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linux/drivers/net/ethernet/cavium/liquidio/cn23xx_vf_device.c
Prasad Kanneganti c4ee5d8103 liquidio: replace info-pointer mode with buffer-pointer-only mode 
Each Octeon output ring can DMA packets to host memory in two modes:  info-
pointer mode and buffer-pointer-only mode.  In info-pointer mode, Octeon
takes two buffer pointers for each packet and places the length of the
packet along with specified number of bytes from the beginning of the
packet into one buffer and the rest of the packet in a separate buffer.  In
buffer-pointer-only mode, Octeon takes single buffer pointer and places the
length of the packet at the beginning of the buffer followed by the packet
data.

This patch switches all Octeon output rings from info-pointer mode to
buffer-pointer-only mode.  This results in fewer DMA setups and cache line
snoops.

Signed-off-by: Prasad Kanneganti <pkanneganti@cavium.com>
Signed-off-by: Derek Chickles <derek.chickles@cavium.com>
Signed-off-by: Satanand Burla <satananda.burla@cavium.com>
Signed-off-by: Felix Manlunas <felix.manlunas@cavium.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2017-06-18 23:55:46 -04:00

712 lines
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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));
/* 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 = 0;
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;
}
void cn23xx_dump_vf_iq_regs(struct octeon_device *oct)
{
u32 regval, q_no;
dev_dbg(&oct->pci_dev->dev, "SLI_IQ_DOORBELL_0 [0x%x]: 0x%016llx\n",
CN23XX_VF_SLI_IQ_DOORBELL(0),
CVM_CAST64(octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_DOORBELL(0))));
dev_dbg(&oct->pci_dev->dev, "SLI_IQ_BASEADDR_0 [0x%x]: 0x%016llx\n",
CN23XX_VF_SLI_IQ_BASE_ADDR64(0),
CVM_CAST64(octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_BASE_ADDR64(0))));
dev_dbg(&oct->pci_dev->dev, "SLI_IQ_FIFO_RSIZE_0 [0x%x]: 0x%016llx\n",
CN23XX_VF_SLI_IQ_SIZE(0),
CVM_CAST64(octeon_read_csr64(oct, CN23XX_VF_SLI_IQ_SIZE(0))));
for (q_no = 0; q_no < oct->sriov_info.rings_per_vf; q_no++) {
dev_dbg(&oct->pci_dev->dev, "SLI_PKT[%d]_INPUT_CTL [0x%x]: 0x%016llx\n",
q_no, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no),
CVM_CAST64(octeon_read_csr64(
oct, CN23XX_VF_SLI_IQ_PKT_CONTROL64(q_no))));
}
pci_read_config_dword(oct->pci_dev, CN23XX_CONFIG_PCIE_DEVCTL, &regval);
dev_dbg(&oct->pci_dev->dev, "Config DevCtl [0x%x]: 0x%08x\n",
CN23XX_CONFIG_PCIE_DEVCTL, regval);
}
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