kernel-fxtec-pro1x/drivers/misc/sgi-gru/grukservices.c
Alexey Dobriyan 405f55712d headers: smp_lock.h redux
* Remove smp_lock.h from files which don't need it (including some headers!)
* Add smp_lock.h to files which do need it
* Make smp_lock.h include conditional in hardirq.h
  It's needed only for one kernel_locked() usage which is under CONFIG_PREEMPT

  This will make hardirq.h inclusion cheaper for every PREEMPT=n config
  (which includes allmodconfig/allyesconfig, BTW)

Signed-off-by: Alexey Dobriyan <adobriyan@gmail.com>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2009-07-12 12:22:34 -07:00

1056 lines
26 KiB
C

/*
* SN Platform GRU Driver
*
* KERNEL SERVICES THAT USE THE GRU
*
* Copyright (c) 2008 Silicon Graphics, Inc. All Rights Reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/slab.h>
#include <linux/mm.h>
#include <linux/spinlock.h>
#include <linux/device.h>
#include <linux/miscdevice.h>
#include <linux/proc_fs.h>
#include <linux/interrupt.h>
#include <linux/uaccess.h>
#include <linux/delay.h>
#include "gru.h"
#include "grulib.h"
#include "grutables.h"
#include "grukservices.h"
#include "gru_instructions.h"
#include <asm/uv/uv_hub.h>
/*
* Kernel GRU Usage
*
* The following is an interim algorithm for management of kernel GRU
* resources. This will likely be replaced when we better understand the
* kernel/user requirements.
*
* Blade percpu resources reserved for kernel use. These resources are
* reserved whenever the the kernel context for the blade is loaded. Note
* that the kernel context is not guaranteed to be always available. It is
* loaded on demand & can be stolen by a user if the user demand exceeds the
* kernel demand. The kernel can always reload the kernel context but
* a SLEEP may be required!!!.
*
* Async Overview:
*
* Each blade has one "kernel context" that owns GRU kernel resources
* located on the blade. Kernel drivers use GRU resources in this context
* for sending messages, zeroing memory, etc.
*
* The kernel context is dynamically loaded on demand. If it is not in
* use by the kernel, the kernel context can be unloaded & given to a user.
* The kernel context will be reloaded when needed. This may require that
* a context be stolen from a user.
* NOTE: frequent unloading/reloading of the kernel context is
* expensive. We are depending on batch schedulers, cpusets, sane
* drivers or some other mechanism to prevent the need for frequent
* stealing/reloading.
*
* The kernel context consists of two parts:
* - 1 CB & a few DSRs that are reserved for each cpu on the blade.
* Each cpu has it's own private resources & does not share them
* with other cpus. These resources are used serially, ie,
* locked, used & unlocked on each call to a function in
* grukservices.
* (Now that we have dynamic loading of kernel contexts, I
* may rethink this & allow sharing between cpus....)
*
* - Additional resources can be reserved long term & used directly
* by UV drivers located in the kernel. Drivers using these GRU
* resources can use asynchronous GRU instructions that send
* interrupts on completion.
* - these resources must be explicitly locked/unlocked
* - locked resources prevent (obviously) the kernel
* context from being unloaded.
* - drivers using these resource directly issue their own
* GRU instruction and must wait/check completion.
*
* When these resources are reserved, the caller can optionally
* associate a wait_queue with the resources and use asynchronous
* GRU instructions. When an async GRU instruction completes, the
* driver will do a wakeup on the event.
*
*/
#define ASYNC_HAN_TO_BID(h) ((h) - 1)
#define ASYNC_BID_TO_HAN(b) ((b) + 1)
#define ASYNC_HAN_TO_BS(h) gru_base[ASYNC_HAN_TO_BID(h)]
#define KCB_TO_GID(cb) ((cb - gru_start_vaddr) / \
(GRU_SIZE * GRU_CHIPLETS_PER_BLADE))
#define KCB_TO_BS(cb) gru_base[KCB_TO_GID(cb)]
#define GRU_NUM_KERNEL_CBR 1
#define GRU_NUM_KERNEL_DSR_BYTES 256
#define GRU_NUM_KERNEL_DSR_CL (GRU_NUM_KERNEL_DSR_BYTES / \
GRU_CACHE_LINE_BYTES)
/* GRU instruction attributes for all instructions */
#define IMA IMA_CB_DELAY
/* GRU cacheline size is always 64 bytes - even on arches with 128 byte lines */
#define __gru_cacheline_aligned__ \
__attribute__((__aligned__(GRU_CACHE_LINE_BYTES)))
#define MAGIC 0x1234567887654321UL
/* Default retry count for GRU errors on kernel instructions */
#define EXCEPTION_RETRY_LIMIT 3
/* Status of message queue sections */
#define MQS_EMPTY 0
#define MQS_FULL 1
#define MQS_NOOP 2
/*----------------- RESOURCE MANAGEMENT -------------------------------------*/
/* optimized for x86_64 */
struct message_queue {
union gru_mesqhead head __gru_cacheline_aligned__; /* CL 0 */
int qlines; /* DW 1 */
long hstatus[2];
void *next __gru_cacheline_aligned__;/* CL 1 */
void *limit;
void *start;
void *start2;
char data ____cacheline_aligned; /* CL 2 */
};
/* First word in every message - used by mesq interface */
struct message_header {
char present;
char present2;
char lines;
char fill;
};
#define HSTATUS(mq, h) ((mq) + offsetof(struct message_queue, hstatus[h]))
/*
* Reload the blade's kernel context into a GRU chiplet. Called holding
* the bs_kgts_sema for READ. Will steal user contexts if necessary.
*/
static void gru_load_kernel_context(struct gru_blade_state *bs, int blade_id)
{
struct gru_state *gru;
struct gru_thread_state *kgts;
void *vaddr;
int ctxnum, ncpus;
up_read(&bs->bs_kgts_sema);
down_write(&bs->bs_kgts_sema);
if (!bs->bs_kgts)
bs->bs_kgts = gru_alloc_gts(NULL, 0, 0, 0, 0);
kgts = bs->bs_kgts;
if (!kgts->ts_gru) {
STAT(load_kernel_context);
ncpus = uv_blade_nr_possible_cpus(blade_id);
kgts->ts_cbr_au_count = GRU_CB_COUNT_TO_AU(
GRU_NUM_KERNEL_CBR * ncpus + bs->bs_async_cbrs);
kgts->ts_dsr_au_count = GRU_DS_BYTES_TO_AU(
GRU_NUM_KERNEL_DSR_BYTES * ncpus +
bs->bs_async_dsr_bytes);
while (!gru_assign_gru_context(kgts, blade_id)) {
msleep(1);
gru_steal_context(kgts, blade_id);
}
gru_load_context(kgts);
gru = bs->bs_kgts->ts_gru;
vaddr = gru->gs_gru_base_vaddr;
ctxnum = kgts->ts_ctxnum;
bs->kernel_cb = get_gseg_base_address_cb(vaddr, ctxnum, 0);
bs->kernel_dsr = get_gseg_base_address_ds(vaddr, ctxnum, 0);
}
downgrade_write(&bs->bs_kgts_sema);
}
/*
* Free all kernel contexts that are not currently in use.
* Returns 0 if all freed, else number of inuse context.
*/
static int gru_free_kernel_contexts(void)
{
struct gru_blade_state *bs;
struct gru_thread_state *kgts;
int bid, ret = 0;
for (bid = 0; bid < GRU_MAX_BLADES; bid++) {
bs = gru_base[bid];
if (!bs)
continue;
if (down_write_trylock(&bs->bs_kgts_sema)) {
kgts = bs->bs_kgts;
if (kgts && kgts->ts_gru)
gru_unload_context(kgts, 0);
kfree(kgts);
bs->bs_kgts = NULL;
up_write(&bs->bs_kgts_sema);
} else {
ret++;
}
}
return ret;
}
/*
* Lock & load the kernel context for the specified blade.
*/
static struct gru_blade_state *gru_lock_kernel_context(int blade_id)
{
struct gru_blade_state *bs;
STAT(lock_kernel_context);
bs = gru_base[blade_id];
down_read(&bs->bs_kgts_sema);
if (!bs->bs_kgts || !bs->bs_kgts->ts_gru)
gru_load_kernel_context(bs, blade_id);
return bs;
}
/*
* Unlock the kernel context for the specified blade. Context is not
* unloaded but may be stolen before next use.
*/
static void gru_unlock_kernel_context(int blade_id)
{
struct gru_blade_state *bs;
bs = gru_base[blade_id];
up_read(&bs->bs_kgts_sema);
STAT(unlock_kernel_context);
}
/*
* Reserve & get pointers to the DSR/CBRs reserved for the current cpu.
* - returns with preemption disabled
*/
static int gru_get_cpu_resources(int dsr_bytes, void **cb, void **dsr)
{
struct gru_blade_state *bs;
int lcpu;
BUG_ON(dsr_bytes > GRU_NUM_KERNEL_DSR_BYTES);
preempt_disable();
bs = gru_lock_kernel_context(uv_numa_blade_id());
lcpu = uv_blade_processor_id();
*cb = bs->kernel_cb + lcpu * GRU_HANDLE_STRIDE;
*dsr = bs->kernel_dsr + lcpu * GRU_NUM_KERNEL_DSR_BYTES;
return 0;
}
/*
* Free the current cpus reserved DSR/CBR resources.
*/
static void gru_free_cpu_resources(void *cb, void *dsr)
{
gru_unlock_kernel_context(uv_numa_blade_id());
preempt_enable();
}
/*
* Reserve GRU resources to be used asynchronously.
* Note: currently supports only 1 reservation per blade.
*
* input:
* blade_id - blade on which resources should be reserved
* cbrs - number of CBRs
* dsr_bytes - number of DSR bytes needed
* output:
* handle to identify resource
* (0 = async resources already reserved)
*/
unsigned long gru_reserve_async_resources(int blade_id, int cbrs, int dsr_bytes,
struct completion *cmp)
{
struct gru_blade_state *bs;
struct gru_thread_state *kgts;
int ret = 0;
bs = gru_base[blade_id];
down_write(&bs->bs_kgts_sema);
/* Verify no resources already reserved */
if (bs->bs_async_dsr_bytes + bs->bs_async_cbrs)
goto done;
bs->bs_async_dsr_bytes = dsr_bytes;
bs->bs_async_cbrs = cbrs;
bs->bs_async_wq = cmp;
kgts = bs->bs_kgts;
/* Resources changed. Unload context if already loaded */
if (kgts && kgts->ts_gru)
gru_unload_context(kgts, 0);
ret = ASYNC_BID_TO_HAN(blade_id);
done:
up_write(&bs->bs_kgts_sema);
return ret;
}
/*
* Release async resources previously reserved.
*
* input:
* han - handle to identify resources
*/
void gru_release_async_resources(unsigned long han)
{
struct gru_blade_state *bs = ASYNC_HAN_TO_BS(han);
down_write(&bs->bs_kgts_sema);
bs->bs_async_dsr_bytes = 0;
bs->bs_async_cbrs = 0;
bs->bs_async_wq = NULL;
up_write(&bs->bs_kgts_sema);
}
/*
* Wait for async GRU instructions to complete.
*
* input:
* han - handle to identify resources
*/
void gru_wait_async_cbr(unsigned long han)
{
struct gru_blade_state *bs = ASYNC_HAN_TO_BS(han);
wait_for_completion(bs->bs_async_wq);
mb();
}
/*
* Lock previous reserved async GRU resources
*
* input:
* han - handle to identify resources
* output:
* cb - pointer to first CBR
* dsr - pointer to first DSR
*/
void gru_lock_async_resource(unsigned long han, void **cb, void **dsr)
{
struct gru_blade_state *bs = ASYNC_HAN_TO_BS(han);
int blade_id = ASYNC_HAN_TO_BID(han);
int ncpus;
gru_lock_kernel_context(blade_id);
ncpus = uv_blade_nr_possible_cpus(blade_id);
if (cb)
*cb = bs->kernel_cb + ncpus * GRU_HANDLE_STRIDE;
if (dsr)
*dsr = bs->kernel_dsr + ncpus * GRU_NUM_KERNEL_DSR_BYTES;
}
/*
* Unlock previous reserved async GRU resources
*
* input:
* han - handle to identify resources
*/
void gru_unlock_async_resource(unsigned long han)
{
int blade_id = ASYNC_HAN_TO_BID(han);
gru_unlock_kernel_context(blade_id);
}
/*----------------------------------------------------------------------*/
int gru_get_cb_exception_detail(void *cb,
struct control_block_extended_exc_detail *excdet)
{
struct gru_control_block_extended *cbe;
struct gru_blade_state *bs;
int cbrnum;
bs = KCB_TO_BS(cb);
cbrnum = thread_cbr_number(bs->bs_kgts, get_cb_number(cb));
cbe = get_cbe(GRUBASE(cb), cbrnum);
gru_flush_cache(cbe); /* CBE not coherent */
excdet->opc = cbe->opccpy;
excdet->exopc = cbe->exopccpy;
excdet->ecause = cbe->ecause;
excdet->exceptdet0 = cbe->idef1upd;
excdet->exceptdet1 = cbe->idef3upd;
gru_flush_cache(cbe);
return 0;
}
char *gru_get_cb_exception_detail_str(int ret, void *cb,
char *buf, int size)
{
struct gru_control_block_status *gen = (void *)cb;
struct control_block_extended_exc_detail excdet;
if (ret > 0 && gen->istatus == CBS_EXCEPTION) {
gru_get_cb_exception_detail(cb, &excdet);
snprintf(buf, size,
"GRU exception: cb %p, opc %d, exopc %d, ecause 0x%x,"
"excdet0 0x%lx, excdet1 0x%x",
gen, excdet.opc, excdet.exopc, excdet.ecause,
excdet.exceptdet0, excdet.exceptdet1);
} else {
snprintf(buf, size, "No exception");
}
return buf;
}
static int gru_wait_idle_or_exception(struct gru_control_block_status *gen)
{
while (gen->istatus >= CBS_ACTIVE) {
cpu_relax();
barrier();
}
return gen->istatus;
}
static int gru_retry_exception(void *cb)
{
struct gru_control_block_status *gen = (void *)cb;
struct control_block_extended_exc_detail excdet;
int retry = EXCEPTION_RETRY_LIMIT;
while (1) {
if (gru_wait_idle_or_exception(gen) == CBS_IDLE)
return CBS_IDLE;
if (gru_get_cb_message_queue_substatus(cb))
return CBS_EXCEPTION;
gru_get_cb_exception_detail(cb, &excdet);
if ((excdet.ecause & ~EXCEPTION_RETRY_BITS) ||
(excdet.cbrexecstatus & CBR_EXS_ABORT_OCC))
break;
if (retry-- == 0)
break;
gen->icmd = 1;
gru_flush_cache(gen);
}
return CBS_EXCEPTION;
}
int gru_check_status_proc(void *cb)
{
struct gru_control_block_status *gen = (void *)cb;
int ret;
ret = gen->istatus;
if (ret != CBS_EXCEPTION)
return ret;
return gru_retry_exception(cb);
}
int gru_wait_proc(void *cb)
{
struct gru_control_block_status *gen = (void *)cb;
int ret;
ret = gru_wait_idle_or_exception(gen);
if (ret == CBS_EXCEPTION)
ret = gru_retry_exception(cb);
return ret;
}
void gru_abort(int ret, void *cb, char *str)
{
char buf[GRU_EXC_STR_SIZE];
panic("GRU FATAL ERROR: %s - %s\n", str,
gru_get_cb_exception_detail_str(ret, cb, buf, sizeof(buf)));
}
void gru_wait_abort_proc(void *cb)
{
int ret;
ret = gru_wait_proc(cb);
if (ret)
gru_abort(ret, cb, "gru_wait_abort");
}
/*------------------------------ MESSAGE QUEUES -----------------------------*/
/* Internal status . These are NOT returned to the user. */
#define MQIE_AGAIN -1 /* try again */
/*
* Save/restore the "present" flag that is in the second line of 2-line
* messages
*/
static inline int get_present2(void *p)
{
struct message_header *mhdr = p + GRU_CACHE_LINE_BYTES;
return mhdr->present;
}
static inline void restore_present2(void *p, int val)
{
struct message_header *mhdr = p + GRU_CACHE_LINE_BYTES;
mhdr->present = val;
}
/*
* Create a message queue.
* qlines - message queue size in cache lines. Includes 2-line header.
*/
int gru_create_message_queue(struct gru_message_queue_desc *mqd,
void *p, unsigned int bytes, int nasid, int vector, int apicid)
{
struct message_queue *mq = p;
unsigned int qlines;
qlines = bytes / GRU_CACHE_LINE_BYTES - 2;
memset(mq, 0, bytes);
mq->start = &mq->data;
mq->start2 = &mq->data + (qlines / 2 - 1) * GRU_CACHE_LINE_BYTES;
mq->next = &mq->data;
mq->limit = &mq->data + (qlines - 2) * GRU_CACHE_LINE_BYTES;
mq->qlines = qlines;
mq->hstatus[0] = 0;
mq->hstatus[1] = 1;
mq->head = gru_mesq_head(2, qlines / 2 + 1);
mqd->mq = mq;
mqd->mq_gpa = uv_gpa(mq);
mqd->qlines = qlines;
mqd->interrupt_pnode = UV_NASID_TO_PNODE(nasid);
mqd->interrupt_vector = vector;
mqd->interrupt_apicid = apicid;
return 0;
}
EXPORT_SYMBOL_GPL(gru_create_message_queue);
/*
* Send a NOOP message to a message queue
* Returns:
* 0 - if queue is full after the send. This is the normal case
* but various races can change this.
* -1 - if mesq sent successfully but queue not full
* >0 - unexpected error. MQE_xxx returned
*/
static int send_noop_message(void *cb, struct gru_message_queue_desc *mqd,
void *mesg)
{
const struct message_header noop_header = {
.present = MQS_NOOP, .lines = 1};
unsigned long m;
int substatus, ret;
struct message_header save_mhdr, *mhdr = mesg;
STAT(mesq_noop);
save_mhdr = *mhdr;
*mhdr = noop_header;
gru_mesq(cb, mqd->mq_gpa, gru_get_tri(mhdr), 1, IMA);
ret = gru_wait(cb);
if (ret) {
substatus = gru_get_cb_message_queue_substatus(cb);
switch (substatus) {
case CBSS_NO_ERROR:
STAT(mesq_noop_unexpected_error);
ret = MQE_UNEXPECTED_CB_ERR;
break;
case CBSS_LB_OVERFLOWED:
STAT(mesq_noop_lb_overflow);
ret = MQE_CONGESTION;
break;
case CBSS_QLIMIT_REACHED:
STAT(mesq_noop_qlimit_reached);
ret = 0;
break;
case CBSS_AMO_NACKED:
STAT(mesq_noop_amo_nacked);
ret = MQE_CONGESTION;
break;
case CBSS_PUT_NACKED:
STAT(mesq_noop_put_nacked);
m = mqd->mq_gpa + (gru_get_amo_value_head(cb) << 6);
gru_vstore(cb, m, gru_get_tri(mesg), XTYPE_CL, 1, 1,
IMA);
if (gru_wait(cb) == CBS_IDLE)
ret = MQIE_AGAIN;
else
ret = MQE_UNEXPECTED_CB_ERR;
break;
case CBSS_PAGE_OVERFLOW:
default:
BUG();
}
}
*mhdr = save_mhdr;
return ret;
}
/*
* Handle a gru_mesq full.
*/
static int send_message_queue_full(void *cb, struct gru_message_queue_desc *mqd,
void *mesg, int lines)
{
union gru_mesqhead mqh;
unsigned int limit, head;
unsigned long avalue;
int half, qlines;
/* Determine if switching to first/second half of q */
avalue = gru_get_amo_value(cb);
head = gru_get_amo_value_head(cb);
limit = gru_get_amo_value_limit(cb);
qlines = mqd->qlines;
half = (limit != qlines);
if (half)
mqh = gru_mesq_head(qlines / 2 + 1, qlines);
else
mqh = gru_mesq_head(2, qlines / 2 + 1);
/* Try to get lock for switching head pointer */
gru_gamir(cb, EOP_IR_CLR, HSTATUS(mqd->mq_gpa, half), XTYPE_DW, IMA);
if (gru_wait(cb) != CBS_IDLE)
goto cberr;
if (!gru_get_amo_value(cb)) {
STAT(mesq_qf_locked);
return MQE_QUEUE_FULL;
}
/* Got the lock. Send optional NOP if queue not full, */
if (head != limit) {
if (send_noop_message(cb, mqd, mesg)) {
gru_gamir(cb, EOP_IR_INC, HSTATUS(mqd->mq_gpa, half),
XTYPE_DW, IMA);
if (gru_wait(cb) != CBS_IDLE)
goto cberr;
STAT(mesq_qf_noop_not_full);
return MQIE_AGAIN;
}
avalue++;
}
/* Then flip queuehead to other half of queue. */
gru_gamer(cb, EOP_ERR_CSWAP, mqd->mq_gpa, XTYPE_DW, mqh.val, avalue,
IMA);
if (gru_wait(cb) != CBS_IDLE)
goto cberr;
/* If not successfully in swapping queue head, clear the hstatus lock */
if (gru_get_amo_value(cb) != avalue) {
STAT(mesq_qf_switch_head_failed);
gru_gamir(cb, EOP_IR_INC, HSTATUS(mqd->mq_gpa, half), XTYPE_DW,
IMA);
if (gru_wait(cb) != CBS_IDLE)
goto cberr;
}
return MQIE_AGAIN;
cberr:
STAT(mesq_qf_unexpected_error);
return MQE_UNEXPECTED_CB_ERR;
}
/*
* Send a cross-partition interrupt to the SSI that contains the target
* message queue. Normally, the interrupt is automatically delivered by hardware
* but some error conditions require explicit delivery.
*/
static void send_message_queue_interrupt(struct gru_message_queue_desc *mqd)
{
if (mqd->interrupt_vector)
uv_hub_send_ipi(mqd->interrupt_pnode, mqd->interrupt_apicid,
mqd->interrupt_vector);
}
/*
* Handle a PUT failure. Note: if message was a 2-line message, one of the
* lines might have successfully have been written. Before sending the
* message, "present" must be cleared in BOTH lines to prevent the receiver
* from prematurely seeing the full message.
*/
static int send_message_put_nacked(void *cb, struct gru_message_queue_desc *mqd,
void *mesg, int lines)
{
unsigned long m;
m = mqd->mq_gpa + (gru_get_amo_value_head(cb) << 6);
if (lines == 2) {
gru_vset(cb, m, 0, XTYPE_CL, lines, 1, IMA);
if (gru_wait(cb) != CBS_IDLE)
return MQE_UNEXPECTED_CB_ERR;
}
gru_vstore(cb, m, gru_get_tri(mesg), XTYPE_CL, lines, 1, IMA);
if (gru_wait(cb) != CBS_IDLE)
return MQE_UNEXPECTED_CB_ERR;
send_message_queue_interrupt(mqd);
return MQE_OK;
}
/*
* Handle a gru_mesq failure. Some of these failures are software recoverable
* or retryable.
*/
static int send_message_failure(void *cb, struct gru_message_queue_desc *mqd,
void *mesg, int lines)
{
int substatus, ret = 0;
substatus = gru_get_cb_message_queue_substatus(cb);
switch (substatus) {
case CBSS_NO_ERROR:
STAT(mesq_send_unexpected_error);
ret = MQE_UNEXPECTED_CB_ERR;
break;
case CBSS_LB_OVERFLOWED:
STAT(mesq_send_lb_overflow);
ret = MQE_CONGESTION;
break;
case CBSS_QLIMIT_REACHED:
STAT(mesq_send_qlimit_reached);
ret = send_message_queue_full(cb, mqd, mesg, lines);
break;
case CBSS_AMO_NACKED:
STAT(mesq_send_amo_nacked);
ret = MQE_CONGESTION;
break;
case CBSS_PUT_NACKED:
STAT(mesq_send_put_nacked);
ret = send_message_put_nacked(cb, mqd, mesg, lines);
break;
default:
BUG();
}
return ret;
}
/*
* Send a message to a message queue
* mqd message queue descriptor
* mesg message. ust be vaddr within a GSEG
* bytes message size (<= 2 CL)
*/
int gru_send_message_gpa(struct gru_message_queue_desc *mqd, void *mesg,
unsigned int bytes)
{
struct message_header *mhdr;
void *cb;
void *dsr;
int istatus, clines, ret;
STAT(mesq_send);
BUG_ON(bytes < sizeof(int) || bytes > 2 * GRU_CACHE_LINE_BYTES);
clines = DIV_ROUND_UP(bytes, GRU_CACHE_LINE_BYTES);
if (gru_get_cpu_resources(bytes, &cb, &dsr))
return MQE_BUG_NO_RESOURCES;
memcpy(dsr, mesg, bytes);
mhdr = dsr;
mhdr->present = MQS_FULL;
mhdr->lines = clines;
if (clines == 2) {
mhdr->present2 = get_present2(mhdr);
restore_present2(mhdr, MQS_FULL);
}
do {
ret = MQE_OK;
gru_mesq(cb, mqd->mq_gpa, gru_get_tri(mhdr), clines, IMA);
istatus = gru_wait(cb);
if (istatus != CBS_IDLE)
ret = send_message_failure(cb, mqd, dsr, clines);
} while (ret == MQIE_AGAIN);
gru_free_cpu_resources(cb, dsr);
if (ret)
STAT(mesq_send_failed);
return ret;
}
EXPORT_SYMBOL_GPL(gru_send_message_gpa);
/*
* Advance the receive pointer for the queue to the next message.
*/
void gru_free_message(struct gru_message_queue_desc *mqd, void *mesg)
{
struct message_queue *mq = mqd->mq;
struct message_header *mhdr = mq->next;
void *next, *pnext;
int half = -1;
int lines = mhdr->lines;
if (lines == 2)
restore_present2(mhdr, MQS_EMPTY);
mhdr->present = MQS_EMPTY;
pnext = mq->next;
next = pnext + GRU_CACHE_LINE_BYTES * lines;
if (next == mq->limit) {
next = mq->start;
half = 1;
} else if (pnext < mq->start2 && next >= mq->start2) {
half = 0;
}
if (half >= 0)
mq->hstatus[half] = 1;
mq->next = next;
}
EXPORT_SYMBOL_GPL(gru_free_message);
/*
* Get next message from message queue. Return NULL if no message
* present. User must call next_message() to move to next message.
* rmq message queue
*/
void *gru_get_next_message(struct gru_message_queue_desc *mqd)
{
struct message_queue *mq = mqd->mq;
struct message_header *mhdr = mq->next;
int present = mhdr->present;
/* skip NOOP messages */
STAT(mesq_receive);
while (present == MQS_NOOP) {
gru_free_message(mqd, mhdr);
mhdr = mq->next;
present = mhdr->present;
}
/* Wait for both halves of 2 line messages */
if (present == MQS_FULL && mhdr->lines == 2 &&
get_present2(mhdr) == MQS_EMPTY)
present = MQS_EMPTY;
if (!present) {
STAT(mesq_receive_none);
return NULL;
}
if (mhdr->lines == 2)
restore_present2(mhdr, mhdr->present2);
return mhdr;
}
EXPORT_SYMBOL_GPL(gru_get_next_message);
/* ---------------------- GRU DATA COPY FUNCTIONS ---------------------------*/
/*
* Copy a block of data using the GRU resources
*/
int gru_copy_gpa(unsigned long dest_gpa, unsigned long src_gpa,
unsigned int bytes)
{
void *cb;
void *dsr;
int ret;
STAT(copy_gpa);
if (gru_get_cpu_resources(GRU_NUM_KERNEL_DSR_BYTES, &cb, &dsr))
return MQE_BUG_NO_RESOURCES;
gru_bcopy(cb, src_gpa, dest_gpa, gru_get_tri(dsr),
XTYPE_B, bytes, GRU_NUM_KERNEL_DSR_CL, IMA);
ret = gru_wait(cb);
gru_free_cpu_resources(cb, dsr);
return ret;
}
EXPORT_SYMBOL_GPL(gru_copy_gpa);
/* ------------------- KERNEL QUICKTESTS RUN AT STARTUP ----------------*/
/* Temp - will delete after we gain confidence in the GRU */
static int quicktest0(unsigned long arg)
{
unsigned long word0;
unsigned long word1;
void *cb;
void *dsr;
unsigned long *p;
int ret = -EIO;
if (gru_get_cpu_resources(GRU_CACHE_LINE_BYTES, &cb, &dsr))
return MQE_BUG_NO_RESOURCES;
p = dsr;
word0 = MAGIC;
word1 = 0;
gru_vload(cb, uv_gpa(&word0), gru_get_tri(dsr), XTYPE_DW, 1, 1, IMA);
if (gru_wait(cb) != CBS_IDLE) {
printk(KERN_DEBUG "GRU quicktest0: CBR failure 1\n");
goto done;
}
if (*p != MAGIC) {
printk(KERN_DEBUG "GRU: quicktest0 bad magic 0x%lx\n", *p);
goto done;
}
gru_vstore(cb, uv_gpa(&word1), gru_get_tri(dsr), XTYPE_DW, 1, 1, IMA);
if (gru_wait(cb) != CBS_IDLE) {
printk(KERN_DEBUG "GRU quicktest0: CBR failure 2\n");
goto done;
}
if (word0 != word1 || word1 != MAGIC) {
printk(KERN_DEBUG
"GRU quicktest0 err: found 0x%lx, expected 0x%lx\n",
word1, MAGIC);
goto done;
}
ret = 0;
done:
gru_free_cpu_resources(cb, dsr);
return ret;
}
#define ALIGNUP(p, q) ((void *)(((unsigned long)(p) + (q) - 1) & ~(q - 1)))
static int quicktest1(unsigned long arg)
{
struct gru_message_queue_desc mqd;
void *p, *mq;
unsigned long *dw;
int i, ret = -EIO;
char mes[GRU_CACHE_LINE_BYTES], *m;
/* Need 1K cacheline aligned that does not cross page boundary */
p = kmalloc(4096, 0);
mq = ALIGNUP(p, 1024);
memset(mes, 0xee, sizeof(mes));
dw = mq;
gru_create_message_queue(&mqd, mq, 8 * GRU_CACHE_LINE_BYTES, 0, 0, 0);
for (i = 0; i < 6; i++) {
mes[8] = i;
do {
ret = gru_send_message_gpa(&mqd, mes, sizeof(mes));
} while (ret == MQE_CONGESTION);
if (ret)
break;
}
if (ret != MQE_QUEUE_FULL || i != 4)
goto done;
for (i = 0; i < 6; i++) {
m = gru_get_next_message(&mqd);
if (!m || m[8] != i)
break;
gru_free_message(&mqd, m);
}
ret = (i == 4) ? 0 : -EIO;
done:
kfree(p);
return ret;
}
static int quicktest2(unsigned long arg)
{
static DECLARE_COMPLETION(cmp);
unsigned long han;
int blade_id = 0;
int numcb = 4;
int ret = 0;
unsigned long *buf;
void *cb0, *cb;
int i, k, istatus, bytes;
bytes = numcb * 4 * 8;
buf = kmalloc(bytes, GFP_KERNEL);
if (!buf)
return -ENOMEM;
ret = -EBUSY;
han = gru_reserve_async_resources(blade_id, numcb, 0, &cmp);
if (!han)
goto done;
gru_lock_async_resource(han, &cb0, NULL);
memset(buf, 0xee, bytes);
for (i = 0; i < numcb; i++)
gru_vset(cb0 + i * GRU_HANDLE_STRIDE, uv_gpa(&buf[i * 4]), 0,
XTYPE_DW, 4, 1, IMA_INTERRUPT);
ret = 0;
for (k = 0; k < numcb; k++) {
gru_wait_async_cbr(han);
for (i = 0; i < numcb; i++) {
cb = cb0 + i * GRU_HANDLE_STRIDE;
istatus = gru_check_status(cb);
if (istatus == CBS_ACTIVE)
continue;
if (istatus == CBS_EXCEPTION)
ret = -EFAULT;
else if (buf[i] || buf[i + 1] || buf[i + 2] ||
buf[i + 3])
ret = -EIO;
}
}
BUG_ON(cmp.done);
gru_unlock_async_resource(han);
gru_release_async_resources(han);
done:
kfree(buf);
return ret;
}
/*
* Debugging only. User hook for various kernel tests
* of driver & gru.
*/
int gru_ktest(unsigned long arg)
{
int ret = -EINVAL;
switch (arg & 0xff) {
case 0:
ret = quicktest0(arg);
break;
case 1:
ret = quicktest1(arg);
break;
case 2:
ret = quicktest2(arg);
break;
case 99:
ret = gru_free_kernel_contexts();
break;
}
return ret;
}
int gru_kservices_init(void)
{
return 0;
}
void gru_kservices_exit(void)
{
if (gru_free_kernel_contexts())
BUG();
}