(per_cpu(cyc2ns, smp_processor_id()));
return cyc;
}
/*
* conditionally add 1 to *v, unless *v is >= u
* return 0 if we cannot add 1 to *v because it is >= u
* return 1 if we can add 1 to *v because it is < u
* the add is atomic
*
* This is close to atomic_add_unless(), but this allows the 'u' value
* to be lowered below the current 'v'. atomic_add_unless can only stop
* on equal.
*/
static inline int atomic_inc_unless_ge(spinlock_t *lock, atomic_t *v, int u)
{
spin_lock(lock);
if (atomic_read(v) >= u) {
spin_unlock(lock);
return 0;
}
atomic_inc(v);
spin_unlock(lock);
return 1;
}
/*
* Our retries are blocked by all destination swack resources being
* in use, and a timeout is pending. In that case hardware immediately
* returns the ERROR that looks like a destination timeout.
*/
static void
destination_plugged(struct bau_desc *bau_desc, struct bau_control *bcp,
struct bau_control *hmaster, struct ptc_stats *stat)
{
udelay(bcp->plugged_delay);
bcp->plugged_tries++;
if (bcp->plugged_tries >= bcp->plugsb4reset) {
bcp->plugged_tries = 0;
quiesce_local_uvhub(hmaster);
spin_lock(&hmaster->queue_lock);
uv_reset_with_ipi(&bau_desc->distribution, bcp->cpu);
spin_unlock(&hmaster->queue_lock);
end_uvhub_quiesce(hmaster);
bcp->ipi_attempts++;
stat->s_resets_plug++;
}
}
static void
destination_timeout(struct bau_desc *bau_desc, struct bau_control *bcp,
struct bau_control *hmaster, struct ptc_stats *stat)
{
hmaster->max_bau_concurrent = 1;
bcp->timeout_tries++;
if (bcp->timeout_tries >= bcp->timeoutsb4reset) {
bcp->timeout_tries = 0;
quiesce_local_uvhub(hmaster);
spin_lock(&hmaster->queue_lock);
uv_reset_with_ipi(&bau_desc->distribution, bcp->cpu);
spin_unlock(&hmaster->queue_lock);
end_uvhub_quiesce(hmaster);
bcp->ipi_attempts++;
stat->s_resets_timeout++;
}
}
/*
* Completions are taking a very long time due to a congested numalink
* network.
*/
static void
disable_for_congestion(struct bau_control *bcp, struct ptc_stats *stat)
{
int tcpu;
struct bau_control *tbcp;
/* let only one cpu do this disabling */
spin_lock(&disable_lock);
if (!baudisabled && bcp->period_requests &&
((bcp->period_time / bcp->period_requests) > congested_cycles)) {
/* it becomes this cpu's job to turn on the use of the
BAU again */
baudisabled = 1;
bcp->set_bau_off = 1;
bcp->set_bau_on_time = get_cycles() +
sec_2_cycles(bcp->congested_period);
stat->s_bau_disabled++;
for_each_present_cpu(tcpu) {
tbcp = &per_cpu(bau_control, tcpu);
tbcp->baudisabled = 1;
}
}
spin_unlock(&disable_lock);
}
/**
* uv_flush_send_and_wait
*
* Send a broadcast and wait for it to complete.
*
* The flush_mask contains the cpus the broadcast is to be sent to including
* cpus that are on the local uvhub.
*
* Returns 0 if all flushing represented in the mask was done.
* Returns 1 if it gives up entirely and the original cpu mask is to be
* returned to the kernel.
*/
int uv_flush_send_and_wait(struct bau_desc *bau_desc,
struct cpumask *flush_mask, struct bau_control *bcp)
{
int right_shift;
int completion_status = 0;
int seq_number = 0;
long try = 0;
int cpu = bcp->uvhub_cpu;
int this_cpu = bcp->cpu;
unsigned long mmr_offset;
unsigned long index;
cycles_t time1;
cycles_t time2;
cycles_t elapsed;
struct ptc_stats *stat = bcp->statp;
struct bau_control *smaster = bcp->socket_master;
struct bau_control *hmaster = bcp->uvhub_master;
if (!atomic_inc_unless_ge(&hmaster->uvhub_lock,
&hmaster->active_descriptor_count,
hmaster->max_bau_concurrent)) {
stat->s_throttles++;
do {
cpu_relax();
} while (!atomic_inc_unless_ge(&hmaster->uvhub_lock,
&hmaster->active_descriptor_count,
hmaster->max_bau_concurrent));
}
while (hmaster->uvhub_quiesce)
cpu_relax();
if (cpu < UV_CPUS_PER_ACT_STATUS) {
mmr_offset = UVH_LB_BAU_SB_ACTIVATION_STATUS_0;
right_shift = cpu * UV_ACT_STATUS_SIZE;
} else {
mmr_offset = UVH_LB_BAU_SB_ACTIVATION_STATUS_1;
right_shift =
((cpu - UV_CPUS_PER_ACT_STATUS) * UV_ACT_STATUS_SIZE);
}
time1 = get_cycles();
do {
if (try == 0) {
bau_desc->header.msg_type = MSG_REGULAR;
seq_number = bcp->message_number++;
} else {
bau_desc->header.msg_type = MSG_RETRY;
stat->s_retry_messages++;
}
bau_desc->header.sequence = seq_number;
index = (1UL << UVH_LB_BAU_SB_ACTIVATION_CONTROL_PUSH_SHFT) |
bcp->uvhub_cpu;
bcp->send_message = get_cycles();
uv_write_local_mmr(UVH_LB_BAU_SB_ACTIVATION_CONTROL, index);
try++;
completion_status = uv_wait_completion(bau_desc, mmr_offset,
right_shift, this_cpu, bcp, smaster, try);
if (completion_status == FLUSH_RETRY_PLUGGED) {
destination_plugged(bau_desc, bcp, hmaster, stat);
} else if (completion_status == FLUSH_RETRY_TIMEOUT) {
destination_timeout(bau_desc, bcp, hmaster, stat);
}
if (bcp->ipi_attempts >= bcp->ipi_reset_limit) {
bcp->ipi_attempts = 0;
completion_status = FLUSH_GIVEUP;
break;
}
cpu_relax();
} while ((completion_status == FLUSH_RETRY_PLUGGED) ||
(completion_status == FLUSH_RETRY_TIMEOUT));
time2 = get_cycles();
bcp->plugged_tries = 0;
bcp->timeout_tries = 0;
if ((completion_status == FLUSH_COMPLETE) &&
(bcp->conseccompletes > bcp->complete_threshold) &&
(hmaster->max_bau_concurrent <
hmaster->max_bau_concurrent_constant))
hmaster->max_bau_concurrent++;
while (hmaster->uvhub_quiesce)
cpu_relax();
atomic_dec(&hmaster->active_descriptor_count);
if (time2 > time1) {
elapsed = time2 - time1;
stat->s_time += elapsed;
if ((completion_status == FLUSH_COMPLETE) && (try == 1)) {
bcp->period_requests++;
bcp->period_time += elapsed;
if ((elapsed > congested_cycles) &&
(bcp->period_requests > bcp->congested_reps)) {
disable_for_congestion(bcp, stat);
}
}
} else
stat->s_requestor--;
if (completion_status == FLUSH_COMPLETE && try > 1)
stat->s_retriesok++;
else if (completion_status == FLUSH_GIVEUP) {
stat->s_giveup++;
return 1;
}
return 0;
}
/**
* uv_flush_tlb_others - globally purge translation cache of a virtual
* address or all TLB's
* @cpumask: mask of all cpu's in which the address is to be removed
* @mm: mm_struct containing virtual address range
* @va: virtual address to be removed (or TLB_FLUSH_ALL for all TLB's on cpu)
* @cpu: the current cpu
*
* This is the entry point for initiating any UV global TLB shootdown.
*
* Purges the translation caches of all specified processors of the given
* virtual address, or purges all TLB's on specified processors.
*
* The caller has derived the cpumask from the mm_struct. This function
* is called only if there are bits set in the mask. (e.g. flush_tlb_page())
*
* The cpumask is converted into a uvhubmask of the uvhubs containing
* those cpus.
*
* Note that this function should be called with preemption disabled.
*
* Returns NULL if all remote flushing was done.
* Returns pointer to cpumask if some remote flushing remains to be
* done. The returned pointer is valid till preemption is re-enabled.
*/
const struct cpumask *uv_flush_tlb_others(const struct cpumask *cpumask,
struct mm_struct *mm,
unsigned long va, unsigned int cpu)
{
int locals = 0;
int remotes = 0;
int hubs = 0;
int tcpu;
int tpnode;
struct bau_desc *bau_desc;
struct cpumask *flush_mask;
struct ptc_stats *stat;
struct bau_control *bcp;
struct bau_control *tbcp;
struct hub_and_pnode *hpp;
/* kernel was booted 'nobau' */
if (nobau)
return cpumask;
bcp = &per_cpu(bau_control, cpu);
stat = bcp->statp;
/* bau was disabled due to slow response */
if (bcp->baudisabled) {
/* the cpu that disabled it must re-enable it */
if (bcp->set_bau_off) {
if (get_cycles() >= bcp->set_bau_on_time) {
stat->s_bau_reenabled++;
baudisabled = 0;
for_each_present_cpu(tcpu) {
tbcp = &per_cpu(bau_control, tcpu);
tbcp->baudisabled = 0;
tbcp->period_requests = 0;
tbcp->period_time = 0;
}
}
}
return cpumask;
}
/*
* Each sending cpu has a per-cpu mask which it fills from the caller's
* cpu mask. All cpus are converted to uvhubs and copied to the
* activation descriptor.
*/
flush_mask = (struct cpumask *)per_cpu(uv_flush_tlb_mask, cpu);
/* don't actually do a shootdown of the local cpu */
cpumask_andnot(flush_mask, cpumask, cpumask_of(cpu));
if (cpu_isset(cpu, *cpumask))
stat->s_ntargself++;
bau_desc = bcp->descriptor_base;
bau_desc += UV_ITEMS_PER_DESCRIPTOR * bcp->uvhub_cpu;
bau_uvhubs_clear(&bau_desc->distribution, UV_DISTRIBUTION_SIZE);
for_each_cpu(tcpu, flush_mask) {
/*
* The distribution vector is a bit map of pnodes, relative
* to the partition base pnode (and the partition base nasid
* in the header).
* Translate cpu to pnode and hub using an array stored
* in local memory.
*/
hpp = &bcp->socket_master->target_hub_and_pnode[tcpu];
tpnode = hpp->pnode - bcp->partition_base_pnode;
bau_uvhub_set(tpnode, &bau_desc->distribution);
if (hpp->uvhub == bcp->uvhub)
locals++;
else
remotes++;
}
if ((locals + remotes) == 0)
return NULL;
stat->s_requestor++;
stat->s_ntargcpu += remotes + locals;
stat->s_ntargremotes += remotes;
stat->s_ntarglocals += locals;
remotes = bau_uvhub_weight(&bau_desc->distribution);
/* uvhub statistics */
hubs = bau_uvhub_weight(&bau_desc->distribution);
if (locals) {
stat->s_ntarglocaluvhub++;
stat->s_ntargremoteuvhub += (hubs - 1);
} else
stat->s_ntargremoteuvhub += hubs;
stat->s_ntarguvhub += hubs;
if (hubs >= 16)
stat->s_ntarguvhub16++;
else if (hubs >= 8)
stat->s_ntarguvhub8++;
else if (hubs >= 4)
stat->s_ntarguvhub4++;
else if (hubs >= 2)
stat->s_ntarguvhub2++;
else
stat->s_ntarguvhub1++;
bau_desc->payload.address = va;
bau_desc->payload.sending_cpu = cpu;
/*
* uv_flush_send_and_wait returns 0 if all cpu's were messaged,
* or 1 if it gave up and the original cpumask should be returned.
*/
if (!uv_flush_send_and_wait(bau_desc, flush_mask, bcp))
return NULL;
else
return cpumask;
}
/*
* The BAU message interrupt comes here. (registered by set_intr_gate)
* See entry_64.S
*
* We received a broadcast assist message.
*
* Interrupts are disabled; this interrupt could represent
* the receipt of several messages.
*
* All cores/threads on this hub get this interrupt.
* The last one to see it does the software ack.
* (the resource will not be freed until noninterruptable cpus see this
* interrupt; hardware may timeout the s/w ack and reply ERROR)
*/
void uv_bau_message_interrupt(struct pt_regs *regs)
{
int count = 0;
cycles_t time_start;
struct bau_payload_queue_entry *msg;
struct bau_control *bcp;
struct ptc_stats *stat;
struct msg_desc msgdesc;
time_start = get_cycles();
bcp = &per_cpu(bau_control, smp_processor_id());
stat = bcp->statp;
msgdesc.va_queue_first = bcp->va_queue_first;
msgdesc.va_queue_last = bcp->va_queue_last;
msg = bcp->bau_msg_head;
while (msg->sw_ack_vector) {
count++;
msgdesc.msg_slot = msg - msgdesc.va_queue_first;
msgdesc.sw_ack_slot = ffs(msg->sw_ack_vector) - 1;
msgdesc.msg = msg;
uv_bau_process_message(&msgdesc, bcp);
msg++;
if (msg > msgdesc.va_queue_last)
msg = msgdesc.va_queue_first;
bcp->bau_msg_head = msg;
}
stat->d_time += (get_cycles() - time_start);
if (!count)
stat->d_nomsg++;
else if (count > 1)
stat->d_multmsg++;
ack_APIC_irq();
}
/*
* uv_enable_timeouts
*
* Each target uvhub (i.e. a uvhub that has no cpu's) needs to have
* shootdown message timeouts enabled. The timeout does not cause
* an interrupt, but causes an error message to be returned to
* the sender.
*/
static void __init uv_enable_timeouts(void)
{
int uvhub;
int nuvhubs;
int pnode;
unsigned long mmr_image;
nuvhubs = uv_num_possible_blades();
for (uvhub = 0; uvhub < nuvhubs; uvhub++) {
if (!uv_blade_nr_possible_cpus(uvhub))
continue;
pnode = uv_blade_to_pnode(uvhub);
mmr_image =
uv_read_global_mmr64(pnode, UVH_LB_BAU_MISC_CONTROL);
/*
* Set the timeout period and then lock it in, in three
* steps; captures and locks in the period.
*
* To program the period, the SOFT_ACK_MODE must be off.
*/
mmr_image &= ~((unsigned long)1 <<
UVH_LB_BAU_MISC_CONTROL_ENABLE_INTD_SOFT_ACK_MODE_SHFT);
uv_write_global_mmr64
(pnode, UVH_LB_BAU_MISC_CONTROL, mmr_image);
/*
* Set the 4-bit period.
*/
mmr_image &= ~((unsigned long)0xf <<
UVH_LB_BAU_MISC_CONTROL_INTD_SOFT_ACK_TIMEOUT_PERIOD_SHFT);
mmr_image |= (UV_INTD_SOFT_ACK_TIMEOUT_PERIOD <<
UVH_LB_BAU_MISC_CONTROL_INTD_SOFT_ACK_TIMEOUT_PERIOD_SHFT);
uv_write_global_mmr64
(pnode, UVH_LB_BAU_MISC_CONTROL, mmr_image);
/*
* Subsequent reversals of the timebase bit (3) cause an
* immediate timeout of one or all INTD resources as
* indicated in bits 2:0 (7 causes all of them to timeout).
*/
mmr_image |= ((unsigned long)1 <<
UVH_LB_BAU_MISC_CONTROL_ENABLE_INTD_SOFT_ACK_MODE_SHFT);
uv_write_global_mmr64
(pnode, UVH_LB_BAU_MISC_CONTROL, mmr_image);
}
}
static void *uv_ptc_seq_start(struct seq_file *file, loff_t *offset)
{
if (*offset < num_possible_cpus())
return offset;
return NULL;
}
static void *uv_ptc_seq_next(struct seq_file *file, void *data, loff_t *offset)
{
(*offset)++;
if (*offset < num_possible_cpus())
return offset;
return NULL;
}
static void uv_ptc_seq_stop(struct seq_file *file, void *data)
{
}
static inline unsigned long long
microsec_2_cycles(unsigned long microsec)
{
unsigned long ns;
unsigned long long cyc;
ns = microsec * 1000;
cyc = (ns << CYC2NS_SCALE_FACTOR)/(per_cpu(cyc2ns, smp_processor_id()));
return cyc;
}
/*
* Display the statistics thru /proc.
* 'data' points to the cpu number
*/
static int uv_ptc_seq_show(struct seq_file *file, void *data)
{
struct ptc_stats *stat;
int cpu;
cpu = *(loff_t *)data;
if (!cpu) {
seq_printf(file,
"# cpu sent stime self locals remotes ncpus localhub ");
seq_printf(file,
"remotehub numuvhubs numuvhubs16 numuvhubs8 ");
seq_printf(file,
"numuvhubs4 numuvhubs2 numuvhubs1 dto ");
seq_printf(file,
"retries rok resetp resett giveup sto bz throt ");
seq_printf(file,
"sw_ack recv rtime all ");
seq_printf(file,
"one mult none retry canc nocan reset rcan ");
seq_printf(file,
"disable enable\n");
}
if (cpu < num_possible_cpus() && cpu_online(cpu)) {
stat = &per_cpu(ptcstats, cpu);
/* source side statistics */
seq_printf(file,
"cpu %d %ld %ld %ld %ld %ld %ld %ld %ld %ld %ld ",
cpu, stat->s_requestor, cycles_2_us(stat->s_time),
stat->s_ntargself, stat->s_ntarglocals,
stat->s_ntargremotes, stat->s_ntargcpu,
stat->s_ntarglocaluvhub, stat->s_ntargremoteuvhub,
stat->s_ntarguvhub, stat->s_ntarguvhub16);
seq_printf(file, "%ld %ld %ld %ld %ld ",
stat->s_ntarguvhub8, stat->s_ntarguvhub4,
stat->s_ntarguvhub2, stat->s_ntarguvhub1,
stat->s_dtimeout);
seq_printf(file, "%ld %ld %ld %ld %ld %ld %ld %ld ",
stat->s_retry_messages, stat->s_retriesok,
stat->s_resets_plug, stat->s_resets_timeout,
stat->s_giveup, stat->s_stimeout,
stat->s_busy, stat->s_throttles);
/* destination side statistics */
seq_printf(file,
"%lx %ld %ld %ld %ld %ld %ld %ld %ld %ld %ld %ld ",
uv_read_global_mmr64(uv_cpu_to_pnode(cpu),
UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE),
stat->d_requestee, cycles_2_us(stat->d_time),
stat->d_alltlb, stat->d_onetlb, stat->d_multmsg,
stat->d_nomsg, stat->d_retries, stat->d_canceled,
stat->d_nocanceled, stat->d_resets,
stat->d_rcanceled);
seq_printf(file, "%ld %ld\n",
stat->s_bau_disabled, stat->s_bau_reenabled);
}
return 0;
}
/*
* Display the tunables thru debugfs
*/
static ssize_t tunables_read(struct file *file, char __user *userbuf,
size_t count, loff_t *ppos)
{
char *buf;
int ret;
buf = kasprintf(GFP_KERNEL, "%s %s %s\n%d %d %d %d %d %d %d %d %d\n",
"max_bau_concurrent plugged_delay plugsb4reset",
"timeoutsb4reset ipi_reset_limit complete_threshold",
"congested_response_us congested_reps congested_period",
max_bau_concurrent, plugged_delay, plugsb4reset,
timeoutsb4reset, ipi_reset_limit, complete_threshold,
congested_response_us, congested_reps, congested_period);
if (!buf)
return -ENOMEM;
ret = simple_read_from_buffer(userbuf, count, ppos, buf, strlen(buf));
kfree(buf);
return ret;
}
/*
* -1: resetf the statistics
* 0: display meaning of the statistics
*/
static ssize_t uv_ptc_proc_write(struct file *file, const char __user *user,
size_t count, loff_t *data)
{
int cpu;
long input_arg;
char optstr[64];
struct ptc_stats *stat;
if (count == 0 || count > sizeof(optstr))
return -EINVAL;
if (copy_from_user(optstr, user, count))
return -EFAULT;
optstr[count - 1] = '\0';
if (strict_strtol(optstr, 10, &input_arg) < 0) {
printk(KERN_DEBUG "%s is invalid\n", optstr);
return -EINVAL;
}
if (input_arg == 0) {
printk(KERN_DEBUG "# cpu: cpu number\n");
printk(KERN_DEBUG "Sender statistics:\n");
printk(KERN_DEBUG
"sent: number of shootdown messages sent\n");
printk(KERN_DEBUG
"stime: time spent sending messages\n");
printk(KERN_DEBUG
"numuvhubs: number of hubs targeted with shootdown\n");
printk(KERN_DEBUG
"numuvhubs16: number times 16 or more hubs targeted\n");
printk(KERN_DEBUG
"numuvhubs8: number times 8 or more hubs targeted\n");
printk(KERN_DEBUG
"numuvhubs4: number times 4 or more hubs targeted\n");
printk(KERN_DEBUG
"numuvhubs2: number times 2 or more hubs targeted\n");
printk(KERN_DEBUG
"numuvhubs1: number times 1 hub targeted\n");
printk(KERN_DEBUG
"numcpus: number of cpus targeted with shootdown\n");
printk(KERN_DEBUG
"dto: number of destination timeouts\n");
printk(KERN_DEBUG
"retries: destination timeout retries sent\n");
printk(KERN_DEBUG
"rok: : destination timeouts successfully retried\n");
printk(KERN_DEBUG
"resetp: ipi-style resource resets for plugs\n");
printk(KERN_DEBUG
"resett: ipi-style resource resets for timeouts\n");
printk(KERN_DEBUG
"giveup: fall-backs to ipi-style shootdowns\n");
printk(KERN_DEBUG
"sto: number of source timeouts\n");
printk(KERN_DEBUG
"bz: number of stay-busy's\n");
printk(KERN_DEBUG
"throt: number times spun in throttle\n");
printk(KERN_DEBUG "Destination side statistics:\n");
printk(KERN_DEBUG
"sw_ack: image of UVH_LB_BAU_INTD_SOFTWARE_ACKNOWLEDGE\n");
printk(KERN_DEBUG
"recv: shootdown messages received\n");
printk(KERN_DEBUG
"rtime: time spent processing messages\n");
printk(KERN_DEBUG
"all: shootdown all-tlb messages\n");
printk(KERN_DEBUG
"one: shootdown one-tlb messages\n");
printk(KERN_DEBUG
"mult: interrupts that found multiple messages\n");
printk(KERN_DEBUG
"none: interrupts that found no messages\n");
printk(KERN_DEBUG
"retry: number of retry messages processed\n");
printk(KERN_DEBUG
"canc: number messages canceled by retries\n");
printk(KERN_DEBUG
"nocan: number retries that found nothing to cancel\n");
printk(KERN_DEBUG
"reset: number of ipi-style reset requests processed\n");
printk(KERN_DEBUG
"rcan: number messages canceled by reset requests\n");
printk(KERN_DEBUG
"disable: number times use of the BAU was disabled\n");
printk(KERN_DEBUG
"enable: number times use of the BAU was re-enabled\n");
} else if (input_arg == -1) {
for_each_present_cpu(cpu) {
stat = &per_cpu(ptcstats, cpu);
memset(stat, 0, sizeof(struct ptc_stats));
}
}
return count;
}
static int local_atoi(const char *name)
{
int val = 0;
for (;; name++) {
switch (*name) {
case '0' ... '9':
val = 10*val+(*name-'0');
break;
default:
return val;
}
}
}
/*
* set the tunables
* 0 values reset them to defaults
*/
static ssize_t tunables_write(struct file *file, const char __user *user,
size_t count, loff_t *data)
{
int cpu;
int cnt = 0;
int val;
char *p;
char *q;
char instr[64];
struct bau_control *bcp;
if (count == 0 || count > sizeof(instr)-1)
return -EINVAL;
if (copy_from_user(instr, user, count))
return -EFAULT;
instr[count] = '\0';
/* count the fields */
p = instr + strspn(instr, WHITESPACE);
q = p;
for (; *p; p = q + strspn(q, WHITESPACE)) {
q = p + strcspn(p, WHITESPACE);
cnt++;
if (q == p)
break;
}
if (cnt != 9) {
printk(KERN_INFO "bau tunable error: should be 9 numbers\n");
return -EINVAL;
}
p = instr + strspn(instr, WHITESPACE);
q = p;
for (cnt = 0; *p; p = q + strspn(q, WHITESPACE), cnt++) {
q = p + strcspn(p, WHITESPACE);
val = local_atoi(p);
switch (cnt) {
case 0:
if (val == 0) {
max_bau_concurrent = MAX_BAU_CONCURRENT;
max_bau_concurrent_constant =
MAX_BAU_CONCURRENT;
continue;
}
bcp = &per_cpu(bau_control, smp_processor_id());
if (val < 1 || val > bcp->cpus_in_uvhub) {
printk(KERN_DEBUG
"Error: BAU max concurrent %d is invalid\n",
val);
return -EINVAL;
}
max_bau_concurrent = val;
max_bau_concurrent_constant = val;
continue;
case 1:
if (val == 0)
plugged_delay = PLUGGED_DELAY;
else
plugged_delay = val;
continue;
case 2:
if (val == 0)
plugsb4reset = PLUGSB4RESET;
else
plugsb4reset = val;
continue;
case 3:
if (val == 0)
timeoutsb4reset = TIMEOUTSB4RESET;
else
timeoutsb4reset = val;
continue;
case 4:
if (val == 0)
ipi_reset_limit = IPI_RESET_LIMIT;
else
ipi_reset_limit = val;
continue;
case 5:
if (val == 0)
complete_threshold = COMPLETE_THRESHOLD;
else
complete_threshold = val;
continue;
case 6:
if (val == 0)
congested_response_us = CONGESTED_RESPONSE_US;
else
congested_response_us = val;
continue;
case 7:
if (val == 0)
congested_reps = CONGESTED_REPS;
else
congested_reps = val;
continue;
case 8:
if (val == 0)
congested_period = CONGESTED_PERIOD;
else
congested_period = val;
continue;
}
if (q == p)
break;
}
for_each_present_cpu(cpu) {
bcp = &per_cpu(bau_control, cpu);
bcp->max_bau_concurrent = max_bau_concurrent;
bcp->max_bau_concurrent_constant = max_bau_concurrent;
bcp->plugged_delay = plugged_delay;
bcp->plugsb4reset = plugsb4reset;
bcp->timeoutsb4reset = timeoutsb4reset;
bcp->ipi_reset_limit = ipi_reset_limit;
bcp->complete_threshold = complete_threshold;
bcp->congested_response_us = congested_response_us;
bcp->congested_reps = congested_reps;
bcp->congested_period = congested_period;
}
return count;
}
static const struct seq_operations uv_ptc_seq_ops = {
.start = uv_ptc_seq_start,
.next = uv_ptc_seq_next,
.stop = uv_ptc_seq_stop,
.show = uv_ptc_seq_show
};
static int uv_ptc_proc_open(struct inode *inode, struct file *file)
{
return seq_open(file, &uv_ptc_seq_ops);
}
static int tunables_open(struct inode *inode, struct file *file)
{
return 0;
}
static const struct file_operations proc_uv_ptc_operations = {
.open = uv_ptc_proc_open,
.read = seq_read,
.write = uv_ptc_proc_write,
.llseek = seq_lseek,
.release = seq_release,
};
static const struct file_operations tunables_fops = {
.open = tunables_open,
.read = tunables_read,
.write = tunables_write,
.llseek = default_llseek,
};
static int __init uv_ptc_init(void)
{
struct proc_dir_entry *proc_uv_ptc;
if (!is_uv_system())
return 0;
proc_uv_ptc = proc_create(UV_PTC_BASENAME, 0444, NULL,
&proc_uv_ptc_operations);
if (!proc_uv_ptc) {
printk(KERN_ERR "unable to create %s proc entry\n",
UV_PTC_BASENAME);
return -EINVAL;
}
tunables_dir = debugfs_create_dir(UV_BAU_TUNABLES_DIR, NULL);
if (!tunables_dir) {
printk(KERN_ERR "unable to create debugfs directory %s\n",
UV_BAU_TUNABLES_DIR);
return -EINVAL;
}
tunables_file = debugfs_create_file(UV_BAU_TUNABLES_FILE, 0600,
tunables_dir, NULL, &tunables_fops);
if (!tunables_file) {
printk(KERN_ERR "unable to create debugfs file %s\n",
UV_BAU_TUNABLES_FILE);
return -EINVAL;
}
return 0;
}
/*
* Initialize the sending side's sending buffers.
*/
static void
uv_activation_descriptor_init(int node, int pnode, int base_pnode)
{
int i;
int cpu;
unsigned long pa;
unsigned long m;
unsigned long n;
struct bau_desc *bau_desc;
struct bau_desc *bd2;
struct bau_control *bcp;
/*
* each bau_desc is 64 bytes; there are 8 (UV_ITEMS_PER_DESCRIPTOR)
* per cpu; and one per cpu on the uvhub (UV_ADP_SIZE)
*/
bau_desc = kmalloc_node(sizeof(struct bau_desc) * UV_ADP_SIZE
* UV_ITEMS_PER_DESCRIPTOR, GFP_KERNEL, node);
BUG_ON(!bau_desc);
pa = uv_gpa(bau_desc); /* need the real nasid*/
n = pa >> uv_nshift;
m = pa & uv_mmask;
/* the 14-bit pnode */
uv_write_global_mmr64(pnode, UVH_LB_BAU_SB_DESCRIPTOR_BASE,
(n << UV_DESC_BASE_PNODE_SHIFT | m));
/*
* Initializing all 8 (UV_ITEMS_PER_DESCRIPTOR) descriptors for each
* cpu even though we only use the first one; one descriptor can
* describe a broadcast to 256 uv hubs.
*/
for (i = 0, bd2 = bau_desc; i < (UV_ADP_SIZE*UV_ITEMS_PER_DESCRIPTOR);
i++, bd2++) {
memset(bd2, 0, sizeof(struct bau_desc));
bd2->header.sw_ack_flag = 1;
/*
* The base_dest_nasid set in the message header is the nasid
* of the first uvhub in the partition. The bit map will
* indicate destination pnode numbers relative to that base.
* They may not be consecutive if nasid striding is being used.
*/
bd2->header.base_dest_nasid = UV_PNODE_TO_NASID(base_pnode);
bd2->header.dest_subnodeid = UV_LB_SUBNODEID;
bd2->header.command = UV_NET_ENDPOINT_INTD;
bd2->header.int_both = 1;
/*
* all others need to be set to zero:
* fairness chaining multilevel count replied_to
*/
}
for_each_present_cpu(cpu) {
if (pnode != uv_blade_to_pnode(uv_cpu_to_blade_id(cpu)))
continue;
bcp = &per_cpu(bau_control, cpu);
bcp->descriptor_base = bau_desc;
}
}
/*
* initialize the destination side's receiving buffers
* entered for each uvhub in the partition
* - node is first node (kernel memory notion) on the uvhub
* - pnode is the uvhub's physical identifier
*/
static void
uv_payload_queue_init(int node, int pnode)
{
int pn;
int cpu;
char *cp;
unsigned long pa;
struct bau_payload_queue_entry *pqp;
struct bau_payload_queue_entry *pqp_malloc;
struct bau_control *bcp;
pqp = kmalloc_node((DEST_Q_SIZE + 1)
* sizeof(struct bau_payload_queue_entry),
GFP_KERNEL, node);
BUG_ON(!pqp);
pqp_malloc = pqp;
cp = (char *)pqp + 31;
pqp = (struct bau_payload_queue_entry *)(((unsigned long)cp >> 5) << 5);
for_each_present_cpu(cpu) {
if (pnode != uv_cpu_to_pnode(cpu))
continue;
/* for every cpu on this pnode: */
bcp = &per_cpu(bau_control, cpu);
bcp->va_queue_first = pqp;
bcp->bau_msg_head = pqp;
bcp->va_queue_last = pqp + (DEST_Q_SIZE - 1);
}
/*
* need the pnode of where the memory was really allocated
*/
pa = uv_gpa(pqp);
pn = pa >> uv_nshift;
uv_write_global_mmr64(pnode,
UVH_LB_BAU_INTD_PAYLOAD_QUEUE_FIRST,
((unsigned long)pn << UV_PAYLOADQ_PNODE_SHIFT) |
uv_physnodeaddr(pqp));
uv_write_global_mmr64(pnode, UVH_LB_BAU_INTD_PAYLOAD_QUEUE_TAIL,
uv_physnodeaddr(pqp));
uv_write_global_mmr64(pnode, UVH_LB_BAU_INTD_PAYLOAD_QUEUE_LAST,
(unsigned long)
uv_physnodeaddr(pqp + (DEST_Q_SIZE - 1)));
/* in effect, all msg_type's are set to MSG_NOOP */
memset(pqp, 0, sizeof(struct bau_payload_queue_entry) * DEST_Q_SIZE);
}
/*
* Initialization of each UV hub's structures
*/
static void __init uv_init_uvhub(int uvhub, int vector, int base_pnode)
{
int node;
int pnode;
unsigned long apicid;
node = uvhub_to_first_node(uvhub);
pnode = uv_blade_to_pnode(uvhub);
uv_activation_descriptor_init(node, pnode, base_pnode);
uv_payload_queue_init(node, pnode);
/*
* The below initialization can't be in firmware because the
* messaging IRQ will be determined by the OS.
*/
apicid = uvhub_to_first_apicid(uvhub) | uv_apicid_hibits;
uv_write_global_mmr64(pnode, UVH_BAU_DATA_CONFIG,
((apicid << 32) | vector));
}
/*
* We will set BAU_MISC_CONTROL with a timeout period.
* But the BIOS has set UVH_AGING_PRESCALE_SEL and UVH_TRANSACTION_TIMEOUT.
* So the destination timeout period has be be calculated from them.
*/
static int
calculate_destination_timeout(void)
{
unsigned long mmr_image;
int mult1;
int mult2;
int index;
int base;
int ret;
unsigned long ts_ns;
mult1 = UV_INTD_SOFT_ACK_TIMEOUT_PERIOD & BAU_MISC_CONTROL_MULT_MASK;
mmr_image = uv_read_local_mmr(UVH_AGING_PRESCALE_SEL);
index = (mmr_image >> BAU_URGENCY_7_SHIFT) & BAU_URGENCY_7_MASK;
mmr_image = uv_read_local_mmr(UVH_TRANSACTION_TIMEOUT);
mult2 = (mmr_image >> BAU_TRANS_SHIFT) & BAU_TRANS_MASK;
base = timeout_base_ns[index];
ts_ns = base * mult1 * mult2;
ret = ts_ns / 1000;
return ret;
}
/*
* initialize the bau_control structure for each cpu
*/
static int __init uv_init_per_cpu(int nuvhubs, int base_part_pnode)
{
int i;
int cpu;
int tcpu;
int pnode;
int uvhub;
int have_hmaster;
short socket = 0;
unsigned short socket_mask;
unsigned char *uvhub_mask;
struct bau_control *bcp;
struct uvhub_desc *bdp;
struct socket_desc *sdp;
struct bau_control *hmaster = NULL;
struct bau_control *smaster = NULL;
struct socket_desc {
short num_cpus;
short cpu_number[MAX_CPUS_PER_SOCKET];
};
struct uvhub_desc {
unsigned short socket_mask;
short num_cpus;
short uvhub;
short pnode;
struct socket_desc socket[2];
};
struct uvhub_desc *uvhub_descs;
timeout_us = calculate_destination_timeout();
uvhub_descs = kmalloc(nuvhubs * sizeof(struct uvhub_desc), GFP_KERNEL);
memset(uvhub_descs, 0, nuvhubs * sizeof(struct uvhub_desc));
uvhub_mask = kzalloc((nuvhubs+7)/8, GFP_KERNEL);
for_each_present_cpu(cpu) {
bcp = &per_cpu(bau_control, cpu);
memset(bcp, 0, sizeof(struct bau_control));
pnode = uv_cpu_hub_info(cpu)->pnode;
if ((pnode - base_part_pnode) >= UV_DISTRIBUTION_SIZE) {
printk(KERN_EMERG
"cpu %d pnode %d-%d beyond %d; BAU disabled\n",
cpu, pnode, base_part_pnode,
UV_DISTRIBUTION_SIZE);
return 1;
}
bcp->osnode = cpu_to_node(cpu);
bcp->partition_base_pnode = uv_partition_base_pnode;
uvhub = uv_cpu_hub_info(cpu)->numa_blade_id;
*(uvhub_mask + (uvhub/8)) |= (1 << (uvhub%8));
bdp = &uvhub_descs[uvhub];
bdp->num_cpus++;
bdp->uvhub = uvhub;
bdp->pnode = pnode;
/* kludge: 'assuming' one node per socket, and assuming that
disabling a socket just leaves a gap in node numbers */
socket = bcp->osnode & 1;
bdp->socket_mask |= (1 << socket);
sdp = &bdp->socket[socket];
sdp->cpu_number[sdp->num_cpus] = cpu;
sdp->num_cpus++;
if (sdp->num_cpus > MAX_CPUS_PER_SOCKET) {
printk(KERN_EMERG "%d cpus per socket invalid\n", sdp->num_cpus);
return 1;
}
}
for (uvhub = 0; uvhub < nuvhubs; uvhub++) {
if (!(*(uvhub_mask + (uvhub/8)) & (1 << (uvhub%8))))
continue;
have_hmaster = 0;
bdp = &uvhub_descs[uvhub];
socket_mask = bdp->socket_mask;
socket = 0;
while (socket_mask) {
if (!(socket_mask & 1))
goto nextsocket;
sdp = &bdp->socket[socket];
for (i = 0; i < sdp->num_cpus; i++) {
cpu = sdp->cpu_number[i];
bcp = &per_cpu(bau_control, cpu);
bcp->cpu = cpu;
if (i == 0) {
smaster = bcp;
if (!have_hmaster) {
have_hmaster++;
hmaster = bcp;
}
}
bcp->cpus_in_uvhub = bdp->num_cpus;
bcp->cpus_in_socket = sdp->num_cpus;
bcp->socket_master = smaster;
bcp->uvhub = bdp->uvhub;
bcp->uvhub_master = hmaster;
bcp->uvhub_cpu = uv_cpu_hub_info(cpu)->
blade_processor_id;
if (bcp->uvhub_cpu >= MAX_CPUS_PER_UVHUB) {
printk(KERN_EMERG
"%d cpus per uvhub invalid\n",
bcp->uvhub_cpu);
return 1;
}
}
nextsocket:
socket++;
socket_mask = (socket_mask >> 1);
/* each socket gets a local array of pnodes/hubs */
bcp = smaster;
bcp->target_hub_and_pnode = kmalloc_node(
sizeof(struct hub_and_pnode) *
num_possible_cpus(), GFP_KERNEL, bcp->osnode);
memset(bcp->target_hub_and_pnode, 0,
sizeof(struct hub_and_pnode) *
num_possible_cpus());
for_each_present_cpu(tcpu) {
bcp->target_hub_and_pnode[tcpu].pnode =
uv_cpu_hub_info(tcpu)->pnode;
bcp->target_hub_and_pnode[tcpu].uvhub =
uv_cpu_hub_info(tcpu)->numa_blade_id;
}
}
}
kfree(uvhub_descs);
kfree(uvhub_mask);
for_each_present_cpu(cpu) {
bcp = &per_cpu(bau_control, cpu);
bcp->baudisabled = 0;
bcp->statp = &per_cpu(ptcstats, cpu);
/* time interval to catch a hardware stay-busy bug */
bcp->timeout_interval = microsec_2_cycles(2*timeout_us);
bcp->max_bau_concurrent = max_bau_concurrent;
bcp->max_bau_concurrent_constant = max_bau_concurrent;
bcp->plugged_delay = plugged_delay;
bcp->plugsb4reset = plugsb4reset;
bcp->timeoutsb4reset = timeoutsb4reset;
bcp->ipi_reset_limit = ipi_reset_limit;
bcp->complete_threshold = complete_threshold;
bcp->congested_response_us = congested_response_us;
bcp->congested_reps = congested_reps;
bcp->congested_period = congested_period;
}
return 0;
}
/*
* Initialization of BAU-related structures
*/
static int __init uv_bau_init(void)
{
int uvhub;
int pnode;
int nuvhubs;
int cur_cpu;
int vector;
unsigned long mmr;
if (!is_uv_system())
return 0;
if (nobau)
return 0;
for_each_possible_cpu(cur_cpu)
zalloc_cpumask_var_node(&per_cpu(uv_flush_tlb_mask, cur_cpu),
GFP_KERNEL, cpu_to_node(cur_cpu));
uv_nshift = uv_hub_info->m_val;
uv_mmask = (1UL << uv_hub_info->m_val) - 1;
nuvhubs = uv_num_possible_blades();
spin_lock_init(&disable_lock);
congested_cycles = microsec_2_cycles(congested_response_us);
uv_partition_base_pnode = 0x7fffffff;
for (uvhub = 0; uvhub < nuvhubs; uvhub++) {
if (uv_blade_nr_possible_cpus(uvhub) &&
(uv_blade_to_pnode(uvhub) < uv_partition_base_pnode))
uv_partition_base_pnode = uv_blade_to_pnode(uvhub);
}
if (uv_init_per_cpu(nuvhubs, uv_partition_base_pnode)) {
nobau = 1;
return 0;
}
vector = UV_BAU_MESSAGE;
for_each_possible_blade(uvhub)
if (uv_blade_nr_possible_cpus(uvhub))
uv_init_uvhub(uvhub, vector, uv_partition_base_pnode);
uv_enable_timeouts();
alloc_intr_gate(vector, uv_bau_message_intr1);
for_each_possible_blade(uvhub) {
if (uv_blade_nr_possible_cpus(uvhub)) {
pnode = uv_blade_to_pnode(uvhub);
/* INIT the bau */
uv_write_global_mmr64(pnode,
UVH_LB_BAU_SB_ACTIVATION_CONTROL,
((unsigned long)1 << 63));
mmr = 1; /* should be 1 to broadcast to both sockets */
uv_write_global_mmr64(pnode, UVH_BAU_DATA_BROADCAST,
mmr);
}
}
return 0;
}
core_initcall(uv_bau_init);
fs_initcall(uv_ptc_init);