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|
/**********************************************************************
* Author: Cavium, Inc.
*
* Contact: support@cavium.com
* Please include "LiquidIO" in the subject.
*
* Copyright (c) 2003-2016 Cavium, Inc.
*
* This file is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License, Version 2, as
* published by the Free Software Foundation.
*
* This file is distributed in the hope that it will be useful, but
* AS-IS and WITHOUT ANY WARRANTY; without even the implied warranty
* of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE, TITLE, or
* NONINFRINGEMENT. See the GNU General Public License for more details.
***********************************************************************/
#include <linux/pci.h>
#include <linux/netdevice.h>
#include <linux/vmalloc.h>
#include "liquidio_common.h"
#include "octeon_droq.h"
#include "octeon_iq.h"
#include "response_manager.h"
#include "octeon_device.h"
#include "cn23xx_vf_device.h"
#include "octeon_main.h"
#include "octeon_mailbox.h"
u32 cn23xx_vf_get_oq_ticks(struct octeon_device *oct, u32 time_intr_in_us)
{
/* This gives the SLI clock per microsec */
u32 oqticks_per_us = (u32)oct->pfvf_hsword.coproc_tics_per_us;
/* This gives the clock cycles per millisecond */
oqticks_per_us *= 1000;
/* This gives the oq ticks (1024 core clock cycles) per millisecond */
oqticks_per_us /= 1024;
/* time_intr is in microseconds. The next 2 steps gives the oq ticks
* corressponding to time_intr.
*/
oqticks_per_us *= time_intr_in_us;
oqticks_per_us /= 1000;
return oqticks_per_us;
}
static int cn23xx_vf_reset_io_queues(struct octeon_device *oct, u32 num_queues)
{
u32 loop = BUSY_READING_REG_VF_LOOP_COUNT;
int ret_val = 0;
u32 q_no;
u64 d64;
for (q_no = 0; q_no < num_queues; q_no++) {
/* set RST bit to 1. This bit applies to both IQ and OQ */
d64 = octeon_read_csr64(oct,
CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no));
d64 |= CN23XX_PKT_INPUT_CTL_RST;
octeon_write_csr64(oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no),
d64);
}
/* wait until the RST bit is clear or the RST and QUIET bits are set */
for (q_no = 0; q_no < num_queues; q_no++) {
u64 reg_val = octeon_read_csr64(oct,
CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no));
while ((READ_ONCE(reg_val) & CN23XX_PKT_INPUT_CTL_RST) &&
!(READ_ONCE(reg_val) & CN23XX_PKT_INPUT_CTL_QUIET) &&
loop) {
WRITE_ONCE(reg_val, octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no)));
loop--;
}
if (!loop) {
dev_err(&oct->pci_dev->dev,
"clearing the reset reg failed or setting the quiet reg failed for qno: %u\n",
q_no);
return -1;
}
WRITE_ONCE(reg_val, READ_ONCE(reg_val) &
~CN23XX_PKT_INPUT_CTL_RST);
octeon_write_csr64(oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no),
READ_ONCE(reg_val));
WRITE_ONCE(reg_val, octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no)));
if (READ_ONCE(reg_val) & CN23XX_PKT_INPUT_CTL_RST) {
dev_err(&oct->pci_dev->dev,
"clearing the reset failed for qno: %u\n",
q_no);
ret_val = -1;
}
}
return ret_val;
}
static int cn23xx_vf_setup_global_input_regs(struct octeon_device *oct)
{
struct octeon_cn23xx_vf *cn23xx = (struct octeon_cn23xx_vf *)oct->chip;
struct octeon_instr_queue *iq;
u64 q_no, intr_threshold;
u64 d64;
if (cn23xx_vf_reset_io_queues(oct, oct->sriov_info.rings_per_vf))
return -1;
for (q_no = 0; q_no < (oct->sriov_info.rings_per_vf); q_no++) {
void __iomem *inst_cnt_reg;
octeon_write_csr64(oct, CN23XX_VF_SLI_IQ_DOORBELL(q_no),
0xFFFFFFFF);
iq = oct->instr_queue[q_no];
if (iq)
inst_cnt_reg = iq->inst_cnt_reg;
else
inst_cnt_reg = (u8 *)oct->mmio[0].hw_addr +
CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no);
d64 = octeon_read_csr64(oct,
CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no));
d64 &= 0xEFFFFFFFFFFFFFFFL;
octeon_write_csr64(oct, CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no),
d64);
/* Select ES, RO, NS, RDSIZE,DPTR Fomat#0 for
* the Input Queues
*/
octeon_write_csr64(oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no),
CN23XX_PKT_INPUT_CTL_MASK);
/* set the wmark level to trigger PI_INT */
intr_threshold = CFG_GET_IQ_INTR_PKT(cn23xx->conf) &
CN23XX_PKT_IN_DONE_WMARK_MASK;
writeq((readq(inst_cnt_reg) &
~(CN23XX_PKT_IN_DONE_WMARK_MASK <<
CN23XX_PKT_IN_DONE_WMARK_BIT_POS)) |
(intr_threshold << CN23XX_PKT_IN_DONE_WMARK_BIT_POS),
inst_cnt_reg);
}
return 0;
}
static void cn23xx_vf_setup_global_output_regs(struct octeon_device *oct)
{
u32 reg_val;
u32 q_no;
for (q_no = 0; q_no < (oct->sriov_info.rings_per_vf); q_no++) {
octeon_write_csr(oct, CN23XX_VF_SLI_OQ_PKTS_CREDIT(q_no),
0xFFFFFFFF);
reg_val =
octeon_read_csr(oct, CN23XX_VF_SLI_OQ_PKTS_SENT(q_no));
reg_val &= 0xEFFFFFFFFFFFFFFFL;
reg_val =
octeon_read_csr(oct, CN23XX_VF_SLI_OQ_PKT_CONTROL(q_no));
/* clear IPTR */
reg_val &= ~CN23XX_PKT_OUTPUT_CTL_IPTR;
/* set DPTR */
reg_val |= CN23XX_PKT_OUTPUT_CTL_DPTR;
/* reset BMODE */
reg_val &= ~(CN23XX_PKT_OUTPUT_CTL_BMODE);
/* No Relaxed Ordering, No Snoop, 64-bit Byte swap
* for Output Queue ScatterList reset ROR_P, NSR_P
*/
reg_val &= ~(CN23XX_PKT_OUTPUT_CTL_ROR_P);
reg_val &= ~(CN23XX_PKT_OUTPUT_CTL_NSR_P);
#ifdef __LITTLE_ENDIAN_BITFIELD
reg_val &= ~(CN23XX_PKT_OUTPUT_CTL_ES_P);
#else
reg_val |= (CN23XX_PKT_OUTPUT_CTL_ES_P);
#endif
/* No Relaxed Ordering, No Snoop, 64-bit Byte swap
* for Output Queue Data reset ROR, NSR
*/
reg_val &= ~(CN23XX_PKT_OUTPUT_CTL_ROR);
reg_val &= ~(CN23XX_PKT_OUTPUT_CTL_NSR);
/* set the ES bit */
reg_val |= (CN23XX_PKT_OUTPUT_CTL_ES);
/* write all the selected settings */
octeon_write_csr(oct, CN23XX_VF_SLI_OQ_PKT_CONTROL(q_no),
reg_val);
}
}
static int cn23xx_setup_vf_device_regs(struct octeon_device *oct)
{
if (cn23xx_vf_setup_global_input_regs(oct))
return -1;
cn23xx_vf_setup_global_output_regs(oct);
return 0;
}
static void cn23xx_setup_vf_iq_regs(struct octeon_device *oct, u32 iq_no)
{
struct octeon_instr_queue *iq = oct->instr_queue[iq_no];
u64 pkt_in_done;
/* Write the start of the input queue's ring and its size */
octeon_write_csr64(oct, CN23XX_VF_SLI_IQ_BASE_ADDR64(iq_no),
iq->base_addr_dma);
octeon_write_csr(oct, CN23XX_VF_SLI_IQ_SIZE(iq_no), iq->max_count);
/* Remember the doorbell & instruction count register addr
* for this queue
*/
iq->doorbell_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_VF_SLI_IQ_DOORBELL(iq_no);
iq->inst_cnt_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_VF_SLI_IQ_INSTR_COUNT64(iq_no);
dev_dbg(&oct->pci_dev->dev, "InstQ[%d]:dbell reg @ 0x%p instcnt_reg @ 0x%p\n",
iq_no, iq->doorbell_reg, iq->inst_cnt_reg);
/* Store the current instruction counter (used in flush_iq
* calculation)
*/
pkt_in_done = readq(iq->inst_cnt_reg);
if (oct->msix_on) {
/* Set CINT_ENB to enable IQ interrupt */
writeq((pkt_in_done | CN23XX_INTR_CINT_ENB),
iq->inst_cnt_reg);
}
iq->reset_instr_cnt = 0;
}
static void cn23xx_setup_vf_oq_regs(struct octeon_device *oct, u32 oq_no)
{
struct octeon_droq *droq = oct->droq[oq_no];
octeon_write_csr64(oct, CN23XX_VF_SLI_OQ_BASE_ADDR64(oq_no),
droq->desc_ring_dma);
octeon_write_csr(oct, CN23XX_VF_SLI_OQ_SIZE(oq_no), droq->max_count);
octeon_write_csr(oct, CN23XX_VF_SLI_OQ_BUFF_INFO_SIZE(oq_no),
droq->buffer_size);
/* Get the mapped address of the pkt_sent and pkts_credit regs */
droq->pkts_sent_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_VF_SLI_OQ_PKTS_SENT(oq_no);
droq->pkts_credit_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_VF_SLI_OQ_PKTS_CREDIT(oq_no);
}
static void cn23xx_vf_mbox_thread(struct work_struct *work)
{
struct cavium_wk *wk = (struct cavium_wk *)work;
struct octeon_mbox *mbox = (struct octeon_mbox *)wk->ctxptr;
octeon_mbox_process_message(mbox);
}
static int cn23xx_free_vf_mbox(struct octeon_device *oct)
{
cancel_delayed_work_sync(&oct->mbox[0]->mbox_poll_wk.work);
vfree(oct->mbox[0]);
return 0;
}
static int cn23xx_setup_vf_mbox(struct octeon_device *oct)
{
struct octeon_mbox *mbox = NULL;
mbox = vmalloc(sizeof(*mbox));
if (!mbox)
return 1;
memset(mbox, 0, sizeof(struct octeon_mbox));
spin_lock_init(&mbox->lock);
mbox->oct_dev = oct;
mbox->q_no = 0;
mbox->state = OCTEON_MBOX_STATE_IDLE;
/* VF mbox interrupt reg */
mbox->mbox_int_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_VF_SLI_PKT_MBOX_INT(0);
/* VF reads from SIG0 reg */
mbox->mbox_read_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_SLI_PKT_PF_VF_MBOX_SIG(0, 0);
/* VF writes into SIG1 reg */
mbox->mbox_write_reg =
(u8 *)oct->mmio[0].hw_addr + CN23XX_SLI_PKT_PF_VF_MBOX_SIG(0, 1);
INIT_DELAYED_WORK(&mbox->mbox_poll_wk.work,
cn23xx_vf_mbox_thread);
mbox->mbox_poll_wk.ctxptr = mbox;
oct->mbox[0] = mbox;
writeq(OCTEON_PFVFSIG, mbox->mbox_read_reg);
return 0;
}
static int cn23xx_enable_vf_io_queues(struct octeon_device *oct)
{
u32 q_no;
for (q_no = 0; q_no < oct->num_iqs; q_no++) {
u64 reg_val;
/* set the corresponding IQ IS_64B bit */
if (oct->io_qmask.iq64B & BIT_ULL(q_no)) {
reg_val = octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no));
reg_val |= CN23XX_PKT_INPUT_CTL_IS_64B;
octeon_write_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no), reg_val);
}
/* set the corresponding IQ ENB bit */
if (oct->io_qmask.iq & BIT_ULL(q_no)) {
reg_val = octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no));
reg_val |= CN23XX_PKT_INPUT_CTL_RING_ENB;
octeon_write_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no), reg_val);
}
}
for (q_no = 0; q_no < oct->num_oqs; q_no++) {
u32 reg_val;
/* set the corresponding OQ ENB bit */
if (oct->io_qmask.oq & BIT_ULL(q_no)) {
reg_val = octeon_read_csr(
oct, CN23XX_VF_SLI_OQ_PKT_CONTROL(q_no));
reg_val |= CN23XX_PKT_OUTPUT_CTL_RING_ENB;
octeon_write_csr(
oct, CN23XX_VF_SLI_OQ_PKT_CONTROL(q_no), reg_val);
}
}
return 0;
}
static void cn23xx_disable_vf_io_queues(struct octeon_device *oct)
{
u32 num_queues = oct->num_iqs;
/* per HRM, rings can only be disabled via reset operation,
* NOT via SLI_PKT()_INPUT/OUTPUT_CONTROL[ENB]
*/
if (num_queues < oct->num_oqs)
num_queues = oct->num_oqs;
cn23xx_vf_reset_io_queues(oct, num_queues);
}
void cn23xx_vf_ask_pf_to_do_flr(struct octeon_device *oct)
{
struct octeon_mbox_cmd mbox_cmd;
mbox_cmd.msg.u64 = 0;
mbox_cmd.msg.s.type = OCTEON_MBOX_REQUEST;
mbox_cmd.msg.s.resp_needed = 0;
mbox_cmd.msg.s.cmd = OCTEON_VF_FLR_REQUEST;
mbox_cmd.msg.s.len = 1;
mbox_cmd.q_no = 0;
mbox_cmd.recv_len = 0;
mbox_cmd.recv_status = 0;
mbox_cmd.fn = NULL;
mbox_cmd.fn_arg = NULL;
octeon_mbox_write(oct, &mbox_cmd);
}
static void octeon_pfvf_hs_callback(struct octeon_device *oct,
struct octeon_mbox_cmd *cmd,
void *arg)
{
u32 major = 0;
memcpy((uint8_t *)&oct->pfvf_hsword, cmd->msg.s.params,
CN23XX_MAILBOX_MSGPARAM_SIZE);
if (cmd->recv_len > 1) {
major = ((struct lio_version *)(cmd->data))->major;
major = major << 16;
}
atomic_set((atomic_t *)arg, major | 1);
}
int cn23xx_octeon_pfvf_handshake(struct octeon_device *oct)
{
struct octeon_mbox_cmd mbox_cmd;
u32 q_no, count = 0;
atomic_t status;
u32 pfmajor;
u32 vfmajor;
u32 ret;
/* Sending VF_ACTIVE indication to the PF driver */
dev_dbg(&oct->pci_dev->dev, "requesting info from pf\n");
mbox_cmd.msg.u64 = 0;
mbox_cmd.msg.s.type = OCTEON_MBOX_REQUEST;
mbox_cmd.msg.s.resp_needed = 1;
mbox_cmd.msg.s.cmd = OCTEON_VF_ACTIVE;
mbox_cmd.msg.s.len = 2;
mbox_cmd.data[0] = 0;
((struct lio_version *)&mbox_cmd.data[0])->major =
LIQUIDIO_BASE_MAJOR_VERSION;
((struct lio_version *)&mbox_cmd.data[0])->minor =
LIQUIDIO_BASE_MINOR_VERSION;
((struct lio_version *)&mbox_cmd.data[0])->micro =
LIQUIDIO_BASE_MICRO_VERSION;
mbox_cmd.q_no = 0;
mbox_cmd.recv_len = 0;
mbox_cmd.recv_status = 0;
mbox_cmd.fn = (octeon_mbox_callback_t)octeon_pfvf_hs_callback;
mbox_cmd.fn_arg = &status;
octeon_mbox_write(oct, &mbox_cmd);
atomic_set(&status, 0);
do {
schedule_timeout_uninterruptible(1);
} while ((!atomic_read(&status)) && (count++ < 100000));
ret = atomic_read(&status);
if (!ret) {
dev_err(&oct->pci_dev->dev, "octeon_pfvf_handshake timeout\n");
return 1;
}
for (q_no = 0 ; q_no < oct->num_iqs ; q_no++)
oct->instr_queue[q_no]->txpciq.s.pkind = oct->pfvf_hsword.pkind;
vfmajor = LIQUIDIO_BASE_MAJOR_VERSION;
pfmajor = ret >> 16;
if (pfmajor != vfmajor) {
dev_err(&oct->pci_dev->dev,
"VF Liquidio driver (major version %d) is not compatible with Liquidio PF driver (major version %d)\n",
vfmajor, pfmajor);
return 1;
}
dev_dbg(&oct->pci_dev->dev,
"VF Liquidio driver (major version %d), Liquidio PF driver (major version %d)\n",
vfmajor, pfmajor);
dev_dbg(&oct->pci_dev->dev, "got data from pf pkind is %d\n",
oct->pfvf_hsword.pkind);
return 0;
}
static void cn23xx_handle_vf_mbox_intr(struct octeon_ioq_vector *ioq_vector)
{
struct octeon_device *oct = ioq_vector->oct_dev;
u64 mbox_int_val;
if (!ioq_vector->droq_index) {
/* read and clear by writing 1 */
mbox_int_val = readq(oct->mbox[0]->mbox_int_reg);
writeq(mbox_int_val, oct->mbox[0]->mbox_int_reg);
if (octeon_mbox_read(oct->mbox[0]))
schedule_delayed_work(&oct->mbox[0]->mbox_poll_wk.work,
msecs_to_jiffies(0));
}
}
static u64 cn23xx_vf_msix_interrupt_handler(void *dev)
{
struct octeon_ioq_vector *ioq_vector = (struct octeon_ioq_vector *)dev;
struct octeon_device *oct = ioq_vector->oct_dev;
struct octeon_droq *droq = oct->droq[ioq_vector->droq_index];
u64 pkts_sent;
u64 ret = 0;
dev_dbg(&oct->pci_dev->dev, "In %s octeon_dev @ %p\n", __func__, oct);
pkts_sent = readq(droq->pkts_sent_reg);
/* If our device has interrupted, then proceed. Also check
* for all f's if interrupt was triggered on an error
* and the PCI read fails.
*/
if (!pkts_sent || (pkts_sent == 0xFFFFFFFFFFFFFFFFULL))
return ret;
/* Write count reg in sli_pkt_cnts to clear these int. */
if ((pkts_sent & CN23XX_INTR_PO_INT) ||
(pkts_sent & CN23XX_INTR_PI_INT)) {
if (pkts_sent & CN23XX_INTR_PO_INT)
ret |= MSIX_PO_INT;
}
if (pkts_sent & CN23XX_INTR_PI_INT)
/* We will clear the count when we update the read_index. */
ret |= MSIX_PI_INT;
if (pkts_sent & CN23XX_INTR_MBOX_INT) {
cn23xx_handle_vf_mbox_intr(ioq_vector);
ret |= MSIX_MBOX_INT;
}
return ret;
}
static u32 cn23xx_update_read_index(struct octeon_instr_queue *iq)
{
u32 pkt_in_done = readl(iq->inst_cnt_reg);
u32 last_done;
u32 new_idx;
last_done = pkt_in_done - iq->pkt_in_done;
iq->pkt_in_done = pkt_in_done;
/* Modulo of the new index with the IQ size will give us
* the new index. The iq->reset_instr_cnt is always zero for
* cn23xx, so no extra adjustments are needed.
*/
new_idx = (iq->octeon_read_index +
(u32)(last_done & CN23XX_PKT_IN_DONE_CNT_MASK)) %
iq->max_count;
return new_idx;
}
static void cn23xx_enable_vf_interrupt(struct octeon_device *oct, u8 intr_flag)
{
struct octeon_cn23xx_vf *cn23xx = (struct octeon_cn23xx_vf *)oct->chip;
u32 q_no, time_threshold;
if (intr_flag & OCTEON_OUTPUT_INTR) {
for (q_no = 0; q_no < oct->num_oqs; q_no++) {
/* Set up interrupt packet and time thresholds
* for all the OQs
*/
time_threshold = cn23xx_vf_get_oq_ticks(
oct, (u32)CFG_GET_OQ_INTR_TIME(cn23xx->conf));
octeon_write_csr64(
oct, CN23XX_VF_SLI_OQ_PKT_INT_LEVELS(q_no),
(CFG_GET_OQ_INTR_PKT(cn23xx->conf) |
((u64)time_threshold << 32)));
}
}
if (intr_flag & OCTEON_INPUT_INTR) {
for (q_no = 0; q_no < oct->num_oqs; q_no++) {
/* Set CINT_ENB to enable IQ interrupt */
octeon_write_csr64(
oct, CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no),
((octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no)) &
~CN23XX_PKT_IN_DONE_CNT_MASK) |
CN23XX_INTR_CINT_ENB));
}
}
/* Set queue-0 MBOX_ENB to enable VF mailbox interrupt */
if (intr_flag & OCTEON_MBOX_INTR) {
octeon_write_csr64(
oct, CN23XX_VF_SLI_PKT_MBOX_INT(0),
(octeon_read_csr64(oct, CN23XX_VF_SLI_PKT_MBOX_INT(0)) |
CN23XX_INTR_MBOX_ENB));
}
}
static void cn23xx_disable_vf_interrupt(struct octeon_device *oct, u8 intr_flag)
{
u32 q_no;
if (intr_flag & OCTEON_OUTPUT_INTR) {
for (q_no = 0; q_no < oct->num_oqs; q_no++) {
/* Write all 1's in INT_LEVEL reg to disable PO_INT */
octeon_write_csr64(
oct, CN23XX_VF_SLI_OQ_PKT_INT_LEVELS(q_no),
0x3fffffffffffff);
}
}
if (intr_flag & OCTEON_INPUT_INTR) {
for (q_no = 0; q_no < oct->num_oqs; q_no++) {
octeon_write_csr64(
oct, CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no),
(octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_INSTR_COUNT64(q_no)) &
~(CN23XX_INTR_CINT_ENB |
CN23XX_PKT_IN_DONE_CNT_MASK)));
}
}
if (intr_flag & OCTEON_MBOX_INTR) {
octeon_write_csr64(
oct, CN23XX_VF_SLI_PKT_MBOX_INT(0),
(octeon_read_csr64(oct, CN23XX_VF_SLI_PKT_MBOX_INT(0)) &
~CN23XX_INTR_MBOX_ENB));
}
}
int cn23xx_setup_octeon_vf_device(struct octeon_device *oct)
{
struct octeon_cn23xx_vf *cn23xx = (struct octeon_cn23xx_vf *)oct->chip;
u32 rings_per_vf, ring_flag;
u64 reg_val;
if (octeon_map_pci_barx(oct, 0, 0))
return 1;
/* INPUT_CONTROL[RPVF] gives the VF IOq count */
reg_val = octeon_read_csr64(oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(0));
oct->pf_num = (reg_val >> CN23XX_PKT_INPUT_CTL_PF_NUM_POS) &
CN23XX_PKT_INPUT_CTL_PF_NUM_MASK;
oct->vf_num = (reg_val >> CN23XX_PKT_INPUT_CTL_VF_NUM_POS) &
CN23XX_PKT_INPUT_CTL_VF_NUM_MASK;
reg_val = reg_val >> CN23XX_PKT_INPUT_CTL_RPVF_POS;
rings_per_vf = reg_val & CN23XX_PKT_INPUT_CTL_RPVF_MASK;
ring_flag = 0;
cn23xx->conf = oct_get_config_info(oct, LIO_23XX);
if (!cn23xx->conf) {
dev_err(&oct->pci_dev->dev, "%s No Config found for CN23XX\n",
__func__);
octeon_unmap_pci_barx(oct, 0);
return 1;
}
if (oct->sriov_info.rings_per_vf > rings_per_vf) {
dev_warn(&oct->pci_dev->dev,
"num_queues:%d greater than PF configured rings_per_vf:%d. Reducing to %d.\n",
oct->sriov_info.rings_per_vf, rings_per_vf,
rings_per_vf);
oct->sriov_info.rings_per_vf = rings_per_vf;
} else {
if (rings_per_vf > num_present_cpus()) {
dev_warn(&oct->pci_dev->dev,
"PF configured rings_per_vf:%d greater than num_cpu:%d. Using rings_per_vf:%d equal to num cpus\n",
rings_per_vf,
num_present_cpus(),
num_present_cpus());
oct->sriov_info.rings_per_vf =
num_present_cpus();
} else {
oct->sriov_info.rings_per_vf = rings_per_vf;
}
}
oct->fn_list.setup_iq_regs = cn23xx_setup_vf_iq_regs;
oct->fn_list.setup_oq_regs = cn23xx_setup_vf_oq_regs;
oct->fn_list.setup_mbox = cn23xx_setup_vf_mbox;
oct->fn_list.free_mbox = cn23xx_free_vf_mbox;
oct->fn_list.msix_interrupt_handler = cn23xx_vf_msix_interrupt_handler;
oct->fn_list.setup_device_regs = cn23xx_setup_vf_device_regs;
oct->fn_list.update_iq_read_idx = cn23xx_update_read_index;
oct->fn_list.enable_interrupt = cn23xx_enable_vf_interrupt;
oct->fn_list.disable_interrupt = cn23xx_disable_vf_interrupt;
oct->fn_list.enable_io_queues = cn23xx_enable_vf_io_queues;
oct->fn_list.disable_io_queues = cn23xx_disable_vf_io_queues;
return 0;
}
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