linux/drivers/net/bna/bna_txrx.c
David S. Miller 5859854290 bna: Fix set-but-unused variables.
The variable 'pgoff' is set but unused in bfa_nw_ioc_fwver_get()
and bfa_ioc_download_fw().

Similarly for 'cmd_h' in bna_mbox_flush_q and the entirety of
bna_rit_mod_uninit() is unused since variables are purely set but no
action is made using them.

Same for 'bna' in bna_rit_create() and 'ret' in bna_rx_create().

Just kill them off.

Signed-off-by: David S. Miller <davem@davemloft.net>
2011-04-17 16:54:08 -07:00

4186 lines
101 KiB
C

/*
* Linux network driver for Brocade Converged Network Adapter.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License (GPL) Version 2 as
* published by the Free Software Foundation
*
* 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.
*/
/*
* Copyright (c) 2005-2010 Brocade Communications Systems, Inc.
* All rights reserved
* www.brocade.com
*/
#include "bna.h"
#include "bfa_sm.h"
#include "bfi.h"
/**
* IB
*/
#define bna_ib_find_free_ibidx(_mask, _pos)\
do {\
(_pos) = 0;\
while (((_pos) < (BFI_IBIDX_MAX_SEGSIZE)) &&\
((1 << (_pos)) & (_mask)))\
(_pos)++;\
} while (0)
#define bna_ib_count_ibidx(_mask, _count)\
do {\
int pos = 0;\
(_count) = 0;\
while (pos < (BFI_IBIDX_MAX_SEGSIZE)) {\
if ((1 << pos) & (_mask))\
(_count) = pos + 1;\
pos++;\
} \
} while (0)
#define bna_ib_select_segpool(_count, _q_idx)\
do {\
int i;\
(_q_idx) = -1;\
for (i = 0; i < BFI_IBIDX_TOTAL_POOLS; i++) {\
if ((_count <= ibidx_pool[i].pool_entry_size)) {\
(_q_idx) = i;\
break;\
} \
} \
} while (0)
struct bna_ibidx_pool {
int pool_size;
int pool_entry_size;
};
init_ibidx_pool(ibidx_pool);
static struct bna_intr *
bna_intr_get(struct bna_ib_mod *ib_mod, enum bna_intr_type intr_type,
int vector)
{
struct bna_intr *intr;
struct list_head *qe;
list_for_each(qe, &ib_mod->intr_active_q) {
intr = (struct bna_intr *)qe;
if ((intr->intr_type == intr_type) &&
(intr->vector == vector)) {
intr->ref_count++;
return intr;
}
}
if (list_empty(&ib_mod->intr_free_q))
return NULL;
bfa_q_deq(&ib_mod->intr_free_q, &intr);
bfa_q_qe_init(&intr->qe);
intr->ref_count = 1;
intr->intr_type = intr_type;
intr->vector = vector;
list_add_tail(&intr->qe, &ib_mod->intr_active_q);
return intr;
}
static void
bna_intr_put(struct bna_ib_mod *ib_mod,
struct bna_intr *intr)
{
intr->ref_count--;
if (intr->ref_count == 0) {
intr->ib = NULL;
list_del(&intr->qe);
bfa_q_qe_init(&intr->qe);
list_add_tail(&intr->qe, &ib_mod->intr_free_q);
}
}
void
bna_ib_mod_init(struct bna_ib_mod *ib_mod, struct bna *bna,
struct bna_res_info *res_info)
{
int i;
int j;
int count;
u8 offset;
struct bna_doorbell_qset *qset;
unsigned long off;
ib_mod->bna = bna;
ib_mod->ib = (struct bna_ib *)
res_info[BNA_RES_MEM_T_IB_ARRAY].res_u.mem_info.mdl[0].kva;
ib_mod->intr = (struct bna_intr *)
res_info[BNA_RES_MEM_T_INTR_ARRAY].res_u.mem_info.mdl[0].kva;
ib_mod->idx_seg = (struct bna_ibidx_seg *)
res_info[BNA_RES_MEM_T_IDXSEG_ARRAY].res_u.mem_info.mdl[0].kva;
INIT_LIST_HEAD(&ib_mod->ib_free_q);
INIT_LIST_HEAD(&ib_mod->intr_free_q);
INIT_LIST_HEAD(&ib_mod->intr_active_q);
for (i = 0; i < BFI_IBIDX_TOTAL_POOLS; i++)
INIT_LIST_HEAD(&ib_mod->ibidx_seg_pool[i]);
for (i = 0; i < BFI_MAX_IB; i++) {
ib_mod->ib[i].ib_id = i;
ib_mod->ib[i].ib_seg_host_addr_kva =
res_info[BNA_RES_MEM_T_IBIDX].res_u.mem_info.mdl[i].kva;
ib_mod->ib[i].ib_seg_host_addr.lsb =
res_info[BNA_RES_MEM_T_IBIDX].res_u.mem_info.mdl[i].dma.lsb;
ib_mod->ib[i].ib_seg_host_addr.msb =
res_info[BNA_RES_MEM_T_IBIDX].res_u.mem_info.mdl[i].dma.msb;
qset = (struct bna_doorbell_qset *)0;
off = (unsigned long)(&qset[i >> 1].ib0[(i & 0x1)
* (0x20 >> 2)]);
ib_mod->ib[i].door_bell.doorbell_addr = off +
BNA_GET_DOORBELL_BASE_ADDR(bna->pcidev.pci_bar_kva);
bfa_q_qe_init(&ib_mod->ib[i].qe);
list_add_tail(&ib_mod->ib[i].qe, &ib_mod->ib_free_q);
bfa_q_qe_init(&ib_mod->intr[i].qe);
list_add_tail(&ib_mod->intr[i].qe, &ib_mod->intr_free_q);
}
count = 0;
offset = 0;
for (i = 0; i < BFI_IBIDX_TOTAL_POOLS; i++) {
for (j = 0; j < ibidx_pool[i].pool_size; j++) {
bfa_q_qe_init(&ib_mod->idx_seg[count]);
ib_mod->idx_seg[count].ib_seg_size =
ibidx_pool[i].pool_entry_size;
ib_mod->idx_seg[count].ib_idx_tbl_offset = offset;
list_add_tail(&ib_mod->idx_seg[count].qe,
&ib_mod->ibidx_seg_pool[i]);
count++;
offset += ibidx_pool[i].pool_entry_size;
}
}
}
void
bna_ib_mod_uninit(struct bna_ib_mod *ib_mod)
{
int i;
int j;
struct list_head *qe;
i = 0;
list_for_each(qe, &ib_mod->ib_free_q)
i++;
i = 0;
list_for_each(qe, &ib_mod->intr_free_q)
i++;
for (i = 0; i < BFI_IBIDX_TOTAL_POOLS; i++) {
j = 0;
list_for_each(qe, &ib_mod->ibidx_seg_pool[i])
j++;
}
ib_mod->bna = NULL;
}
static struct bna_ib *
bna_ib_get(struct bna_ib_mod *ib_mod,
enum bna_intr_type intr_type,
int vector)
{
struct bna_ib *ib;
struct bna_intr *intr;
if (intr_type == BNA_INTR_T_INTX)
vector = (1 << vector);
intr = bna_intr_get(ib_mod, intr_type, vector);
if (intr == NULL)
return NULL;
if (intr->ib) {
if (intr->ib->ref_count == BFI_IBIDX_MAX_SEGSIZE) {
bna_intr_put(ib_mod, intr);
return NULL;
}
intr->ib->ref_count++;
return intr->ib;
}
if (list_empty(&ib_mod->ib_free_q)) {
bna_intr_put(ib_mod, intr);
return NULL;
}
bfa_q_deq(&ib_mod->ib_free_q, &ib);
bfa_q_qe_init(&ib->qe);
ib->ref_count = 1;
ib->start_count = 0;
ib->idx_mask = 0;
ib->intr = intr;
ib->idx_seg = NULL;
intr->ib = ib;
ib->bna = ib_mod->bna;
return ib;
}
static void
bna_ib_put(struct bna_ib_mod *ib_mod, struct bna_ib *ib)
{
bna_intr_put(ib_mod, ib->intr);
ib->ref_count--;
if (ib->ref_count == 0) {
ib->intr = NULL;
ib->bna = NULL;
list_add_tail(&ib->qe, &ib_mod->ib_free_q);
}
}
/* Returns index offset - starting from 0 */
static int
bna_ib_reserve_idx(struct bna_ib *ib)
{
struct bna_ib_mod *ib_mod = &ib->bna->ib_mod;
struct bna_ibidx_seg *idx_seg;
int idx;
int num_idx;
int q_idx;
/* Find the first free index position */
bna_ib_find_free_ibidx(ib->idx_mask, idx);
if (idx == BFI_IBIDX_MAX_SEGSIZE)
return -1;
/*
* Calculate the total number of indexes held by this IB,
* including the index newly reserved above.
*/
bna_ib_count_ibidx((ib->idx_mask | (1 << idx)), num_idx);
/* See if there is a free space in the index segment held by this IB */
if (ib->idx_seg && (num_idx <= ib->idx_seg->ib_seg_size)) {
ib->idx_mask |= (1 << idx);
return idx;
}
if (ib->start_count)
return -1;
/* Allocate a new segment */
bna_ib_select_segpool(num_idx, q_idx);
while (1) {
if (q_idx == BFI_IBIDX_TOTAL_POOLS)
return -1;
if (!list_empty(&ib_mod->ibidx_seg_pool[q_idx]))
break;
q_idx++;
}
bfa_q_deq(&ib_mod->ibidx_seg_pool[q_idx], &idx_seg);
bfa_q_qe_init(&idx_seg->qe);
/* Free the old segment */
if (ib->idx_seg) {
bna_ib_select_segpool(ib->idx_seg->ib_seg_size, q_idx);
list_add_tail(&ib->idx_seg->qe, &ib_mod->ibidx_seg_pool[q_idx]);
}
ib->idx_seg = idx_seg;
ib->idx_mask |= (1 << idx);
return idx;
}
static void
bna_ib_release_idx(struct bna_ib *ib, int idx)
{
struct bna_ib_mod *ib_mod = &ib->bna->ib_mod;
struct bna_ibidx_seg *idx_seg;
int num_idx;
int cur_q_idx;
int new_q_idx;
ib->idx_mask &= ~(1 << idx);
if (ib->start_count)
return;
bna_ib_count_ibidx(ib->idx_mask, num_idx);
/*
* Free the segment, if there are no more indexes in the segment
* held by this IB
*/
if (!num_idx) {
bna_ib_select_segpool(ib->idx_seg->ib_seg_size, cur_q_idx);
list_add_tail(&ib->idx_seg->qe,
&ib_mod->ibidx_seg_pool[cur_q_idx]);
ib->idx_seg = NULL;
return;
}
/* See if we can move to a smaller segment */
bna_ib_select_segpool(num_idx, new_q_idx);
bna_ib_select_segpool(ib->idx_seg->ib_seg_size, cur_q_idx);
while (new_q_idx < cur_q_idx) {
if (!list_empty(&ib_mod->ibidx_seg_pool[new_q_idx]))
break;
new_q_idx++;
}
if (new_q_idx < cur_q_idx) {
/* Select the new smaller segment */
bfa_q_deq(&ib_mod->ibidx_seg_pool[new_q_idx], &idx_seg);
bfa_q_qe_init(&idx_seg->qe);
/* Free the old segment */
list_add_tail(&ib->idx_seg->qe,
&ib_mod->ibidx_seg_pool[cur_q_idx]);
ib->idx_seg = idx_seg;
}
}
static int
bna_ib_config(struct bna_ib *ib, struct bna_ib_config *ib_config)
{
if (ib->start_count)
return -1;
ib->ib_config.coalescing_timeo = ib_config->coalescing_timeo;
ib->ib_config.interpkt_timeo = ib_config->interpkt_timeo;
ib->ib_config.interpkt_count = ib_config->interpkt_count;
ib->ib_config.ctrl_flags = ib_config->ctrl_flags;
ib->ib_config.ctrl_flags |= BFI_IB_CF_MASTER_ENABLE;
if (ib->intr->intr_type == BNA_INTR_T_MSIX)
ib->ib_config.ctrl_flags |= BFI_IB_CF_MSIX_MODE;
return 0;
}
static void
bna_ib_start(struct bna_ib *ib)
{
struct bna_ib_blk_mem ib_cfg;
struct bna_ib_blk_mem *ib_mem;
u32 pg_num;
u32 intx_mask;
int i;
void __iomem *base_addr;
unsigned long off;
ib->start_count++;
if (ib->start_count > 1)
return;
ib_cfg.host_addr_lo = (u32)(ib->ib_seg_host_addr.lsb);
ib_cfg.host_addr_hi = (u32)(ib->ib_seg_host_addr.msb);
ib_cfg.clsc_n_ctrl_n_msix = (((u32)
ib->ib_config.coalescing_timeo << 16) |
((u32)ib->ib_config.ctrl_flags << 8) |
(ib->intr->vector));
ib_cfg.ipkt_n_ent_n_idxof =
((u32)
(ib->ib_config.interpkt_timeo & 0xf) << 16) |
((u32)ib->idx_seg->ib_seg_size << 8) |
(ib->idx_seg->ib_idx_tbl_offset);
ib_cfg.ipkt_cnt_cfg_n_unacked = ((u32)
ib->ib_config.interpkt_count << 24);
pg_num = BNA_GET_PAGE_NUM(HQM0_BLK_PG_NUM + ib->bna->port_num,
HQM_IB_RAM_BASE_OFFSET);
writel(pg_num, ib->bna->regs.page_addr);
base_addr = BNA_GET_MEM_BASE_ADDR(ib->bna->pcidev.pci_bar_kva,
HQM_IB_RAM_BASE_OFFSET);
ib_mem = (struct bna_ib_blk_mem *)0;
off = (unsigned long)&ib_mem[ib->ib_id].host_addr_lo;
writel(htonl(ib_cfg.host_addr_lo), base_addr + off);
off = (unsigned long)&ib_mem[ib->ib_id].host_addr_hi;
writel(htonl(ib_cfg.host_addr_hi), base_addr + off);
off = (unsigned long)&ib_mem[ib->ib_id].clsc_n_ctrl_n_msix;
writel(ib_cfg.clsc_n_ctrl_n_msix, base_addr + off);
off = (unsigned long)&ib_mem[ib->ib_id].ipkt_n_ent_n_idxof;
writel(ib_cfg.ipkt_n_ent_n_idxof, base_addr + off);
off = (unsigned long)&ib_mem[ib->ib_id].ipkt_cnt_cfg_n_unacked;
writel(ib_cfg.ipkt_cnt_cfg_n_unacked, base_addr + off);
ib->door_bell.doorbell_ack = BNA_DOORBELL_IB_INT_ACK(
(u32)ib->ib_config.coalescing_timeo, 0);
pg_num = BNA_GET_PAGE_NUM(HQM0_BLK_PG_NUM + ib->bna->port_num,
HQM_INDX_TBL_RAM_BASE_OFFSET);
writel(pg_num, ib->bna->regs.page_addr);
base_addr = BNA_GET_MEM_BASE_ADDR(ib->bna->pcidev.pci_bar_kva,
HQM_INDX_TBL_RAM_BASE_OFFSET);
for (i = 0; i < ib->idx_seg->ib_seg_size; i++) {
off = (unsigned long)
((ib->idx_seg->ib_idx_tbl_offset + i) * BFI_IBIDX_SIZE);
writel(0, base_addr + off);
}
if (ib->intr->intr_type == BNA_INTR_T_INTX) {
bna_intx_disable(ib->bna, intx_mask);
intx_mask &= ~(ib->intr->vector);
bna_intx_enable(ib->bna, intx_mask);
}
}
static void
bna_ib_stop(struct bna_ib *ib)
{
u32 intx_mask;
ib->start_count--;
if (ib->start_count == 0) {
writel(BNA_DOORBELL_IB_INT_DISABLE,
ib->door_bell.doorbell_addr);
if (ib->intr->intr_type == BNA_INTR_T_INTX) {
bna_intx_disable(ib->bna, intx_mask);
intx_mask |= (ib->intr->vector);
bna_intx_enable(ib->bna, intx_mask);
}
}
}
static void
bna_ib_fail(struct bna_ib *ib)
{
ib->start_count = 0;
}
/**
* RXF
*/
static void rxf_enable(struct bna_rxf *rxf);
static void rxf_disable(struct bna_rxf *rxf);
static void __rxf_config_set(struct bna_rxf *rxf);
static void __rxf_rit_set(struct bna_rxf *rxf);
static void __bna_rxf_stat_clr(struct bna_rxf *rxf);
static int rxf_process_packet_filter(struct bna_rxf *rxf);
static int rxf_clear_packet_filter(struct bna_rxf *rxf);
static void rxf_reset_packet_filter(struct bna_rxf *rxf);
static void rxf_cb_enabled(void *arg, int status);
static void rxf_cb_disabled(void *arg, int status);
static void bna_rxf_cb_stats_cleared(void *arg, int status);
static void __rxf_enable(struct bna_rxf *rxf);
static void __rxf_disable(struct bna_rxf *rxf);
bfa_fsm_state_decl(bna_rxf, stopped, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, start_wait, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, cam_fltr_mod_wait, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, started, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, cam_fltr_clr_wait, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, stop_wait, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, pause_wait, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, resume_wait, struct bna_rxf,
enum bna_rxf_event);
bfa_fsm_state_decl(bna_rxf, stat_clr_wait, struct bna_rxf,
enum bna_rxf_event);
static struct bfa_sm_table rxf_sm_table[] = {
{BFA_SM(bna_rxf_sm_stopped), BNA_RXF_STOPPED},
{BFA_SM(bna_rxf_sm_start_wait), BNA_RXF_START_WAIT},
{BFA_SM(bna_rxf_sm_cam_fltr_mod_wait), BNA_RXF_CAM_FLTR_MOD_WAIT},
{BFA_SM(bna_rxf_sm_started), BNA_RXF_STARTED},
{BFA_SM(bna_rxf_sm_cam_fltr_clr_wait), BNA_RXF_CAM_FLTR_CLR_WAIT},
{BFA_SM(bna_rxf_sm_stop_wait), BNA_RXF_STOP_WAIT},
{BFA_SM(bna_rxf_sm_pause_wait), BNA_RXF_PAUSE_WAIT},
{BFA_SM(bna_rxf_sm_resume_wait), BNA_RXF_RESUME_WAIT},
{BFA_SM(bna_rxf_sm_stat_clr_wait), BNA_RXF_STAT_CLR_WAIT}
};
static void
bna_rxf_sm_stopped_entry(struct bna_rxf *rxf)
{
call_rxf_stop_cbfn(rxf, BNA_CB_SUCCESS);
}
static void
bna_rxf_sm_stopped(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_START:
bfa_fsm_set_state(rxf, bna_rxf_sm_start_wait);
break;
case RXF_E_STOP:
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_FAIL:
/* No-op */
break;
case RXF_E_CAM_FLTR_MOD:
call_rxf_cam_fltr_cbfn(rxf, BNA_CB_SUCCESS);
break;
case RXF_E_STARTED:
case RXF_E_STOPPED:
case RXF_E_CAM_FLTR_RESP:
/**
* These events are received due to flushing of mbox
* when device fails
*/
/* No-op */
break;
case RXF_E_PAUSE:
rxf->rxf_oper_state = BNA_RXF_OPER_STATE_PAUSED;
call_rxf_pause_cbfn(rxf, BNA_CB_SUCCESS);
break;
case RXF_E_RESUME:
rxf->rxf_oper_state = BNA_RXF_OPER_STATE_RUNNING;
call_rxf_resume_cbfn(rxf, BNA_CB_SUCCESS);
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_start_wait_entry(struct bna_rxf *rxf)
{
__rxf_config_set(rxf);
__rxf_rit_set(rxf);
rxf_enable(rxf);
}
static void
bna_rxf_sm_start_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_STOP:
/**
* STOP is originated from bnad. When this happens,
* it can not be waiting for filter update
*/
call_rxf_start_cbfn(rxf, BNA_CB_INTERRUPT);
bfa_fsm_set_state(rxf, bna_rxf_sm_stop_wait);
break;
case RXF_E_FAIL:
call_rxf_cam_fltr_cbfn(rxf, BNA_CB_SUCCESS);
call_rxf_start_cbfn(rxf, BNA_CB_FAIL);
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_CAM_FLTR_MOD:
/* No-op */
break;
case RXF_E_STARTED:
/**
* Force rxf_process_filter() to go through initial
* config
*/
if ((rxf->ucast_active_mac != NULL) &&
(rxf->ucast_pending_set == 0))
rxf->ucast_pending_set = 1;
if (rxf->rss_status == BNA_STATUS_T_ENABLED)
rxf->rxf_flags |= BNA_RXF_FL_RSS_CONFIG_PENDING;
rxf->rxf_flags |= BNA_RXF_FL_VLAN_CONFIG_PENDING;
bfa_fsm_set_state(rxf, bna_rxf_sm_cam_fltr_mod_wait);
break;
case RXF_E_PAUSE:
case RXF_E_RESUME:
rxf->rxf_flags |= BNA_RXF_FL_OPERSTATE_CHANGED;
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_cam_fltr_mod_wait_entry(struct bna_rxf *rxf)
{
if (!rxf_process_packet_filter(rxf)) {
/* No more pending CAM entries to update */
bfa_fsm_set_state(rxf, bna_rxf_sm_started);
}
}
static void
bna_rxf_sm_cam_fltr_mod_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_STOP:
/**
* STOP is originated from bnad. When this happens,
* it can not be waiting for filter update
*/
call_rxf_start_cbfn(rxf, BNA_CB_INTERRUPT);
bfa_fsm_set_state(rxf, bna_rxf_sm_cam_fltr_clr_wait);
break;
case RXF_E_FAIL:
rxf_reset_packet_filter(rxf);
call_rxf_cam_fltr_cbfn(rxf, BNA_CB_SUCCESS);
call_rxf_start_cbfn(rxf, BNA_CB_FAIL);
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_CAM_FLTR_MOD:
/* No-op */
break;
case RXF_E_CAM_FLTR_RESP:
if (!rxf_process_packet_filter(rxf)) {
/* No more pending CAM entries to update */
call_rxf_cam_fltr_cbfn(rxf, BNA_CB_SUCCESS);
bfa_fsm_set_state(rxf, bna_rxf_sm_started);
}
break;
case RXF_E_PAUSE:
case RXF_E_RESUME:
rxf->rxf_flags |= BNA_RXF_FL_OPERSTATE_CHANGED;
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_started_entry(struct bna_rxf *rxf)
{
call_rxf_start_cbfn(rxf, BNA_CB_SUCCESS);
if (rxf->rxf_flags & BNA_RXF_FL_OPERSTATE_CHANGED) {
if (rxf->rxf_oper_state == BNA_RXF_OPER_STATE_PAUSED)
bfa_fsm_send_event(rxf, RXF_E_PAUSE);
else
bfa_fsm_send_event(rxf, RXF_E_RESUME);
}
}
static void
bna_rxf_sm_started(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_STOP:
bfa_fsm_set_state(rxf, bna_rxf_sm_cam_fltr_clr_wait);
/* Hack to get FSM start clearing CAM entries */
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_RESP);
break;
case RXF_E_FAIL:
rxf_reset_packet_filter(rxf);
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_CAM_FLTR_MOD:
bfa_fsm_set_state(rxf, bna_rxf_sm_cam_fltr_mod_wait);
break;
case RXF_E_PAUSE:
bfa_fsm_set_state(rxf, bna_rxf_sm_pause_wait);
break;
case RXF_E_RESUME:
bfa_fsm_set_state(rxf, bna_rxf_sm_resume_wait);
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_cam_fltr_clr_wait_entry(struct bna_rxf *rxf)
{
/**
* Note: Do not add rxf_clear_packet_filter here.
* It will overstep mbox when this transition happens:
* cam_fltr_mod_wait -> cam_fltr_clr_wait on RXF_E_STOP event
*/
}
static void
bna_rxf_sm_cam_fltr_clr_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_FAIL:
/**
* FSM was in the process of stopping, initiated by
* bnad. When this happens, no one can be waiting for
* start or filter update
*/
rxf_reset_packet_filter(rxf);
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_CAM_FLTR_RESP:
if (!rxf_clear_packet_filter(rxf)) {
/* No more pending CAM entries to clear */
bfa_fsm_set_state(rxf, bna_rxf_sm_stop_wait);
rxf_disable(rxf);
}
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_stop_wait_entry(struct bna_rxf *rxf)
{
/**
* NOTE: Do not add rxf_disable here.
* It will overstep mbox when this transition happens:
* start_wait -> stop_wait on RXF_E_STOP event
*/
}
static void
bna_rxf_sm_stop_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_FAIL:
/**
* FSM was in the process of stopping, initiated by
* bnad. When this happens, no one can be waiting for
* start or filter update
*/
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_STARTED:
/**
* This event is received due to abrupt transition from
* bna_rxf_sm_start_wait state on receiving
* RXF_E_STOP event
*/
rxf_disable(rxf);
break;
case RXF_E_STOPPED:
/**
* FSM was in the process of stopping, initiated by
* bnad. When this happens, no one can be waiting for
* start or filter update
*/
bfa_fsm_set_state(rxf, bna_rxf_sm_stat_clr_wait);
break;
case RXF_E_PAUSE:
rxf->rxf_oper_state = BNA_RXF_OPER_STATE_PAUSED;
break;
case RXF_E_RESUME:
rxf->rxf_oper_state = BNA_RXF_OPER_STATE_RUNNING;
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_pause_wait_entry(struct bna_rxf *rxf)
{
rxf->rxf_flags &=
~(BNA_RXF_FL_OPERSTATE_CHANGED | BNA_RXF_FL_RXF_ENABLED);
__rxf_disable(rxf);
}
static void
bna_rxf_sm_pause_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_FAIL:
/**
* FSM was in the process of disabling rxf, initiated by
* bnad.
*/
call_rxf_pause_cbfn(rxf, BNA_CB_FAIL);
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_STOPPED:
rxf->rxf_oper_state = BNA_RXF_OPER_STATE_PAUSED;
call_rxf_pause_cbfn(rxf, BNA_CB_SUCCESS);
bfa_fsm_set_state(rxf, bna_rxf_sm_started);
break;
/*
* Since PAUSE/RESUME can only be sent by bnad, we don't expect
* any other event during these states
*/
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_resume_wait_entry(struct bna_rxf *rxf)
{
rxf->rxf_flags &= ~(BNA_RXF_FL_OPERSTATE_CHANGED);
rxf->rxf_flags |= BNA_RXF_FL_RXF_ENABLED;
__rxf_enable(rxf);
}
static void
bna_rxf_sm_resume_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_FAIL:
/**
* FSM was in the process of disabling rxf, initiated by
* bnad.
*/
call_rxf_resume_cbfn(rxf, BNA_CB_FAIL);
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
case RXF_E_STARTED:
rxf->rxf_oper_state = BNA_RXF_OPER_STATE_RUNNING;
call_rxf_resume_cbfn(rxf, BNA_CB_SUCCESS);
bfa_fsm_set_state(rxf, bna_rxf_sm_started);
break;
/*
* Since PAUSE/RESUME can only be sent by bnad, we don't expect
* any other event during these states
*/
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
bna_rxf_sm_stat_clr_wait_entry(struct bna_rxf *rxf)
{
__bna_rxf_stat_clr(rxf);
}
static void
bna_rxf_sm_stat_clr_wait(struct bna_rxf *rxf, enum bna_rxf_event event)
{
switch (event) {
case RXF_E_FAIL:
case RXF_E_STAT_CLEARED:
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
break;
default:
bfa_sm_fault(rxf->rx->bna, event);
}
}
static void
__rxf_enable(struct bna_rxf *rxf)
{
struct bfi_ll_rxf_multi_req ll_req;
u32 bm[2] = {0, 0};
if (rxf->rxf_id < 32)
bm[0] = 1 << rxf->rxf_id;
else
bm[1] = 1 << (rxf->rxf_id - 32);
bfi_h2i_set(ll_req.mh, BFI_MC_LL, BFI_LL_H2I_RX_REQ, 0);
ll_req.rxf_id_mask[0] = htonl(bm[0]);
ll_req.rxf_id_mask[1] = htonl(bm[1]);
ll_req.enable = 1;
bna_mbox_qe_fill(&rxf->mbox_qe, &ll_req, sizeof(ll_req),
rxf_cb_enabled, rxf);
bna_mbox_send(rxf->rx->bna, &rxf->mbox_qe);
}
static void
__rxf_disable(struct bna_rxf *rxf)
{
struct bfi_ll_rxf_multi_req ll_req;
u32 bm[2] = {0, 0};
if (rxf->rxf_id < 32)
bm[0] = 1 << rxf->rxf_id;
else
bm[1] = 1 << (rxf->rxf_id - 32);
bfi_h2i_set(ll_req.mh, BFI_MC_LL, BFI_LL_H2I_RX_REQ, 0);
ll_req.rxf_id_mask[0] = htonl(bm[0]);
ll_req.rxf_id_mask[1] = htonl(bm[1]);
ll_req.enable = 0;
bna_mbox_qe_fill(&rxf->mbox_qe, &ll_req, sizeof(ll_req),
rxf_cb_disabled, rxf);
bna_mbox_send(rxf->rx->bna, &rxf->mbox_qe);
}
static void
__rxf_config_set(struct bna_rxf *rxf)
{
u32 i;
struct bna_rss_mem *rss_mem;
struct bna_rx_fndb_ram *rx_fndb_ram;
struct bna *bna = rxf->rx->bna;
void __iomem *base_addr;
unsigned long off;
base_addr = BNA_GET_MEM_BASE_ADDR(bna->pcidev.pci_bar_kva,
RSS_TABLE_BASE_OFFSET);
rss_mem = (struct bna_rss_mem *)0;
/* Configure RSS if required */
if (rxf->ctrl_flags & BNA_RXF_CF_RSS_ENABLE) {
/* configure RSS Table */
writel(BNA_GET_PAGE_NUM(RAD0_MEM_BLK_BASE_PG_NUM +
bna->port_num, RSS_TABLE_BASE_OFFSET),
bna->regs.page_addr);
/* temporarily disable RSS, while hash value is written */
off = (unsigned long)&rss_mem[0].type_n_hash;
writel(0, base_addr + off);
for (i = 0; i < BFI_RSS_HASH_KEY_LEN; i++) {
off = (unsigned long)
&rss_mem[0].hash_key[(BFI_RSS_HASH_KEY_LEN - 1) - i];
writel(htonl(rxf->rss_cfg.toeplitz_hash_key[i]),
base_addr + off);
}
off = (unsigned long)&rss_mem[0].type_n_hash;
writel(rxf->rss_cfg.hash_type | rxf->rss_cfg.hash_mask,
base_addr + off);
}
/* Configure RxF */
writel(BNA_GET_PAGE_NUM(
LUT0_MEM_BLK_BASE_PG_NUM + (bna->port_num * 2),
RX_FNDB_RAM_BASE_OFFSET),
bna->regs.page_addr);
base_addr = BNA_GET_MEM_BASE_ADDR(bna->pcidev.pci_bar_kva,
RX_FNDB_RAM_BASE_OFFSET);
rx_fndb_ram = (struct bna_rx_fndb_ram *)0;
/* We always use RSS table 0 */
off = (unsigned long)&rx_fndb_ram[rxf->rxf_id].rss_prop;
writel(rxf->ctrl_flags & BNA_RXF_CF_RSS_ENABLE,
base_addr + off);
/* small large buffer enable/disable */
off = (unsigned long)&rx_fndb_ram[rxf->rxf_id].size_routing_props;
writel((rxf->ctrl_flags & BNA_RXF_CF_SM_LG_RXQ) | 0x80,
base_addr + off);
/* RIT offset, HDS forced offset, multicast RxQ Id */
off = (unsigned long)&rx_fndb_ram[rxf->rxf_id].rit_hds_mcastq;
writel((rxf->rit_segment->rit_offset << 16) |
(rxf->forced_offset << 8) |
(rxf->hds_cfg.hdr_type & BNA_HDS_FORCED) | rxf->mcast_rxq_id,
base_addr + off);
/*
* default vlan tag, default function enable, strip vlan bytes,
* HDS type, header size
*/
off = (unsigned long)&rx_fndb_ram[rxf->rxf_id].control_flags;
writel(((u32)rxf->default_vlan_tag << 16) |
(rxf->ctrl_flags &
(BNA_RXF_CF_DEFAULT_VLAN |
BNA_RXF_CF_DEFAULT_FUNCTION_ENABLE |
BNA_RXF_CF_VLAN_STRIP)) |
(rxf->hds_cfg.hdr_type & ~BNA_HDS_FORCED) |
rxf->hds_cfg.header_size,
base_addr + off);
}
void
__rxf_vlan_filter_set(struct bna_rxf *rxf, enum bna_status status)
{
struct bna *bna = rxf->rx->bna;
int i;
writel(BNA_GET_PAGE_NUM(LUT0_MEM_BLK_BASE_PG_NUM +
(bna->port_num * 2), VLAN_RAM_BASE_OFFSET),
bna->regs.page_addr);
if (status == BNA_STATUS_T_ENABLED) {
/* enable VLAN filtering on this function */
for (i = 0; i <= BFI_MAX_VLAN / 32; i++) {
writel(rxf->vlan_filter_table[i],
BNA_GET_VLAN_MEM_ENTRY_ADDR
(bna->pcidev.pci_bar_kva, rxf->rxf_id,
i * 32));
}
} else {
/* disable VLAN filtering on this function */
for (i = 0; i <= BFI_MAX_VLAN / 32; i++) {
writel(0xffffffff,
BNA_GET_VLAN_MEM_ENTRY_ADDR
(bna->pcidev.pci_bar_kva, rxf->rxf_id,
i * 32));
}
}
}
static void
__rxf_rit_set(struct bna_rxf *rxf)
{
struct bna *bna = rxf->rx->bna;
struct bna_rit_mem *rit_mem;
int i;
void __iomem *base_addr;
unsigned long off;
base_addr = BNA_GET_MEM_BASE_ADDR(bna->pcidev.pci_bar_kva,
FUNCTION_TO_RXQ_TRANSLATE);
rit_mem = (struct bna_rit_mem *)0;
writel(BNA_GET_PAGE_NUM(RXA0_MEM_BLK_BASE_PG_NUM + bna->port_num,
FUNCTION_TO_RXQ_TRANSLATE),
bna->regs.page_addr);
for (i = 0; i < rxf->rit_segment->rit_size; i++) {
off = (unsigned long)&rit_mem[i + rxf->rit_segment->rit_offset];
writel(rxf->rit_segment->rit[i].large_rxq_id << 6 |
rxf->rit_segment->rit[i].small_rxq_id,
base_addr + off);
}
}
static void
__bna_rxf_stat_clr(struct bna_rxf *rxf)
{
struct bfi_ll_stats_req ll_req;
u32 bm[2] = {0, 0};
if (rxf->rxf_id < 32)
bm[0] = 1 << rxf->rxf_id;
else
bm[1] = 1 << (rxf->rxf_id - 32);
bfi_h2i_set(ll_req.mh, BFI_MC_LL, BFI_LL_H2I_STATS_CLEAR_REQ, 0);
ll_req.stats_mask = 0;
ll_req.txf_id_mask[0] = 0;
ll_req.txf_id_mask[1] = 0;
ll_req.rxf_id_mask[0] = htonl(bm[0]);
ll_req.rxf_id_mask[1] = htonl(bm[1]);
bna_mbox_qe_fill(&rxf->mbox_qe, &ll_req, sizeof(ll_req),
bna_rxf_cb_stats_cleared, rxf);
bna_mbox_send(rxf->rx->bna, &rxf->mbox_qe);
}
static void
rxf_enable(struct bna_rxf *rxf)
{
if (rxf->rxf_oper_state == BNA_RXF_OPER_STATE_PAUSED)
bfa_fsm_send_event(rxf, RXF_E_STARTED);
else {
rxf->rxf_flags |= BNA_RXF_FL_RXF_ENABLED;
__rxf_enable(rxf);
}
}
static void
rxf_cb_enabled(void *arg, int status)
{
struct bna_rxf *rxf = (struct bna_rxf *)arg;
bfa_q_qe_init(&rxf->mbox_qe.qe);
bfa_fsm_send_event(rxf, RXF_E_STARTED);
}
static void
rxf_disable(struct bna_rxf *rxf)
{
if (rxf->rxf_oper_state == BNA_RXF_OPER_STATE_PAUSED)
bfa_fsm_send_event(rxf, RXF_E_STOPPED);
else
rxf->rxf_flags &= ~BNA_RXF_FL_RXF_ENABLED;
__rxf_disable(rxf);
}
static void
rxf_cb_disabled(void *arg, int status)
{
struct bna_rxf *rxf = (struct bna_rxf *)arg;
bfa_q_qe_init(&rxf->mbox_qe.qe);
bfa_fsm_send_event(rxf, RXF_E_STOPPED);
}
void
rxf_cb_cam_fltr_mbox_cmd(void *arg, int status)
{
struct bna_rxf *rxf = (struct bna_rxf *)arg;
bfa_q_qe_init(&rxf->mbox_qe.qe);
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_RESP);
}
static void
bna_rxf_cb_stats_cleared(void *arg, int status)
{
struct bna_rxf *rxf = (struct bna_rxf *)arg;
bfa_q_qe_init(&rxf->mbox_qe.qe);
bfa_fsm_send_event(rxf, RXF_E_STAT_CLEARED);
}
void
rxf_cam_mbox_cmd(struct bna_rxf *rxf, u8 cmd,
const struct bna_mac *mac_addr)
{
struct bfi_ll_mac_addr_req req;
bfi_h2i_set(req.mh, BFI_MC_LL, cmd, 0);
req.rxf_id = rxf->rxf_id;
memcpy(&req.mac_addr, (void *)&mac_addr->addr, ETH_ALEN);
bna_mbox_qe_fill(&rxf->mbox_qe, &req, sizeof(req),
rxf_cb_cam_fltr_mbox_cmd, rxf);
bna_mbox_send(rxf->rx->bna, &rxf->mbox_qe);
}
static int
rxf_process_packet_filter_mcast(struct bna_rxf *rxf)
{
struct bna_mac *mac = NULL;
struct list_head *qe;
/* Add multicast entries */
if (!list_empty(&rxf->mcast_pending_add_q)) {
bfa_q_deq(&rxf->mcast_pending_add_q, &qe);
bfa_q_qe_init(qe);
mac = (struct bna_mac *)qe;
rxf_cam_mbox_cmd(rxf, BFI_LL_H2I_MAC_MCAST_ADD_REQ, mac);
list_add_tail(&mac->qe, &rxf->mcast_active_q);
return 1;
}
/* Delete multicast entries previousely added */
if (!list_empty(&rxf->mcast_pending_del_q)) {
bfa_q_deq(&rxf->mcast_pending_del_q, &qe);
bfa_q_qe_init(qe);
mac = (struct bna_mac *)qe;
rxf_cam_mbox_cmd(rxf, BFI_LL_H2I_MAC_MCAST_DEL_REQ, mac);
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod, mac);
return 1;
}
return 0;
}
static int
rxf_process_packet_filter_vlan(struct bna_rxf *rxf)
{
/* Apply the VLAN filter */
if (rxf->rxf_flags & BNA_RXF_FL_VLAN_CONFIG_PENDING) {
rxf->rxf_flags &= ~BNA_RXF_FL_VLAN_CONFIG_PENDING;
if (!(rxf->rxmode_active & BNA_RXMODE_PROMISC))
__rxf_vlan_filter_set(rxf, rxf->vlan_filter_status);
}
/* Apply RSS configuration */
if (rxf->rxf_flags & BNA_RXF_FL_RSS_CONFIG_PENDING) {
rxf->rxf_flags &= ~BNA_RXF_FL_RSS_CONFIG_PENDING;
if (rxf->rss_status == BNA_STATUS_T_DISABLED) {
/* RSS is being disabled */
rxf->ctrl_flags &= ~BNA_RXF_CF_RSS_ENABLE;
__rxf_rit_set(rxf);
__rxf_config_set(rxf);
} else {
/* RSS is being enabled or reconfigured */
rxf->ctrl_flags |= BNA_RXF_CF_RSS_ENABLE;
__rxf_rit_set(rxf);
__rxf_config_set(rxf);
}
}
return 0;
}
/**
* Processes pending ucast, mcast entry addition/deletion and issues mailbox
* command. Also processes pending filter configuration - promiscuous mode,
* default mode, allmutli mode and issues mailbox command or directly applies
* to h/w
*/
static int
rxf_process_packet_filter(struct bna_rxf *rxf)
{
/* Set the default MAC first */
if (rxf->ucast_pending_set > 0) {
rxf_cam_mbox_cmd(rxf, BFI_LL_H2I_MAC_UCAST_SET_REQ,
rxf->ucast_active_mac);
rxf->ucast_pending_set--;
return 1;
}
if (rxf_process_packet_filter_ucast(rxf))
return 1;
if (rxf_process_packet_filter_mcast(rxf))
return 1;
if (rxf_process_packet_filter_promisc(rxf))
return 1;
if (rxf_process_packet_filter_allmulti(rxf))
return 1;
if (rxf_process_packet_filter_vlan(rxf))
return 1;
return 0;
}
static int
rxf_clear_packet_filter_mcast(struct bna_rxf *rxf)
{
struct bna_mac *mac = NULL;
struct list_head *qe;
/* 3. delete pending mcast entries */
if (!list_empty(&rxf->mcast_pending_del_q)) {
bfa_q_deq(&rxf->mcast_pending_del_q, &qe);
bfa_q_qe_init(qe);
mac = (struct bna_mac *)qe;
rxf_cam_mbox_cmd(rxf, BFI_LL_H2I_MAC_MCAST_DEL_REQ, mac);
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod, mac);
return 1;
}
/* 4. clear active mcast entries; move them to pending_add_q */
if (!list_empty(&rxf->mcast_active_q)) {
bfa_q_deq(&rxf->mcast_active_q, &qe);
bfa_q_qe_init(qe);
mac = (struct bna_mac *)qe;
rxf_cam_mbox_cmd(rxf, BFI_LL_H2I_MAC_MCAST_DEL_REQ, mac);
list_add_tail(&mac->qe, &rxf->mcast_pending_add_q);
return 1;
}
return 0;
}
/**
* In the rxf stop path, processes pending ucast/mcast delete queue and issues
* the mailbox command. Moves the active ucast/mcast entries to pending add q,
* so that they are added to CAM again in the rxf start path. Moves the current
* filter settings - promiscuous, default, allmutli - to pending filter
* configuration
*/
static int
rxf_clear_packet_filter(struct bna_rxf *rxf)
{
if (rxf_clear_packet_filter_ucast(rxf))
return 1;
if (rxf_clear_packet_filter_mcast(rxf))
return 1;
/* 5. clear active default MAC in the CAM */
if (rxf->ucast_pending_set > 0)
rxf->ucast_pending_set = 0;
if (rxf_clear_packet_filter_promisc(rxf))
return 1;
if (rxf_clear_packet_filter_allmulti(rxf))
return 1;
return 0;
}
static void
rxf_reset_packet_filter_mcast(struct bna_rxf *rxf)
{
struct list_head *qe;
struct bna_mac *mac;
/* 3. Move active mcast entries to pending_add_q */
while (!list_empty(&rxf->mcast_active_q)) {
bfa_q_deq(&rxf->mcast_active_q, &qe);
bfa_q_qe_init(qe);
list_add_tail(qe, &rxf->mcast_pending_add_q);
}
/* 4. Throw away delete pending mcast entries */
while (!list_empty(&rxf->mcast_pending_del_q)) {
bfa_q_deq(&rxf->mcast_pending_del_q, &qe);
bfa_q_qe_init(qe);
mac = (struct bna_mac *)qe;
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod, mac);
}
}
/**
* In the rxf fail path, throws away the ucast/mcast entries pending for
* deletion, moves all active ucast/mcast entries to pending queue so that
* they are added back to CAM in the rxf start path. Also moves the current
* filter configuration to pending filter configuration.
*/
static void
rxf_reset_packet_filter(struct bna_rxf *rxf)
{
rxf_reset_packet_filter_ucast(rxf);
rxf_reset_packet_filter_mcast(rxf);
/* 5. Turn off ucast set flag */
rxf->ucast_pending_set = 0;
rxf_reset_packet_filter_promisc(rxf);
rxf_reset_packet_filter_allmulti(rxf);
}
static void
bna_rxf_init(struct bna_rxf *rxf,
struct bna_rx *rx,
struct bna_rx_config *q_config)
{
struct list_head *qe;
struct bna_rxp *rxp;
/* rxf_id is initialized during rx_mod init */
rxf->rx = rx;
INIT_LIST_HEAD(&rxf->ucast_pending_add_q);
INIT_LIST_HEAD(&rxf->ucast_pending_del_q);
rxf->ucast_pending_set = 0;
INIT_LIST_HEAD(&rxf->ucast_active_q);
rxf->ucast_active_mac = NULL;
INIT_LIST_HEAD(&rxf->mcast_pending_add_q);
INIT_LIST_HEAD(&rxf->mcast_pending_del_q);
INIT_LIST_HEAD(&rxf->mcast_active_q);
bfa_q_qe_init(&rxf->mbox_qe.qe);
if (q_config->vlan_strip_status == BNA_STATUS_T_ENABLED)
rxf->ctrl_flags |= BNA_RXF_CF_VLAN_STRIP;
rxf->rxf_oper_state = (q_config->paused) ?
BNA_RXF_OPER_STATE_PAUSED : BNA_RXF_OPER_STATE_RUNNING;
bna_rxf_adv_init(rxf, rx, q_config);
rxf->rit_segment = bna_rit_mod_seg_get(&rxf->rx->bna->rit_mod,
q_config->num_paths);
list_for_each(qe, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe;
if (q_config->rxp_type == BNA_RXP_SINGLE)
rxf->mcast_rxq_id = rxp->rxq.single.only->rxq_id;
else
rxf->mcast_rxq_id = rxp->rxq.slr.large->rxq_id;
break;
}
rxf->vlan_filter_status = BNA_STATUS_T_DISABLED;
memset(rxf->vlan_filter_table, 0,
(sizeof(u32) * ((BFI_MAX_VLAN + 1) / 32)));
/* Set up VLAN 0 for pure priority tagged packets */
rxf->vlan_filter_table[0] |= 1;
bfa_fsm_set_state(rxf, bna_rxf_sm_stopped);
}
static void
bna_rxf_uninit(struct bna_rxf *rxf)
{
struct bna *bna = rxf->rx->bna;
struct bna_mac *mac;
bna_rit_mod_seg_put(&rxf->rx->bna->rit_mod, rxf->rit_segment);
rxf->rit_segment = NULL;
rxf->ucast_pending_set = 0;
while (!list_empty(&rxf->ucast_pending_add_q)) {
bfa_q_deq(&rxf->ucast_pending_add_q, &mac);
bfa_q_qe_init(&mac->qe);
bna_ucam_mod_mac_put(&rxf->rx->bna->ucam_mod, mac);
}
if (rxf->ucast_active_mac) {
bfa_q_qe_init(&rxf->ucast_active_mac->qe);
bna_ucam_mod_mac_put(&rxf->rx->bna->ucam_mod,
rxf->ucast_active_mac);
rxf->ucast_active_mac = NULL;
}
while (!list_empty(&rxf->mcast_pending_add_q)) {
bfa_q_deq(&rxf->mcast_pending_add_q, &mac);
bfa_q_qe_init(&mac->qe);
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod, mac);
}
/* Turn off pending promisc mode */
if (is_promisc_enable(rxf->rxmode_pending,
rxf->rxmode_pending_bitmask)) {
/* system promisc state should be pending */
BUG_ON(!(bna->rxf_promisc_id == rxf->rxf_id));
promisc_inactive(rxf->rxmode_pending,
rxf->rxmode_pending_bitmask);
bna->rxf_promisc_id = BFI_MAX_RXF;
}
/* Promisc mode should not be active */
BUG_ON(rxf->rxmode_active & BNA_RXMODE_PROMISC);
/* Turn off pending all-multi mode */
if (is_allmulti_enable(rxf->rxmode_pending,
rxf->rxmode_pending_bitmask)) {
allmulti_inactive(rxf->rxmode_pending,
rxf->rxmode_pending_bitmask);
}
/* Allmulti mode should not be active */
BUG_ON(rxf->rxmode_active & BNA_RXMODE_ALLMULTI);
rxf->rx = NULL;
}
static void
bna_rx_cb_rxf_started(struct bna_rx *rx, enum bna_cb_status status)
{
bfa_fsm_send_event(rx, RX_E_RXF_STARTED);
if (rx->rxf.rxf_id < 32)
rx->bna->rx_mod.rxf_bmap[0] |= ((u32)1 << rx->rxf.rxf_id);
else
rx->bna->rx_mod.rxf_bmap[1] |= ((u32)
1 << (rx->rxf.rxf_id - 32));
}
static void
bna_rxf_start(struct bna_rxf *rxf)
{
rxf->start_cbfn = bna_rx_cb_rxf_started;
rxf->start_cbarg = rxf->rx;
rxf->rxf_flags &= ~BNA_RXF_FL_FAILED;
bfa_fsm_send_event(rxf, RXF_E_START);
}
static void
bna_rx_cb_rxf_stopped(struct bna_rx *rx, enum bna_cb_status status)
{
bfa_fsm_send_event(rx, RX_E_RXF_STOPPED);
if (rx->rxf.rxf_id < 32)
rx->bna->rx_mod.rxf_bmap[0] &= ~(u32)1 << rx->rxf.rxf_id;
else
rx->bna->rx_mod.rxf_bmap[1] &= ~(u32)
1 << (rx->rxf.rxf_id - 32);
}
static void
bna_rxf_stop(struct bna_rxf *rxf)
{
rxf->stop_cbfn = bna_rx_cb_rxf_stopped;
rxf->stop_cbarg = rxf->rx;
bfa_fsm_send_event(rxf, RXF_E_STOP);
}
static void
bna_rxf_fail(struct bna_rxf *rxf)
{
rxf->rxf_flags |= BNA_RXF_FL_FAILED;
bfa_fsm_send_event(rxf, RXF_E_FAIL);
}
int
bna_rxf_state_get(struct bna_rxf *rxf)
{
return bfa_sm_to_state(rxf_sm_table, rxf->fsm);
}
enum bna_cb_status
bna_rx_ucast_set(struct bna_rx *rx, u8 *ucmac,
void (*cbfn)(struct bnad *, struct bna_rx *,
enum bna_cb_status))
{
struct bna_rxf *rxf = &rx->rxf;
if (rxf->ucast_active_mac == NULL) {
rxf->ucast_active_mac =
bna_ucam_mod_mac_get(&rxf->rx->bna->ucam_mod);
if (rxf->ucast_active_mac == NULL)
return BNA_CB_UCAST_CAM_FULL;
bfa_q_qe_init(&rxf->ucast_active_mac->qe);
}
memcpy(rxf->ucast_active_mac->addr, ucmac, ETH_ALEN);
rxf->ucast_pending_set++;
rxf->cam_fltr_cbfn = cbfn;
rxf->cam_fltr_cbarg = rx->bna->bnad;
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_MOD);
return BNA_CB_SUCCESS;
}
enum bna_cb_status
bna_rx_mcast_add(struct bna_rx *rx, u8 *addr,
void (*cbfn)(struct bnad *, struct bna_rx *,
enum bna_cb_status))
{
struct bna_rxf *rxf = &rx->rxf;
struct list_head *qe;
struct bna_mac *mac;
/* Check if already added */
list_for_each(qe, &rxf->mcast_active_q) {
mac = (struct bna_mac *)qe;
if (BNA_MAC_IS_EQUAL(mac->addr, addr)) {
if (cbfn)
(*cbfn)(rx->bna->bnad, rx, BNA_CB_SUCCESS);
return BNA_CB_SUCCESS;
}
}
/* Check if pending addition */
list_for_each(qe, &rxf->mcast_pending_add_q) {
mac = (struct bna_mac *)qe;
if (BNA_MAC_IS_EQUAL(mac->addr, addr)) {
if (cbfn)
(*cbfn)(rx->bna->bnad, rx, BNA_CB_SUCCESS);
return BNA_CB_SUCCESS;
}
}
mac = bna_mcam_mod_mac_get(&rxf->rx->bna->mcam_mod);
if (mac == NULL)
return BNA_CB_MCAST_LIST_FULL;
bfa_q_qe_init(&mac->qe);
memcpy(mac->addr, addr, ETH_ALEN);
list_add_tail(&mac->qe, &rxf->mcast_pending_add_q);
rxf->cam_fltr_cbfn = cbfn;
rxf->cam_fltr_cbarg = rx->bna->bnad;
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_MOD);
return BNA_CB_SUCCESS;
}
enum bna_cb_status
bna_rx_mcast_listset(struct bna_rx *rx, int count, u8 *mclist,
void (*cbfn)(struct bnad *, struct bna_rx *,
enum bna_cb_status))
{
struct bna_rxf *rxf = &rx->rxf;
struct list_head list_head;
struct list_head *qe;
u8 *mcaddr;
struct bna_mac *mac;
struct bna_mac *mac1;
int skip;
int delete;
int need_hw_config = 0;
int i;
/* Allocate nodes */
INIT_LIST_HEAD(&list_head);
for (i = 0, mcaddr = mclist; i < count; i++) {
mac = bna_mcam_mod_mac_get(&rxf->rx->bna->mcam_mod);
if (mac == NULL)
goto err_return;
bfa_q_qe_init(&mac->qe);
memcpy(mac->addr, mcaddr, ETH_ALEN);
list_add_tail(&mac->qe, &list_head);
mcaddr += ETH_ALEN;
}
/* Schedule for addition */
while (!list_empty(&list_head)) {
bfa_q_deq(&list_head, &qe);
mac = (struct bna_mac *)qe;
bfa_q_qe_init(&mac->qe);
skip = 0;
/* Skip if already added */
list_for_each(qe, &rxf->mcast_active_q) {
mac1 = (struct bna_mac *)qe;
if (BNA_MAC_IS_EQUAL(mac1->addr, mac->addr)) {
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod,
mac);
skip = 1;
break;
}
}
if (skip)
continue;
/* Skip if pending addition */
list_for_each(qe, &rxf->mcast_pending_add_q) {
mac1 = (struct bna_mac *)qe;
if (BNA_MAC_IS_EQUAL(mac1->addr, mac->addr)) {
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod,
mac);
skip = 1;
break;
}
}
if (skip)
continue;
need_hw_config = 1;
list_add_tail(&mac->qe, &rxf->mcast_pending_add_q);
}
/**
* Delete the entries that are in the pending_add_q but not
* in the new list
*/
while (!list_empty(&rxf->mcast_pending_add_q)) {
bfa_q_deq(&rxf->mcast_pending_add_q, &qe);
mac = (struct bna_mac *)qe;
bfa_q_qe_init(&mac->qe);
for (i = 0, mcaddr = mclist, delete = 1; i < count; i++) {
if (BNA_MAC_IS_EQUAL(mcaddr, mac->addr)) {
delete = 0;
break;
}
mcaddr += ETH_ALEN;
}
if (delete)
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod, mac);
else
list_add_tail(&mac->qe, &list_head);
}
while (!list_empty(&list_head)) {
bfa_q_deq(&list_head, &qe);
mac = (struct bna_mac *)qe;
bfa_q_qe_init(&mac->qe);
list_add_tail(&mac->qe, &rxf->mcast_pending_add_q);
}
/**
* Schedule entries for deletion that are in the active_q but not
* in the new list
*/
while (!list_empty(&rxf->mcast_active_q)) {
bfa_q_deq(&rxf->mcast_active_q, &qe);
mac = (struct bna_mac *)qe;
bfa_q_qe_init(&mac->qe);
for (i = 0, mcaddr = mclist, delete = 1; i < count; i++) {
if (BNA_MAC_IS_EQUAL(mcaddr, mac->addr)) {
delete = 0;
break;
}
mcaddr += ETH_ALEN;
}
if (delete) {
list_add_tail(&mac->qe, &rxf->mcast_pending_del_q);
need_hw_config = 1;
} else {
list_add_tail(&mac->qe, &list_head);
}
}
while (!list_empty(&list_head)) {
bfa_q_deq(&list_head, &qe);
mac = (struct bna_mac *)qe;
bfa_q_qe_init(&mac->qe);
list_add_tail(&mac->qe, &rxf->mcast_active_q);
}
if (need_hw_config) {
rxf->cam_fltr_cbfn = cbfn;
rxf->cam_fltr_cbarg = rx->bna->bnad;
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_MOD);
} else if (cbfn)
(*cbfn)(rx->bna->bnad, rx, BNA_CB_SUCCESS);
return BNA_CB_SUCCESS;
err_return:
while (!list_empty(&list_head)) {
bfa_q_deq(&list_head, &qe);
mac = (struct bna_mac *)qe;
bfa_q_qe_init(&mac->qe);
bna_mcam_mod_mac_put(&rxf->rx->bna->mcam_mod, mac);
}
return BNA_CB_MCAST_LIST_FULL;
}
void
bna_rx_vlan_add(struct bna_rx *rx, int vlan_id)
{
struct bna_rxf *rxf = &rx->rxf;
int index = (vlan_id >> 5);
int bit = (1 << (vlan_id & 0x1F));
rxf->vlan_filter_table[index] |= bit;
if (rxf->vlan_filter_status == BNA_STATUS_T_ENABLED) {
rxf->rxf_flags |= BNA_RXF_FL_VLAN_CONFIG_PENDING;
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_MOD);
}
}
void
bna_rx_vlan_del(struct bna_rx *rx, int vlan_id)
{
struct bna_rxf *rxf = &rx->rxf;
int index = (vlan_id >> 5);
int bit = (1 << (vlan_id & 0x1F));
rxf->vlan_filter_table[index] &= ~bit;
if (rxf->vlan_filter_status == BNA_STATUS_T_ENABLED) {
rxf->rxf_flags |= BNA_RXF_FL_VLAN_CONFIG_PENDING;
bfa_fsm_send_event(rxf, RXF_E_CAM_FLTR_MOD);
}
}
/**
* RX
*/
#define RXQ_RCB_INIT(q, rxp, qdepth, bna, _id, unmapq_mem) do { \
struct bna_doorbell_qset *_qset; \
unsigned long off; \
(q)->rcb->producer_index = (q)->rcb->consumer_index = 0; \
(q)->rcb->q_depth = (qdepth); \
(q)->rcb->unmap_q = unmapq_mem; \
(q)->rcb->rxq = (q); \
(q)->rcb->cq = &(rxp)->cq; \
(q)->rcb->bnad = (bna)->bnad; \
_qset = (struct bna_doorbell_qset *)0; \
off = (unsigned long)&_qset[(q)->rxq_id].rxq[0]; \
(q)->rcb->q_dbell = off + \
BNA_GET_DOORBELL_BASE_ADDR((bna)->pcidev.pci_bar_kva); \
(q)->rcb->id = _id; \
} while (0)
#define BNA_GET_RXQS(qcfg) (((qcfg)->rxp_type == BNA_RXP_SINGLE) ? \
(qcfg)->num_paths : ((qcfg)->num_paths * 2))
#define SIZE_TO_PAGES(size) (((size) >> PAGE_SHIFT) + ((((size) &\
(PAGE_SIZE - 1)) + (PAGE_SIZE - 1)) >> PAGE_SHIFT))
#define call_rx_stop_callback(rx, status) \
if ((rx)->stop_cbfn) { \
(*(rx)->stop_cbfn)((rx)->stop_cbarg, rx, (status)); \
(rx)->stop_cbfn = NULL; \
(rx)->stop_cbarg = NULL; \
}
/*
* Since rx_enable is synchronous callback, there is no start_cbfn required.
* Instead, we'll call bnad_rx_post(rxp) so that bnad can post the buffers
* for each rxpath.
*/
#define call_rx_disable_cbfn(rx, status) \
if ((rx)->disable_cbfn) { \
(*(rx)->disable_cbfn)((rx)->disable_cbarg, \
status); \
(rx)->disable_cbfn = NULL; \
(rx)->disable_cbarg = NULL; \
} \
#define rxqs_reqd(type, num_rxqs) \
(((type) == BNA_RXP_SINGLE) ? (num_rxqs) : ((num_rxqs) * 2))
#define rx_ib_fail(rx) \
do { \
struct bna_rxp *rxp; \
struct list_head *qe; \
list_for_each(qe, &(rx)->rxp_q) { \
rxp = (struct bna_rxp *)qe; \
bna_ib_fail(rxp->cq.ib); \
} \
} while (0)
static void __bna_multi_rxq_stop(struct bna_rxp *, u32 *);
static void __bna_rxq_start(struct bna_rxq *rxq);
static void __bna_cq_start(struct bna_cq *cq);
static void bna_rit_create(struct bna_rx *rx);
static void bna_rx_cb_multi_rxq_stopped(void *arg, int status);
static void bna_rx_cb_rxq_stopped_all(void *arg);
bfa_fsm_state_decl(bna_rx, stopped,
struct bna_rx, enum bna_rx_event);
bfa_fsm_state_decl(bna_rx, rxf_start_wait,
struct bna_rx, enum bna_rx_event);
bfa_fsm_state_decl(bna_rx, started,
struct bna_rx, enum bna_rx_event);
bfa_fsm_state_decl(bna_rx, rxf_stop_wait,
struct bna_rx, enum bna_rx_event);
bfa_fsm_state_decl(bna_rx, rxq_stop_wait,
struct bna_rx, enum bna_rx_event);
static const struct bfa_sm_table rx_sm_table[] = {
{BFA_SM(bna_rx_sm_stopped), BNA_RX_STOPPED},
{BFA_SM(bna_rx_sm_rxf_start_wait), BNA_RX_RXF_START_WAIT},
{BFA_SM(bna_rx_sm_started), BNA_RX_STARTED},
{BFA_SM(bna_rx_sm_rxf_stop_wait), BNA_RX_RXF_STOP_WAIT},
{BFA_SM(bna_rx_sm_rxq_stop_wait), BNA_RX_RXQ_STOP_WAIT},
};
static void bna_rx_sm_stopped_entry(struct bna_rx *rx)
{
struct bna_rxp *rxp;
struct list_head *qe_rxp;
list_for_each(qe_rxp, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe_rxp;
rx->rx_cleanup_cbfn(rx->bna->bnad, rxp->cq.ccb);
}
call_rx_stop_callback(rx, BNA_CB_SUCCESS);
}
static void bna_rx_sm_stopped(struct bna_rx *rx,
enum bna_rx_event event)
{
switch (event) {
case RX_E_START:
bfa_fsm_set_state(rx, bna_rx_sm_rxf_start_wait);
break;
case RX_E_STOP:
call_rx_stop_callback(rx, BNA_CB_SUCCESS);
break;
case RX_E_FAIL:
/* no-op */
break;
default:
bfa_sm_fault(rx->bna, event);
break;
}
}
static void bna_rx_sm_rxf_start_wait_entry(struct bna_rx *rx)
{
struct bna_rxp *rxp;
struct list_head *qe_rxp;
struct bna_rxq *q0 = NULL, *q1 = NULL;
/* Setup the RIT */
bna_rit_create(rx);
list_for_each(qe_rxp, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe_rxp;
bna_ib_start(rxp->cq.ib);
GET_RXQS(rxp, q0, q1);
q0->buffer_size = bna_port_mtu_get(&rx->bna->port);
__bna_rxq_start(q0);
rx->rx_post_cbfn(rx->bna->bnad, q0->rcb);
if (q1) {
__bna_rxq_start(q1);
rx->rx_post_cbfn(rx->bna->bnad, q1->rcb);
}
__bna_cq_start(&rxp->cq);
}
bna_rxf_start(&rx->rxf);
}
static void bna_rx_sm_rxf_start_wait(struct bna_rx *rx,
enum bna_rx_event event)
{
switch (event) {
case RX_E_STOP:
bfa_fsm_set_state(rx, bna_rx_sm_rxf_stop_wait);
break;
case RX_E_FAIL:
bfa_fsm_set_state(rx, bna_rx_sm_stopped);
rx_ib_fail(rx);
bna_rxf_fail(&rx->rxf);
break;
case RX_E_RXF_STARTED:
bfa_fsm_set_state(rx, bna_rx_sm_started);
break;
default:
bfa_sm_fault(rx->bna, event);
break;
}
}
void
bna_rx_sm_started_entry(struct bna_rx *rx)
{
struct bna_rxp *rxp;
struct list_head *qe_rxp;
/* Start IB */
list_for_each(qe_rxp, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe_rxp;
bna_ib_ack(&rxp->cq.ib->door_bell, 0);
}
bna_llport_rx_started(&rx->bna->port.llport);
}
void
bna_rx_sm_started(struct bna_rx *rx, enum bna_rx_event event)
{
switch (event) {
case RX_E_FAIL:
bna_llport_rx_stopped(&rx->bna->port.llport);
bfa_fsm_set_state(rx, bna_rx_sm_stopped);
rx_ib_fail(rx);
bna_rxf_fail(&rx->rxf);
break;
case RX_E_STOP:
bna_llport_rx_stopped(&rx->bna->port.llport);
bfa_fsm_set_state(rx, bna_rx_sm_rxf_stop_wait);
break;
default:
bfa_sm_fault(rx->bna, event);
break;
}
}
void
bna_rx_sm_rxf_stop_wait_entry(struct bna_rx *rx)
{
bna_rxf_stop(&rx->rxf);
}
void
bna_rx_sm_rxf_stop_wait(struct bna_rx *rx, enum bna_rx_event event)
{
switch (event) {
case RX_E_RXF_STOPPED:
bfa_fsm_set_state(rx, bna_rx_sm_rxq_stop_wait);
break;
case RX_E_RXF_STARTED:
/**
* RxF was in the process of starting up when
* RXF_E_STOP was issued. Ignore this event
*/
break;
case RX_E_FAIL:
bfa_fsm_set_state(rx, bna_rx_sm_stopped);
rx_ib_fail(rx);
bna_rxf_fail(&rx->rxf);
break;
default:
bfa_sm_fault(rx->bna, event);
break;
}
}
void
bna_rx_sm_rxq_stop_wait_entry(struct bna_rx *rx)
{
struct bna_rxp *rxp = NULL;
struct bna_rxq *q0 = NULL;
struct bna_rxq *q1 = NULL;
struct list_head *qe;
u32 rxq_mask[2] = {0, 0};
/* Only one call to multi-rxq-stop for all RXPs in this RX */
bfa_wc_up(&rx->rxq_stop_wc);
list_for_each(qe, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe;
GET_RXQS(rxp, q0, q1);
if (q0->rxq_id < 32)
rxq_mask[0] |= ((u32)1 << q0->rxq_id);
else
rxq_mask[1] |= ((u32)1 << (q0->rxq_id - 32));
if (q1) {
if (q1->rxq_id < 32)
rxq_mask[0] |= ((u32)1 << q1->rxq_id);
else
rxq_mask[1] |= ((u32)
1 << (q1->rxq_id - 32));
}
}
__bna_multi_rxq_stop(rxp, rxq_mask);
}
void
bna_rx_sm_rxq_stop_wait(struct bna_rx *rx, enum bna_rx_event event)
{
struct bna_rxp *rxp = NULL;
struct list_head *qe;
switch (event) {
case RX_E_RXQ_STOPPED:
list_for_each(qe, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe;
bna_ib_stop(rxp->cq.ib);
}
/* Fall through */
case RX_E_FAIL:
bfa_fsm_set_state(rx, bna_rx_sm_stopped);
break;
default:
bfa_sm_fault(rx->bna, event);
break;
}
}
void
__bna_multi_rxq_stop(struct bna_rxp *rxp, u32 * rxq_id_mask)
{
struct bfi_ll_q_stop_req ll_req;
bfi_h2i_set(ll_req.mh, BFI_MC_LL, BFI_LL_H2I_RXQ_STOP_REQ, 0);
ll_req.q_id_mask[0] = htonl(rxq_id_mask[0]);
ll_req.q_id_mask[1] = htonl(rxq_id_mask[1]);
bna_mbox_qe_fill(&rxp->mbox_qe, &ll_req, sizeof(ll_req),
bna_rx_cb_multi_rxq_stopped, rxp);
bna_mbox_send(rxp->rx->bna, &rxp->mbox_qe);
}
void
__bna_rxq_start(struct bna_rxq *rxq)
{
struct bna_rxtx_q_mem *q_mem;
struct bna_rxq_mem rxq_cfg, *rxq_mem;
struct bna_dma_addr cur_q_addr;
/* struct bna_doorbell_qset *qset; */
struct bna_qpt *qpt;
u32 pg_num;
struct bna *bna = rxq->rx->bna;
void __iomem *base_addr;
unsigned long off;
qpt = &rxq->qpt;
cur_q_addr = *((struct bna_dma_addr *)(qpt->kv_qpt_ptr));
rxq_cfg.pg_tbl_addr_lo = qpt->hw_qpt_ptr.lsb;
rxq_cfg.pg_tbl_addr_hi = qpt->hw_qpt_ptr.msb;
rxq_cfg.cur_q_entry_lo = cur_q_addr.lsb;
rxq_cfg.cur_q_entry_hi = cur_q_addr.msb;
rxq_cfg.pg_cnt_n_prd_ptr = ((u32)qpt->page_count << 16) | 0x0;
rxq_cfg.entry_n_pg_size = ((u32)(BFI_RXQ_WI_SIZE >> 2) << 16) |
(qpt->page_size >> 2);
rxq_cfg.sg_n_cq_n_cns_ptr =
((u32)(rxq->rxp->cq.cq_id & 0xff) << 16) | 0x0;
rxq_cfg.buf_sz_n_q_state = ((u32)rxq->buffer_size << 16) |
BNA_Q_IDLE_STATE;
rxq_cfg.next_qid = 0x0 | (0x3 << 8);
/* Write the page number register */
pg_num = BNA_GET_PAGE_NUM(HQM0_BLK_PG_NUM + bna->port_num,
HQM_RXTX_Q_RAM_BASE_OFFSET);
writel(pg_num, bna->regs.page_addr);
/* Write to h/w */
base_addr = BNA_GET_MEM_BASE_ADDR(bna->pcidev.pci_bar_kva,
HQM_RXTX_Q_RAM_BASE_OFFSET);
q_mem = (struct bna_rxtx_q_mem *)0;
rxq_mem = &q_mem[rxq->rxq_id].rxq;
off = (unsigned long)&rxq_mem->pg_tbl_addr_lo;
writel(htonl(rxq_cfg.pg_tbl_addr_lo), base_addr + off);
off = (unsigned long)&rxq_mem->pg_tbl_addr_hi;
writel(htonl(rxq_cfg.pg_tbl_addr_hi), base_addr + off);
off = (unsigned long)&rxq_mem->cur_q_entry_lo;
writel(htonl(rxq_cfg.cur_q_entry_lo), base_addr + off);
off = (unsigned long)&rxq_mem->cur_q_entry_hi;
writel(htonl(rxq_cfg.cur_q_entry_hi), base_addr + off);
off = (unsigned long)&rxq_mem->pg_cnt_n_prd_ptr;
writel(rxq_cfg.pg_cnt_n_prd_ptr, base_addr + off);
off = (unsigned long)&rxq_mem->entry_n_pg_size;
writel(rxq_cfg.entry_n_pg_size, base_addr + off);
off = (unsigned long)&rxq_mem->sg_n_cq_n_cns_ptr;
writel(rxq_cfg.sg_n_cq_n_cns_ptr, base_addr + off);
off = (unsigned long)&rxq_mem->buf_sz_n_q_state;
writel(rxq_cfg.buf_sz_n_q_state, base_addr + off);
off = (unsigned long)&rxq_mem->next_qid;
writel(rxq_cfg.next_qid, base_addr + off);
rxq->rcb->producer_index = 0;
rxq->rcb->consumer_index = 0;
}
void
__bna_cq_start(struct bna_cq *cq)
{
struct bna_cq_mem cq_cfg, *cq_mem;
const struct bna_qpt *qpt;
struct bna_dma_addr cur_q_addr;
u32 pg_num;
struct bna *bna = cq->rx->bna;
void __iomem *base_addr;
unsigned long off;
qpt = &cq->qpt;
cur_q_addr = *((struct bna_dma_addr *)(qpt->kv_qpt_ptr));
/*
* Fill out structure, to be subsequently written
* to hardware
*/
cq_cfg.pg_tbl_addr_lo = qpt->hw_qpt_ptr.lsb;
cq_cfg.pg_tbl_addr_hi = qpt->hw_qpt_ptr.msb;
cq_cfg.cur_q_entry_lo = cur_q_addr.lsb;
cq_cfg.cur_q_entry_hi = cur_q_addr.msb;
cq_cfg.pg_cnt_n_prd_ptr = (qpt->page_count << 16) | 0x0;
cq_cfg.entry_n_pg_size =
((u32)(BFI_CQ_WI_SIZE >> 2) << 16) | (qpt->page_size >> 2);
cq_cfg.int_blk_n_cns_ptr = ((((u32)cq->ib_seg_offset) << 24) |
((u32)(cq->ib->ib_id & 0xff) << 16) | 0x0);
cq_cfg.q_state = BNA_Q_IDLE_STATE;
/* Write the page number register */
pg_num = BNA_GET_PAGE_NUM(HQM0_BLK_PG_NUM + bna->port_num,
HQM_CQ_RAM_BASE_OFFSET);
writel(pg_num, bna->regs.page_addr);
/* H/W write */
base_addr = BNA_GET_MEM_BASE_ADDR(bna->pcidev.pci_bar_kva,
HQM_CQ_RAM_BASE_OFFSET);
cq_mem = (struct bna_cq_mem *)0;
off = (unsigned long)&cq_mem[cq->cq_id].pg_tbl_addr_lo;
writel(htonl(cq_cfg.pg_tbl_addr_lo), base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].pg_tbl_addr_hi;
writel(htonl(cq_cfg.pg_tbl_addr_hi), base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].cur_q_entry_lo;
writel(htonl(cq_cfg.cur_q_entry_lo), base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].cur_q_entry_hi;
writel(htonl(cq_cfg.cur_q_entry_hi), base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].pg_cnt_n_prd_ptr;
writel(cq_cfg.pg_cnt_n_prd_ptr, base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].entry_n_pg_size;
writel(cq_cfg.entry_n_pg_size, base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].int_blk_n_cns_ptr;
writel(cq_cfg.int_blk_n_cns_ptr, base_addr + off);
off = (unsigned long)&cq_mem[cq->cq_id].q_state;
writel(cq_cfg.q_state, base_addr + off);
cq->ccb->producer_index = 0;
*(cq->ccb->hw_producer_index) = 0;
}
void
bna_rit_create(struct bna_rx *rx)
{
struct list_head *qe_rxp;
struct bna_rxp *rxp;
struct bna_rxq *q0 = NULL;
struct bna_rxq *q1 = NULL;
int offset;
offset = 0;
list_for_each(qe_rxp, &rx->rxp_q) {
rxp = (struct bna_rxp *)qe_rxp;
GET_RXQS(rxp, q0, q1);
rx->rxf.rit_segment->rit[offset].large_rxq_id = q0->rxq_id;
rx->rxf.rit_segment->rit[offset].small_rxq_id =
(q1 ? q1->rxq_id : 0);
offset++;
}
}
static int
_rx_can_satisfy(struct bna_rx_mod *rx_mod,
struct bna_rx_config *rx_cfg)
{
if ((rx_mod->rx_free_count == 0) ||
(rx_mod->rxp_free_count == 0) ||
(rx_mod->rxq_free_count == 0))
return 0;
if (rx_cfg->rxp_type == BNA_RXP_SINGLE) {
if ((rx_mod->rxp_free_count < rx_cfg->num_paths) ||
(rx_mod->rxq_free_count < rx_cfg->num_paths))
return 0;
} else {
if ((rx_mod->rxp_free_count < rx_cfg->num_paths) ||
(rx_mod->rxq_free_count < (2 * rx_cfg->num_paths)))
return 0;
}
if (!bna_rit_mod_can_satisfy(&rx_mod->bna->rit_mod, rx_cfg->num_paths))
return 0;
return 1;
}
static struct bna_rxq *
_get_free_rxq(struct bna_rx_mod *rx_mod)
{
struct bna_rxq *rxq = NULL;
struct list_head *qe = NULL;
bfa_q_deq(&rx_mod->rxq_free_q, &qe);
if (qe) {
rx_mod->rxq_free_count--;
rxq = (struct bna_rxq *)qe;
}
return rxq;
}
static void
_put_free_rxq(struct bna_rx_mod *rx_mod, struct bna_rxq *rxq)
{
bfa_q_qe_init(&rxq->qe);
list_add_tail(&rxq->qe, &rx_mod->rxq_free_q);
rx_mod->rxq_free_count++;
}
static struct bna_rxp *
_get_free_rxp(struct bna_rx_mod *rx_mod)
{
struct list_head *qe = NULL;
struct bna_rxp *rxp = NULL;
bfa_q_deq(&rx_mod->rxp_free_q, &qe);
if (qe) {
rx_mod->rxp_free_count--;
rxp = (struct bna_rxp *)qe;
}
return rxp;
}
static void
_put_free_rxp(struct bna_rx_mod *rx_mod, struct bna_rxp *rxp)
{
bfa_q_qe_init(&rxp->qe);
list_add_tail(&rxp->qe, &rx_mod->rxp_free_q);
rx_mod->rxp_free_count++;
}
static struct bna_rx *
_get_free_rx(struct bna_rx_mod *rx_mod)
{
struct list_head *qe = NULL;
struct bna_rx *rx = NULL;
bfa_q_deq(&rx_mod->rx_free_q, &qe);
if (qe) {
rx_mod->rx_free_count--;
rx = (struct bna_rx *)qe;
bfa_q_qe_init(qe);
list_add_tail(&rx->qe, &rx_mod->rx_active_q);
}
return rx;
}
static void
_put_free_rx(struct bna_rx_mod *rx_mod, struct bna_rx *rx)
{
bfa_q_qe_init(&rx->qe);
list_add_tail(&rx->qe, &rx_mod->rx_free_q);
rx_mod->rx_free_count++;
}
static void
_rx_init(struct bna_rx *rx, struct bna *bna)
{
rx->bna = bna;
rx->rx_flags = 0;
INIT_LIST_HEAD(&rx->rxp_q);
rx->rxq_stop_wc.wc_resume = bna_rx_cb_rxq_stopped_all;
rx->rxq_stop_wc.wc_cbarg = rx;
rx->rxq_stop_wc.wc_count = 0;
rx->stop_cbfn = NULL;
rx->stop_cbarg = NULL;
}
static void
_rxp_add_rxqs(struct bna_rxp *rxp,
struct bna_rxq *q0,
struct bna_rxq *q1)
{
switch (rxp->type) {
case BNA_RXP_SINGLE:
rxp->rxq.single.only = q0;
rxp->rxq.single.reserved = NULL;
break;
case BNA_RXP_SLR:
rxp->rxq.slr.large = q0;
rxp->rxq.slr.small = q1;
break;
case BNA_RXP_HDS:
rxp->rxq.hds.data = q0;
rxp->rxq.hds.hdr = q1;
break;
default:
break;
}
}
static void
_rxq_qpt_init(struct bna_rxq *rxq,
struct bna_rxp *rxp,
u32 page_count,
u32 page_size,
struct bna_mem_descr *qpt_mem,
struct bna_mem_descr *swqpt_mem,
struct bna_mem_descr *page_mem)
{
int i;
rxq->qpt.hw_qpt_ptr.lsb = qpt_mem->dma.lsb;
rxq->qpt.hw_qpt_ptr.msb = qpt_mem->dma.msb;
rxq->qpt.kv_qpt_ptr = qpt_mem->kva;
rxq->qpt.page_count = page_count;
rxq->qpt.page_size = page_size;
rxq->rcb->sw_qpt = (void **) swqpt_mem->kva;
for (i = 0; i < rxq->qpt.page_count; i++) {
rxq->rcb->sw_qpt[i] = page_mem[i].kva;
((struct bna_dma_addr *)rxq->qpt.kv_qpt_ptr)[i].lsb =
page_mem[i].dma.lsb;
((struct bna_dma_addr *)rxq->qpt.kv_qpt_ptr)[i].msb =
page_mem[i].dma.msb;
}
}
static void
_rxp_cqpt_setup(struct bna_rxp *rxp,
u32 page_count,
u32 page_size,
struct bna_mem_descr *qpt_mem,
struct bna_mem_descr *swqpt_mem,
struct bna_mem_descr *page_mem)
{
int i;
rxp->cq.qpt.hw_qpt_ptr.lsb = qpt_mem->dma.lsb;
rxp->cq.qpt.hw_qpt_ptr.msb = qpt_mem->dma.msb;
rxp->cq.qpt.kv_qpt_ptr = qpt_mem->kva;
rxp->cq.qpt.page_count = page_count;
rxp->cq.qpt.page_size = page_size;
rxp->cq.ccb->sw_qpt = (void **) swqpt_mem->kva;
for (i = 0; i < rxp->cq.qpt.page_count; i++) {
rxp->cq.ccb->sw_qpt[i] = page_mem[i].kva;
((struct bna_dma_addr *)rxp->cq.qpt.kv_qpt_ptr)[i].lsb =
page_mem[i].dma.lsb;
((struct bna_dma_addr *)rxp->cq.qpt.kv_qpt_ptr)[i].msb =
page_mem[i].dma.msb;
}
}
static void
_rx_add_rxp(struct bna_rx *rx, struct bna_rxp *rxp)
{
list_add_tail(&rxp->qe, &rx->rxp_q);
}
static void
_init_rxmod_queues(struct bna_rx_mod *rx_mod)
{
INIT_LIST_HEAD(&rx_mod->rx_free_q);
INIT_LIST_HEAD(&rx_mod->rxq_free_q);
INIT_LIST_HEAD(&rx_mod->rxp_free_q);
INIT_LIST_HEAD(&rx_mod->rx_active_q);
rx_mod->rx_free_count = 0;
rx_mod->rxq_free_count = 0;
rx_mod->rxp_free_count = 0;
}
static void
_rx_ctor(struct bna_rx *rx, int id)
{
bfa_q_qe_init(&rx->qe);
INIT_LIST_HEAD(&rx->rxp_q);
rx->bna = NULL;
rx->rxf.rxf_id = id;
/* FIXME: mbox_qe ctor()?? */
bfa_q_qe_init(&rx->mbox_qe.qe);
rx->stop_cbfn = NULL;
rx->stop_cbarg = NULL;
}
void
bna_rx_cb_multi_rxq_stopped(void *arg, int status)
{
struct bna_rxp *rxp = (struct bna_rxp *)arg;
bfa_wc_down(&rxp->rx->rxq_stop_wc);
}
void
bna_rx_cb_rxq_stopped_all(void *arg)
{
struct bna_rx *rx = (struct bna_rx *)arg;
bfa_fsm_send_event(rx, RX_E_RXQ_STOPPED);
}
static void
bna_rx_mod_cb_rx_stopped(void *arg, struct bna_rx *rx,
enum bna_cb_status status)
{
struct bna_rx_mod *rx_mod = (struct bna_rx_mod *)arg;
bfa_wc_down(&rx_mod->rx_stop_wc);
}
static void
bna_rx_mod_cb_rx_stopped_all(void *arg)
{
struct bna_rx_mod *rx_mod = (struct bna_rx_mod *)arg;
if (rx_mod->stop_cbfn)
rx_mod->stop_cbfn(&rx_mod->bna->port, BNA_CB_SUCCESS);
rx_mod->stop_cbfn = NULL;
}
static void
bna_rx_start(struct bna_rx *rx)
{
rx->rx_flags |= BNA_RX_F_PORT_ENABLED;
if (rx->rx_flags & BNA_RX_F_ENABLE)
bfa_fsm_send_event(rx, RX_E_START);
}
static void
bna_rx_stop(struct bna_rx *rx)
{
rx->rx_flags &= ~BNA_RX_F_PORT_ENABLED;
if (rx->fsm == (bfa_fsm_t) bna_rx_sm_stopped)
bna_rx_mod_cb_rx_stopped(&rx->bna->rx_mod, rx, BNA_CB_SUCCESS);
else {
rx->stop_cbfn = bna_rx_mod_cb_rx_stopped;
rx->stop_cbarg = &rx->bna->rx_mod;
bfa_fsm_send_event(rx, RX_E_STOP);
}
}
static void
bna_rx_fail(struct bna_rx *rx)
{
/* Indicate port is not enabled, and failed */
rx->rx_flags &= ~BNA_RX_F_PORT_ENABLED;
rx->rx_flags |= BNA_RX_F_PORT_FAILED;
bfa_fsm_send_event(rx, RX_E_FAIL);
}
void
bna_rx_mod_start(struct bna_rx_mod *rx_mod, enum bna_rx_type type)
{
struct bna_rx *rx;
struct list_head *qe;
rx_mod->flags |= BNA_RX_MOD_F_PORT_STARTED;
if (type == BNA_RX_T_LOOPBACK)
rx_mod->flags |= BNA_RX_MOD_F_PORT_LOOPBACK;
list_for_each(qe, &rx_mod->rx_active_q) {
rx = (struct bna_rx *)qe;
if (rx->type == type)
bna_rx_start(rx);
}
}
void
bna_rx_mod_stop(struct bna_rx_mod *rx_mod, enum bna_rx_type type)
{
struct bna_rx *rx;
struct list_head *qe;
rx_mod->flags &= ~BNA_RX_MOD_F_PORT_STARTED;
rx_mod->flags &= ~BNA_RX_MOD_F_PORT_LOOPBACK;
rx_mod->stop_cbfn = bna_port_cb_rx_stopped;
/**
* Before calling bna_rx_stop(), increment rx_stop_wc as many times
* as we are going to call bna_rx_stop
*/
list_for_each(qe, &rx_mod->rx_active_q) {
rx = (struct bna_rx *)qe;
if (rx->type == type)
bfa_wc_up(&rx_mod->rx_stop_wc);
}
if (rx_mod->rx_stop_wc.wc_count == 0) {
rx_mod->stop_cbfn(&rx_mod->bna->port, BNA_CB_SUCCESS);
rx_mod->stop_cbfn = NULL;
return;
}
list_for_each(qe, &rx_mod->rx_active_q) {
rx = (struct bna_rx *)qe;
if (rx->type == type)
bna_rx_stop(rx);
}
}
void
bna_rx_mod_fail(struct bna_rx_mod *rx_mod)
{
struct bna_rx *rx;
struct list_head *qe;
rx_mod->flags &= ~BNA_RX_MOD_F_PORT_STARTED;
rx_mod->flags &= ~BNA_RX_MOD_F_PORT_LOOPBACK;
list_for_each(qe, &rx_mod->rx_active_q) {
rx = (struct bna_rx *)qe;
bna_rx_fail(rx);
}
}
void bna_rx_mod_init(struct bna_rx_mod *rx_mod, struct bna *bna,
struct bna_res_info *res_info)
{
int index;
struct bna_rx *rx_ptr;
struct bna_rxp *rxp_ptr;
struct bna_rxq *rxq_ptr;
rx_mod->bna = bna;
rx_mod->flags = 0;
rx_mod->rx = (struct bna_rx *)
res_info[BNA_RES_MEM_T_RX_ARRAY].res_u.mem_info.mdl[0].kva;
rx_mod->rxp = (struct bna_rxp *)
res_info[BNA_RES_MEM_T_RXP_ARRAY].res_u.mem_info.mdl[0].kva;
rx_mod->rxq = (struct bna_rxq *)
res_info[BNA_RES_MEM_T_RXQ_ARRAY].res_u.mem_info.mdl[0].kva;
/* Initialize the queues */
_init_rxmod_queues(rx_mod);
/* Build RX queues */
for (index = 0; index < BFI_MAX_RXQ; index++) {
rx_ptr = &rx_mod->rx[index];
_rx_ctor(rx_ptr, index);
list_add_tail(&rx_ptr->qe, &rx_mod->rx_free_q);
rx_mod->rx_free_count++;
}
/* build RX-path queue */
for (index = 0; index < BFI_MAX_RXQ; index++) {
rxp_ptr = &rx_mod->rxp[index];
rxp_ptr->cq.cq_id = index;
bfa_q_qe_init(&rxp_ptr->qe);
list_add_tail(&rxp_ptr->qe, &rx_mod->rxp_free_q);
rx_mod->rxp_free_count++;
}
/* build RXQ queue */
for (index = 0; index < BFI_MAX_RXQ; index++) {
rxq_ptr = &rx_mod->rxq[index];
rxq_ptr->rxq_id = index;
bfa_q_qe_init(&rxq_ptr->qe);
list_add_tail(&rxq_ptr->qe, &rx_mod->rxq_free_q);
rx_mod->rxq_free_count++;
}
rx_mod->rx_stop_wc.wc_resume = bna_rx_mod_cb_rx_stopped_all;
rx_mod->rx_stop_wc.wc_cbarg = rx_mod;
rx_mod->rx_stop_wc.wc_count = 0;
}
void
bna_rx_mod_uninit(struct bna_rx_mod *rx_mod)
{
struct list_head *qe;
int i;
i = 0;
list_for_each(qe, &rx_mod->rx_free_q)
i++;
i = 0;
list_for_each(qe, &rx_mod->rxp_free_q)
i++;
i = 0;
list_for_each(qe, &rx_mod->rxq_free_q)
i++;
rx_mod->bna = NULL;
}
int
bna_rx_state_get(struct bna_rx *rx)
{
return bfa_sm_to_state(rx_sm_table, rx->fsm);
}
void
bna_rx_res_req(struct bna_rx_config *q_cfg, struct bna_res_info *res_info)
{
u32 cq_size, hq_size, dq_size;
u32 cpage_count, hpage_count, dpage_count;
struct bna_mem_info *mem_info;
u32 cq_depth;
u32 hq_depth;
u32 dq_depth;
dq_depth = q_cfg->q_depth;
hq_depth = ((q_cfg->rxp_type == BNA_RXP_SINGLE) ? 0 : q_cfg->q_depth);
cq_depth = dq_depth + hq_depth;
BNA_TO_POWER_OF_2_HIGH(cq_depth);
cq_size = cq_depth * BFI_CQ_WI_SIZE;
cq_size = ALIGN(cq_size, PAGE_SIZE);
cpage_count = SIZE_TO_PAGES(cq_size);
BNA_TO_POWER_OF_2_HIGH(dq_depth);
dq_size = dq_depth * BFI_RXQ_WI_SIZE;
dq_size = ALIGN(dq_size, PAGE_SIZE);
dpage_count = SIZE_TO_PAGES(dq_size);
if (BNA_RXP_SINGLE != q_cfg->rxp_type) {
BNA_TO_POWER_OF_2_HIGH(hq_depth);
hq_size = hq_depth * BFI_RXQ_WI_SIZE;
hq_size = ALIGN(hq_size, PAGE_SIZE);
hpage_count = SIZE_TO_PAGES(hq_size);
} else {
hpage_count = 0;
}
/* CCB structures */
res_info[BNA_RX_RES_MEM_T_CCB].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_CCB].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = sizeof(struct bna_ccb);
mem_info->num = q_cfg->num_paths;
/* RCB structures */
res_info[BNA_RX_RES_MEM_T_RCB].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_RCB].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = sizeof(struct bna_rcb);
mem_info->num = BNA_GET_RXQS(q_cfg);
/* Completion QPT */
res_info[BNA_RX_RES_MEM_T_CQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_CQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = cpage_count * sizeof(struct bna_dma_addr);
mem_info->num = q_cfg->num_paths;
/* Completion s/w QPT */
res_info[BNA_RX_RES_MEM_T_CSWQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_CSWQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = cpage_count * sizeof(void *);
mem_info->num = q_cfg->num_paths;
/* Completion QPT pages */
res_info[BNA_RX_RES_MEM_T_CQPT_PAGE].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_CQPT_PAGE].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = PAGE_SIZE;
mem_info->num = cpage_count * q_cfg->num_paths;
/* Data QPTs */
res_info[BNA_RX_RES_MEM_T_DQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_DQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = dpage_count * sizeof(struct bna_dma_addr);
mem_info->num = q_cfg->num_paths;
/* Data s/w QPTs */
res_info[BNA_RX_RES_MEM_T_DSWQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_DSWQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = dpage_count * sizeof(void *);
mem_info->num = q_cfg->num_paths;
/* Data QPT pages */
res_info[BNA_RX_RES_MEM_T_DPAGE].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_DPAGE].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = PAGE_SIZE;
mem_info->num = dpage_count * q_cfg->num_paths;
/* Hdr QPTs */
res_info[BNA_RX_RES_MEM_T_HQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_HQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = hpage_count * sizeof(struct bna_dma_addr);
mem_info->num = (hpage_count ? q_cfg->num_paths : 0);
/* Hdr s/w QPTs */
res_info[BNA_RX_RES_MEM_T_HSWQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_HSWQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = hpage_count * sizeof(void *);
mem_info->num = (hpage_count ? q_cfg->num_paths : 0);
/* Hdr QPT pages */
res_info[BNA_RX_RES_MEM_T_HPAGE].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_RX_RES_MEM_T_HPAGE].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = (hpage_count ? PAGE_SIZE : 0);
mem_info->num = (hpage_count ? (hpage_count * q_cfg->num_paths) : 0);
/* RX Interrupts */
res_info[BNA_RX_RES_T_INTR].res_type = BNA_RES_T_INTR;
res_info[BNA_RX_RES_T_INTR].res_u.intr_info.intr_type = BNA_INTR_T_MSIX;
res_info[BNA_RX_RES_T_INTR].res_u.intr_info.num = q_cfg->num_paths;
}
struct bna_rx *
bna_rx_create(struct bna *bna, struct bnad *bnad,
struct bna_rx_config *rx_cfg,
struct bna_rx_event_cbfn *rx_cbfn,
struct bna_res_info *res_info,
void *priv)
{
struct bna_rx_mod *rx_mod = &bna->rx_mod;
struct bna_rx *rx;
struct bna_rxp *rxp;
struct bna_rxq *q0;
struct bna_rxq *q1;
struct bna_intr_info *intr_info;
u32 page_count;
struct bna_mem_descr *ccb_mem;
struct bna_mem_descr *rcb_mem;
struct bna_mem_descr *unmapq_mem;
struct bna_mem_descr *cqpt_mem;
struct bna_mem_descr *cswqpt_mem;
struct bna_mem_descr *cpage_mem;
struct bna_mem_descr *hqpt_mem; /* Header/Small Q qpt */
struct bna_mem_descr *dqpt_mem; /* Data/Large Q qpt */
struct bna_mem_descr *hsqpt_mem; /* s/w qpt for hdr */
struct bna_mem_descr *dsqpt_mem; /* s/w qpt for data */
struct bna_mem_descr *hpage_mem; /* hdr page mem */
struct bna_mem_descr *dpage_mem; /* data page mem */
int i, cpage_idx = 0, dpage_idx = 0, hpage_idx = 0;
int dpage_count, hpage_count, rcb_idx;
struct bna_ib_config ibcfg;
/* Fail if we don't have enough RXPs, RXQs */
if (!_rx_can_satisfy(rx_mod, rx_cfg))
return NULL;
/* Initialize resource pointers */
intr_info = &res_info[BNA_RX_RES_T_INTR].res_u.intr_info;
ccb_mem = &res_info[BNA_RX_RES_MEM_T_CCB].res_u.mem_info.mdl[0];
rcb_mem = &res_info[BNA_RX_RES_MEM_T_RCB].res_u.mem_info.mdl[0];
unmapq_mem = &res_info[BNA_RX_RES_MEM_T_UNMAPQ].res_u.mem_info.mdl[0];
cqpt_mem = &res_info[BNA_RX_RES_MEM_T_CQPT].res_u.mem_info.mdl[0];
cswqpt_mem = &res_info[BNA_RX_RES_MEM_T_CSWQPT].res_u.mem_info.mdl[0];
cpage_mem = &res_info[BNA_RX_RES_MEM_T_CQPT_PAGE].res_u.mem_info.mdl[0];
hqpt_mem = &res_info[BNA_RX_RES_MEM_T_HQPT].res_u.mem_info.mdl[0];
dqpt_mem = &res_info[BNA_RX_RES_MEM_T_DQPT].res_u.mem_info.mdl[0];
hsqpt_mem = &res_info[BNA_RX_RES_MEM_T_HSWQPT].res_u.mem_info.mdl[0];
dsqpt_mem = &res_info[BNA_RX_RES_MEM_T_DSWQPT].res_u.mem_info.mdl[0];
hpage_mem = &res_info[BNA_RX_RES_MEM_T_HPAGE].res_u.mem_info.mdl[0];
dpage_mem = &res_info[BNA_RX_RES_MEM_T_DPAGE].res_u.mem_info.mdl[0];
/* Compute q depth & page count */
page_count = res_info[BNA_RX_RES_MEM_T_CQPT_PAGE].res_u.mem_info.num /
rx_cfg->num_paths;
dpage_count = res_info[BNA_RX_RES_MEM_T_DPAGE].res_u.mem_info.num /
rx_cfg->num_paths;
hpage_count = res_info[BNA_RX_RES_MEM_T_HPAGE].res_u.mem_info.num /
rx_cfg->num_paths;
/* Get RX pointer */
rx = _get_free_rx(rx_mod);
_rx_init(rx, bna);
rx->priv = priv;
rx->type = rx_cfg->rx_type;
rx->rcb_setup_cbfn = rx_cbfn->rcb_setup_cbfn;
rx->rcb_destroy_cbfn = rx_cbfn->rcb_destroy_cbfn;
rx->ccb_setup_cbfn = rx_cbfn->ccb_setup_cbfn;
rx->ccb_destroy_cbfn = rx_cbfn->ccb_destroy_cbfn;
/* Following callbacks are mandatory */
rx->rx_cleanup_cbfn = rx_cbfn->rx_cleanup_cbfn;
rx->rx_post_cbfn = rx_cbfn->rx_post_cbfn;
if (rx->bna->rx_mod.flags & BNA_RX_MOD_F_PORT_STARTED) {
switch (rx->type) {
case BNA_RX_T_REGULAR:
if (!(rx->bna->rx_mod.flags &
BNA_RX_MOD_F_PORT_LOOPBACK))
rx->rx_flags |= BNA_RX_F_PORT_ENABLED;
break;
case BNA_RX_T_LOOPBACK:
if (rx->bna->rx_mod.flags & BNA_RX_MOD_F_PORT_LOOPBACK)
rx->rx_flags |= BNA_RX_F_PORT_ENABLED;
break;
}
}
for (i = 0, rcb_idx = 0; i < rx_cfg->num_paths; i++) {
rxp = _get_free_rxp(rx_mod);
rxp->type = rx_cfg->rxp_type;
rxp->rx = rx;
rxp->cq.rx = rx;
/* Get required RXQs, and queue them to rx-path */
q0 = _get_free_rxq(rx_mod);
if (BNA_RXP_SINGLE == rx_cfg->rxp_type)
q1 = NULL;
else
q1 = _get_free_rxq(rx_mod);
/* Initialize IB */
if (1 == intr_info->num) {
rxp->cq.ib = bna_ib_get(&bna->ib_mod,
intr_info->intr_type,
intr_info->idl[0].vector);
rxp->vector = intr_info->idl[0].vector;
} else {
rxp->cq.ib = bna_ib_get(&bna->ib_mod,
intr_info->intr_type,
intr_info->idl[i].vector);
/* Map the MSI-x vector used for this RXP */
rxp->vector = intr_info->idl[i].vector;
}
rxp->cq.ib_seg_offset = bna_ib_reserve_idx(rxp->cq.ib);
ibcfg.coalescing_timeo = BFI_RX_COALESCING_TIMEO;
ibcfg.interpkt_count = BFI_RX_INTERPKT_COUNT;
ibcfg.interpkt_timeo = BFI_RX_INTERPKT_TIMEO;
ibcfg.ctrl_flags = BFI_IB_CF_INT_ENABLE;
bna_ib_config(rxp->cq.ib, &ibcfg);
/* Link rxqs to rxp */
_rxp_add_rxqs(rxp, q0, q1);
/* Link rxp to rx */
_rx_add_rxp(rx, rxp);
q0->rx = rx;
q0->rxp = rxp;
/* Initialize RCB for the large / data q */
q0->rcb = (struct bna_rcb *) rcb_mem[rcb_idx].kva;
RXQ_RCB_INIT(q0, rxp, rx_cfg->q_depth, bna, 0,
(void *)unmapq_mem[rcb_idx].kva);
rcb_idx++;
(q0)->rx_packets = (q0)->rx_bytes = 0;
(q0)->rx_packets_with_error = (q0)->rxbuf_alloc_failed = 0;
/* Initialize RXQs */
_rxq_qpt_init(q0, rxp, dpage_count, PAGE_SIZE,
&dqpt_mem[i], &dsqpt_mem[i], &dpage_mem[dpage_idx]);
q0->rcb->page_idx = dpage_idx;
q0->rcb->page_count = dpage_count;
dpage_idx += dpage_count;
/* Call bnad to complete rcb setup */
if (rx->rcb_setup_cbfn)
rx->rcb_setup_cbfn(bnad, q0->rcb);
if (q1) {
q1->rx = rx;
q1->rxp = rxp;
q1->rcb = (struct bna_rcb *) rcb_mem[rcb_idx].kva;
RXQ_RCB_INIT(q1, rxp, rx_cfg->q_depth, bna, 1,
(void *)unmapq_mem[rcb_idx].kva);
rcb_idx++;
(q1)->buffer_size = (rx_cfg)->small_buff_size;
(q1)->rx_packets = (q1)->rx_bytes = 0;
(q1)->rx_packets_with_error =
(q1)->rxbuf_alloc_failed = 0;
_rxq_qpt_init(q1, rxp, hpage_count, PAGE_SIZE,
&hqpt_mem[i], &hsqpt_mem[i],
&hpage_mem[hpage_idx]);
q1->rcb->page_idx = hpage_idx;
q1->rcb->page_count = hpage_count;
hpage_idx += hpage_count;
/* Call bnad to complete rcb setup */
if (rx->rcb_setup_cbfn)
rx->rcb_setup_cbfn(bnad, q1->rcb);
}
/* Setup RXP::CQ */
rxp->cq.ccb = (struct bna_ccb *) ccb_mem[i].kva;
_rxp_cqpt_setup(rxp, page_count, PAGE_SIZE,
&cqpt_mem[i], &cswqpt_mem[i], &cpage_mem[cpage_idx]);
rxp->cq.ccb->page_idx = cpage_idx;
rxp->cq.ccb->page_count = page_count;
cpage_idx += page_count;
rxp->cq.ccb->pkt_rate.small_pkt_cnt = 0;
rxp->cq.ccb->pkt_rate.large_pkt_cnt = 0;
rxp->cq.ccb->producer_index = 0;
rxp->cq.ccb->q_depth = rx_cfg->q_depth +
((rx_cfg->rxp_type == BNA_RXP_SINGLE) ?
0 : rx_cfg->q_depth);
rxp->cq.ccb->i_dbell = &rxp->cq.ib->door_bell;
rxp->cq.ccb->rcb[0] = q0->rcb;
if (q1)
rxp->cq.ccb->rcb[1] = q1->rcb;
rxp->cq.ccb->cq = &rxp->cq;
rxp->cq.ccb->bnad = bna->bnad;
rxp->cq.ccb->hw_producer_index =
((volatile u32 *)rxp->cq.ib->ib_seg_host_addr_kva +
(rxp->cq.ib_seg_offset * BFI_IBIDX_SIZE));
*(rxp->cq.ccb->hw_producer_index) = 0;
rxp->cq.ccb->intr_type = intr_info->intr_type;
rxp->cq.ccb->intr_vector = (intr_info->num == 1) ?
intr_info->idl[0].vector :
intr_info->idl[i].vector;
rxp->cq.ccb->rx_coalescing_timeo =
rxp->cq.ib->ib_config.coalescing_timeo;
rxp->cq.ccb->id = i;
/* Call bnad to complete CCB setup */
if (rx->ccb_setup_cbfn)
rx->ccb_setup_cbfn(bnad, rxp->cq.ccb);
} /* for each rx-path */
bna_rxf_init(&rx->rxf, rx, rx_cfg);
bfa_fsm_set_state(rx, bna_rx_sm_stopped);
return rx;
}
void
bna_rx_destroy(struct bna_rx *rx)
{
struct bna_rx_mod *rx_mod = &rx->bna->rx_mod;
struct bna_ib_mod *ib_mod = &rx->bna->ib_mod;
struct bna_rxq *q0 = NULL;
struct bna_rxq *q1 = NULL;
struct bna_rxp *rxp;
struct list_head *qe;
bna_rxf_uninit(&rx->rxf);
while (!list_empty(&rx->rxp_q)) {
bfa_q_deq(&rx->rxp_q, &rxp);
GET_RXQS(rxp, q0, q1);
/* Callback to bnad for destroying RCB */
if (rx->rcb_destroy_cbfn)
rx->rcb_destroy_cbfn(rx->bna->bnad, q0->rcb);
q0->rcb = NULL;
q0->rxp = NULL;
q0->rx = NULL;
_put_free_rxq(rx_mod, q0);
if (q1) {
/* Callback to bnad for destroying RCB */
if (rx->rcb_destroy_cbfn)
rx->rcb_destroy_cbfn(rx->bna->bnad, q1->rcb);
q1->rcb = NULL;
q1->rxp = NULL;
q1->rx = NULL;
_put_free_rxq(rx_mod, q1);
}
rxp->rxq.slr.large = NULL;
rxp->rxq.slr.small = NULL;
if (rxp->cq.ib) {
if (rxp->cq.ib_seg_offset != 0xff)
bna_ib_release_idx(rxp->cq.ib,
rxp->cq.ib_seg_offset);
bna_ib_put(ib_mod, rxp->cq.ib);
rxp->cq.ib = NULL;
}
/* Callback to bnad for destroying CCB */
if (rx->ccb_destroy_cbfn)
rx->ccb_destroy_cbfn(rx->bna->bnad, rxp->cq.ccb);
rxp->cq.ccb = NULL;
rxp->rx = NULL;
_put_free_rxp(rx_mod, rxp);
}
list_for_each(qe, &rx_mod->rx_active_q) {
if (qe == &rx->qe) {
list_del(&rx->qe);
bfa_q_qe_init(&rx->qe);
break;
}
}
rx->bna = NULL;
rx->priv = NULL;
_put_free_rx(rx_mod, rx);
}
void
bna_rx_enable(struct bna_rx *rx)
{
if (rx->fsm != (bfa_sm_t)bna_rx_sm_stopped)
return;
rx->rx_flags |= BNA_RX_F_ENABLE;
if (rx->rx_flags & BNA_RX_F_PORT_ENABLED)
bfa_fsm_send_event(rx, RX_E_START);
}
void
bna_rx_disable(struct bna_rx *rx, enum bna_cleanup_type type,
void (*cbfn)(void *, struct bna_rx *,
enum bna_cb_status))
{
if (type == BNA_SOFT_CLEANUP) {
/* h/w should not be accessed. Treat we're stopped */
(*cbfn)(rx->bna->bnad, rx, BNA_CB_SUCCESS);
} else {
rx->stop_cbfn = cbfn;
rx->stop_cbarg = rx->bna->bnad;
rx->rx_flags &= ~BNA_RX_F_ENABLE;
bfa_fsm_send_event(rx, RX_E_STOP);
}
}
/**
* TX
*/
#define call_tx_stop_cbfn(tx, status)\
do {\
if ((tx)->stop_cbfn)\
(tx)->stop_cbfn((tx)->stop_cbarg, (tx), status);\
(tx)->stop_cbfn = NULL;\
(tx)->stop_cbarg = NULL;\
} while (0)
#define call_tx_prio_change_cbfn(tx, status)\
do {\
if ((tx)->prio_change_cbfn)\
(tx)->prio_change_cbfn((tx)->bna->bnad, (tx), status);\
(tx)->prio_change_cbfn = NULL;\
} while (0)
static void bna_tx_mod_cb_tx_stopped(void *tx_mod, struct bna_tx *tx,
enum bna_cb_status status);
static void bna_tx_cb_txq_stopped(void *arg, int status);
static void bna_tx_cb_stats_cleared(void *arg, int status);
static void __bna_tx_stop(struct bna_tx *tx);
static void __bna_tx_start(struct bna_tx *tx);
static void __bna_txf_stat_clr(struct bna_tx *tx);
enum bna_tx_event {
TX_E_START = 1,
TX_E_STOP = 2,
TX_E_FAIL = 3,
TX_E_TXQ_STOPPED = 4,
TX_E_PRIO_CHANGE = 5,
TX_E_STAT_CLEARED = 6,
};
enum bna_tx_state {
BNA_TX_STOPPED = 1,
BNA_TX_STARTED = 2,
BNA_TX_TXQ_STOP_WAIT = 3,
BNA_TX_PRIO_STOP_WAIT = 4,
BNA_TX_STAT_CLR_WAIT = 5,
};
bfa_fsm_state_decl(bna_tx, stopped, struct bna_tx,
enum bna_tx_event);
bfa_fsm_state_decl(bna_tx, started, struct bna_tx,
enum bna_tx_event);
bfa_fsm_state_decl(bna_tx, txq_stop_wait, struct bna_tx,
enum bna_tx_event);
bfa_fsm_state_decl(bna_tx, prio_stop_wait, struct bna_tx,
enum bna_tx_event);
bfa_fsm_state_decl(bna_tx, stat_clr_wait, struct bna_tx,
enum bna_tx_event);
static struct bfa_sm_table tx_sm_table[] = {
{BFA_SM(bna_tx_sm_stopped), BNA_TX_STOPPED},
{BFA_SM(bna_tx_sm_started), BNA_TX_STARTED},
{BFA_SM(bna_tx_sm_txq_stop_wait), BNA_TX_TXQ_STOP_WAIT},
{BFA_SM(bna_tx_sm_prio_stop_wait), BNA_TX_PRIO_STOP_WAIT},
{BFA_SM(bna_tx_sm_stat_clr_wait), BNA_TX_STAT_CLR_WAIT},
};
static void
bna_tx_sm_stopped_entry(struct bna_tx *tx)
{
struct bna_txq *txq;
struct list_head *qe;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
(tx->tx_cleanup_cbfn)(tx->bna->bnad, txq->tcb);
}
call_tx_stop_cbfn(tx, BNA_CB_SUCCESS);
}
static void
bna_tx_sm_stopped(struct bna_tx *tx, enum bna_tx_event event)
{
switch (event) {
case TX_E_START:
bfa_fsm_set_state(tx, bna_tx_sm_started);
break;
case TX_E_STOP:
bfa_fsm_set_state(tx, bna_tx_sm_stopped);
break;
case TX_E_FAIL:
/* No-op */
break;
case TX_E_PRIO_CHANGE:
call_tx_prio_change_cbfn(tx, BNA_CB_SUCCESS);
break;
case TX_E_TXQ_STOPPED:
/**
* This event is received due to flushing of mbox when
* device fails
*/
/* No-op */
break;
default:
bfa_sm_fault(tx->bna, event);
}
}
static void
bna_tx_sm_started_entry(struct bna_tx *tx)
{
struct bna_txq *txq;
struct list_head *qe;
__bna_tx_start(tx);
/* Start IB */
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
bna_ib_ack(&txq->ib->door_bell, 0);
}
}
static void
bna_tx_sm_started(struct bna_tx *tx, enum bna_tx_event event)
{
struct bna_txq *txq;
struct list_head *qe;
switch (event) {
case TX_E_STOP:
bfa_fsm_set_state(tx, bna_tx_sm_txq_stop_wait);
__bna_tx_stop(tx);
break;
case TX_E_FAIL:
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
bna_ib_fail(txq->ib);
(tx->tx_stall_cbfn)(tx->bna->bnad, txq->tcb);
}
bfa_fsm_set_state(tx, bna_tx_sm_stopped);
break;
case TX_E_PRIO_CHANGE:
bfa_fsm_set_state(tx, bna_tx_sm_prio_stop_wait);
break;
default:
bfa_sm_fault(tx->bna, event);
}
}
static void
bna_tx_sm_txq_stop_wait_entry(struct bna_tx *tx)
{
}
static void
bna_tx_sm_txq_stop_wait(struct bna_tx *tx, enum bna_tx_event event)
{
struct bna_txq *txq;
struct list_head *qe;
switch (event) {
case TX_E_FAIL:
bfa_fsm_set_state(tx, bna_tx_sm_stopped);
break;
case TX_E_TXQ_STOPPED:
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
bna_ib_stop(txq->ib);
}
bfa_fsm_set_state(tx, bna_tx_sm_stat_clr_wait);
break;
case TX_E_PRIO_CHANGE:
/* No-op */
break;
default:
bfa_sm_fault(tx->bna, event);
}
}
static void
bna_tx_sm_prio_stop_wait_entry(struct bna_tx *tx)
{
__bna_tx_stop(tx);
}
static void
bna_tx_sm_prio_stop_wait(struct bna_tx *tx, enum bna_tx_event event)
{
struct bna_txq *txq;
struct list_head *qe;
switch (event) {
case TX_E_STOP:
bfa_fsm_set_state(tx, bna_tx_sm_txq_stop_wait);
break;
case TX_E_FAIL:
call_tx_prio_change_cbfn(tx, BNA_CB_FAIL);
bfa_fsm_set_state(tx, bna_tx_sm_stopped);
break;
case TX_E_TXQ_STOPPED:
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
bna_ib_stop(txq->ib);
(tx->tx_cleanup_cbfn)(tx->bna->bnad, txq->tcb);
}
call_tx_prio_change_cbfn(tx, BNA_CB_SUCCESS);
bfa_fsm_set_state(tx, bna_tx_sm_started);
break;
case TX_E_PRIO_CHANGE:
/* No-op */
break;
default:
bfa_sm_fault(tx->bna, event);
}
}
static void
bna_tx_sm_stat_clr_wait_entry(struct bna_tx *tx)
{
__bna_txf_stat_clr(tx);
}
static void
bna_tx_sm_stat_clr_wait(struct bna_tx *tx, enum bna_tx_event event)
{
switch (event) {
case TX_E_FAIL:
case TX_E_STAT_CLEARED:
bfa_fsm_set_state(tx, bna_tx_sm_stopped);
break;
default:
bfa_sm_fault(tx->bna, event);
}
}
static void
__bna_txq_start(struct bna_tx *tx, struct bna_txq *txq)
{
struct bna_rxtx_q_mem *q_mem;
struct bna_txq_mem txq_cfg;
struct bna_txq_mem *txq_mem;
struct bna_dma_addr cur_q_addr;
u32 pg_num;
void __iomem *base_addr;
unsigned long off;
/* Fill out structure, to be subsequently written to hardware */
txq_cfg.pg_tbl_addr_lo = txq->qpt.hw_qpt_ptr.lsb;
txq_cfg.pg_tbl_addr_hi = txq->qpt.hw_qpt_ptr.msb;
cur_q_addr = *((struct bna_dma_addr *)(txq->qpt.kv_qpt_ptr));
txq_cfg.cur_q_entry_lo = cur_q_addr.lsb;
txq_cfg.cur_q_entry_hi = cur_q_addr.msb;
txq_cfg.pg_cnt_n_prd_ptr = (txq->qpt.page_count << 16) | 0x0;
txq_cfg.entry_n_pg_size = ((u32)(BFI_TXQ_WI_SIZE >> 2) << 16) |
(txq->qpt.page_size >> 2);
txq_cfg.int_blk_n_cns_ptr = ((((u32)txq->ib_seg_offset) << 24) |
((u32)(txq->ib->ib_id & 0xff) << 16) | 0x0);
txq_cfg.cns_ptr2_n_q_state = BNA_Q_IDLE_STATE;
txq_cfg.nxt_qid_n_fid_n_pri = (((tx->txf.txf_id & 0x3f) << 3) |
(txq->priority & 0x7));
txq_cfg.wvc_n_cquota_n_rquota =
((((u32)BFI_TX_MAX_WRR_QUOTA & 0xfff) << 12) |
(BFI_TX_MAX_WRR_QUOTA & 0xfff));
/* Setup the page and write to H/W */
pg_num = BNA_GET_PAGE_NUM(HQM0_BLK_PG_NUM + tx->bna->port_num,
HQM_RXTX_Q_RAM_BASE_OFFSET);
writel(pg_num, tx->bna->regs.page_addr);
base_addr = BNA_GET_MEM_BASE_ADDR(tx->bna->pcidev.pci_bar_kva,
HQM_RXTX_Q_RAM_BASE_OFFSET);
q_mem = (struct bna_rxtx_q_mem *)0;
txq_mem = &q_mem[txq->txq_id].txq;
/*
* The following 4 lines, is a hack b'cos the H/W needs to read
* these DMA addresses as little endian
*/
off = (unsigned long)&txq_mem->pg_tbl_addr_lo;
writel(htonl(txq_cfg.pg_tbl_addr_lo), base_addr + off);
off = (unsigned long)&txq_mem->pg_tbl_addr_hi;
writel(htonl(txq_cfg.pg_tbl_addr_hi), base_addr + off);
off = (unsigned long)&txq_mem->cur_q_entry_lo;
writel(htonl(txq_cfg.cur_q_entry_lo), base_addr + off);
off = (unsigned long)&txq_mem->cur_q_entry_hi;
writel(htonl(txq_cfg.cur_q_entry_hi), base_addr + off);
off = (unsigned long)&txq_mem->pg_cnt_n_prd_ptr;
writel(txq_cfg.pg_cnt_n_prd_ptr, base_addr + off);
off = (unsigned long)&txq_mem->entry_n_pg_size;
writel(txq_cfg.entry_n_pg_size, base_addr + off);
off = (unsigned long)&txq_mem->int_blk_n_cns_ptr;
writel(txq_cfg.int_blk_n_cns_ptr, base_addr + off);
off = (unsigned long)&txq_mem->cns_ptr2_n_q_state;
writel(txq_cfg.cns_ptr2_n_q_state, base_addr + off);
off = (unsigned long)&txq_mem->nxt_qid_n_fid_n_pri;
writel(txq_cfg.nxt_qid_n_fid_n_pri, base_addr + off);
off = (unsigned long)&txq_mem->wvc_n_cquota_n_rquota;
writel(txq_cfg.wvc_n_cquota_n_rquota, base_addr + off);
txq->tcb->producer_index = 0;
txq->tcb->consumer_index = 0;
*(txq->tcb->hw_consumer_index) = 0;
}
static void
__bna_txq_stop(struct bna_tx *tx, struct bna_txq *txq)
{
struct bfi_ll_q_stop_req ll_req;
u32 bit_mask[2] = {0, 0};
if (txq->txq_id < 32)
bit_mask[0] = (u32)1 << txq->txq_id;
else
bit_mask[1] = (u32)1 << (txq->txq_id - 32);
memset(&ll_req, 0, sizeof(ll_req));
ll_req.mh.msg_class = BFI_MC_LL;
ll_req.mh.msg_id = BFI_LL_H2I_TXQ_STOP_REQ;
ll_req.mh.mtag.h2i.lpu_id = 0;
ll_req.q_id_mask[0] = htonl(bit_mask[0]);
ll_req.q_id_mask[1] = htonl(bit_mask[1]);
bna_mbox_qe_fill(&tx->mbox_qe, &ll_req, sizeof(ll_req),
bna_tx_cb_txq_stopped, tx);
bna_mbox_send(tx->bna, &tx->mbox_qe);
}
static void
__bna_txf_start(struct bna_tx *tx)
{
struct bna_tx_fndb_ram *tx_fndb;
struct bna_txf *txf = &tx->txf;
void __iomem *base_addr;
unsigned long off;
writel(BNA_GET_PAGE_NUM(LUT0_MEM_BLK_BASE_PG_NUM +
(tx->bna->port_num * 2), TX_FNDB_RAM_BASE_OFFSET),
tx->bna->regs.page_addr);
base_addr = BNA_GET_MEM_BASE_ADDR(tx->bna->pcidev.pci_bar_kva,
TX_FNDB_RAM_BASE_OFFSET);
tx_fndb = (struct bna_tx_fndb_ram *)0;
off = (unsigned long)&tx_fndb[txf->txf_id].vlan_n_ctrl_flags;
writel(((u32)txf->vlan << 16) | txf->ctrl_flags,
base_addr + off);
if (tx->txf.txf_id < 32)
tx->bna->tx_mod.txf_bmap[0] |= ((u32)1 << tx->txf.txf_id);
else
tx->bna->tx_mod.txf_bmap[1] |= ((u32)
1 << (tx->txf.txf_id - 32));
}
static void
__bna_txf_stop(struct bna_tx *tx)
{
struct bna_tx_fndb_ram *tx_fndb;
u32 page_num;
u32 ctl_flags;
struct bna_txf *txf = &tx->txf;
void __iomem *base_addr;
unsigned long off;
/* retrieve the running txf_flags & turn off enable bit */
page_num = BNA_GET_PAGE_NUM(LUT0_MEM_BLK_BASE_PG_NUM +
(tx->bna->port_num * 2), TX_FNDB_RAM_BASE_OFFSET);
writel(page_num, tx->bna->regs.page_addr);
base_addr = BNA_GET_MEM_BASE_ADDR(tx->bna->pcidev.pci_bar_kva,
TX_FNDB_RAM_BASE_OFFSET);
tx_fndb = (struct bna_tx_fndb_ram *)0;
off = (unsigned long)&tx_fndb[txf->txf_id].vlan_n_ctrl_flags;
ctl_flags = readl(base_addr + off);
ctl_flags &= ~BFI_TXF_CF_ENABLE;
writel(ctl_flags, base_addr + off);
if (tx->txf.txf_id < 32)
tx->bna->tx_mod.txf_bmap[0] &= ~((u32)1 << tx->txf.txf_id);
else
tx->bna->tx_mod.txf_bmap[0] &= ~((u32)
1 << (tx->txf.txf_id - 32));
}
static void
__bna_txf_stat_clr(struct bna_tx *tx)
{
struct bfi_ll_stats_req ll_req;
u32 txf_bmap[2] = {0, 0};
if (tx->txf.txf_id < 32)
txf_bmap[0] = ((u32)1 << tx->txf.txf_id);
else
txf_bmap[1] = ((u32)1 << (tx->txf.txf_id - 32));
bfi_h2i_set(ll_req.mh, BFI_MC_LL, BFI_LL_H2I_STATS_CLEAR_REQ, 0);
ll_req.stats_mask = 0;
ll_req.rxf_id_mask[0] = 0;
ll_req.rxf_id_mask[1] = 0;
ll_req.txf_id_mask[0] = htonl(txf_bmap[0]);
ll_req.txf_id_mask[1] = htonl(txf_bmap[1]);
bna_mbox_qe_fill(&tx->mbox_qe, &ll_req, sizeof(ll_req),
bna_tx_cb_stats_cleared, tx);
bna_mbox_send(tx->bna, &tx->mbox_qe);
}
static void
__bna_tx_start(struct bna_tx *tx)
{
struct bna_txq *txq;
struct list_head *qe;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
bna_ib_start(txq->ib);
__bna_txq_start(tx, txq);
}
__bna_txf_start(tx);
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
txq->tcb->priority = txq->priority;
(tx->tx_resume_cbfn)(tx->bna->bnad, txq->tcb);
}
}
static void
__bna_tx_stop(struct bna_tx *tx)
{
struct bna_txq *txq;
struct list_head *qe;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
(tx->tx_stall_cbfn)(tx->bna->bnad, txq->tcb);
}
__bna_txf_stop(tx);
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
bfa_wc_up(&tx->txq_stop_wc);
}
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
__bna_txq_stop(tx, txq);
}
}
static void
bna_txq_qpt_setup(struct bna_txq *txq, int page_count, int page_size,
struct bna_mem_descr *qpt_mem,
struct bna_mem_descr *swqpt_mem,
struct bna_mem_descr *page_mem)
{
int i;
txq->qpt.hw_qpt_ptr.lsb = qpt_mem->dma.lsb;
txq->qpt.hw_qpt_ptr.msb = qpt_mem->dma.msb;
txq->qpt.kv_qpt_ptr = qpt_mem->kva;
txq->qpt.page_count = page_count;
txq->qpt.page_size = page_size;
txq->tcb->sw_qpt = (void **) swqpt_mem->kva;
for (i = 0; i < page_count; i++) {
txq->tcb->sw_qpt[i] = page_mem[i].kva;
((struct bna_dma_addr *)txq->qpt.kv_qpt_ptr)[i].lsb =
page_mem[i].dma.lsb;
((struct bna_dma_addr *)txq->qpt.kv_qpt_ptr)[i].msb =
page_mem[i].dma.msb;
}
}
static void
bna_tx_free(struct bna_tx *tx)
{
struct bna_tx_mod *tx_mod = &tx->bna->tx_mod;
struct bna_txq *txq;
struct bna_ib_mod *ib_mod = &tx->bna->ib_mod;
struct list_head *qe;
while (!list_empty(&tx->txq_q)) {
bfa_q_deq(&tx->txq_q, &txq);
bfa_q_qe_init(&txq->qe);
if (txq->ib) {
if (txq->ib_seg_offset != -1)
bna_ib_release_idx(txq->ib,
txq->ib_seg_offset);
bna_ib_put(ib_mod, txq->ib);
txq->ib = NULL;
}
txq->tcb = NULL;
txq->tx = NULL;
list_add_tail(&txq->qe, &tx_mod->txq_free_q);
}
list_for_each(qe, &tx_mod->tx_active_q) {
if (qe == &tx->qe) {
list_del(&tx->qe);
bfa_q_qe_init(&tx->qe);
break;
}
}
tx->bna = NULL;
tx->priv = NULL;
list_add_tail(&tx->qe, &tx_mod->tx_free_q);
}
static void
bna_tx_cb_txq_stopped(void *arg, int status)
{
struct bna_tx *tx = (struct bna_tx *)arg;
bfa_q_qe_init(&tx->mbox_qe.qe);
bfa_wc_down(&tx->txq_stop_wc);
}
static void
bna_tx_cb_txq_stopped_all(void *arg)
{
struct bna_tx *tx = (struct bna_tx *)arg;
bfa_fsm_send_event(tx, TX_E_TXQ_STOPPED);
}
static void
bna_tx_cb_stats_cleared(void *arg, int status)
{
struct bna_tx *tx = (struct bna_tx *)arg;
bfa_q_qe_init(&tx->mbox_qe.qe);
bfa_fsm_send_event(tx, TX_E_STAT_CLEARED);
}
static void
bna_tx_start(struct bna_tx *tx)
{
tx->flags |= BNA_TX_F_PORT_STARTED;
if (tx->flags & BNA_TX_F_ENABLED)
bfa_fsm_send_event(tx, TX_E_START);
}
static void
bna_tx_stop(struct bna_tx *tx)
{
tx->stop_cbfn = bna_tx_mod_cb_tx_stopped;
tx->stop_cbarg = &tx->bna->tx_mod;
tx->flags &= ~BNA_TX_F_PORT_STARTED;
bfa_fsm_send_event(tx, TX_E_STOP);
}
static void
bna_tx_fail(struct bna_tx *tx)
{
tx->flags &= ~BNA_TX_F_PORT_STARTED;
bfa_fsm_send_event(tx, TX_E_FAIL);
}
static void
bna_tx_prio_changed(struct bna_tx *tx, int prio)
{
struct bna_txq *txq;
struct list_head *qe;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
txq->priority = prio;
}
bfa_fsm_send_event(tx, TX_E_PRIO_CHANGE);
}
static void
bna_tx_cee_link_status(struct bna_tx *tx, int cee_link)
{
if (cee_link)
tx->flags |= BNA_TX_F_PRIO_LOCK;
else
tx->flags &= ~BNA_TX_F_PRIO_LOCK;
}
static void
bna_tx_mod_cb_tx_stopped(void *arg, struct bna_tx *tx,
enum bna_cb_status status)
{
struct bna_tx_mod *tx_mod = (struct bna_tx_mod *)arg;
bfa_wc_down(&tx_mod->tx_stop_wc);
}
static void
bna_tx_mod_cb_tx_stopped_all(void *arg)
{
struct bna_tx_mod *tx_mod = (struct bna_tx_mod *)arg;
if (tx_mod->stop_cbfn)
tx_mod->stop_cbfn(&tx_mod->bna->port, BNA_CB_SUCCESS);
tx_mod->stop_cbfn = NULL;
}
void
bna_tx_res_req(int num_txq, int txq_depth, struct bna_res_info *res_info)
{
u32 q_size;
u32 page_count;
struct bna_mem_info *mem_info;
res_info[BNA_TX_RES_MEM_T_TCB].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_TX_RES_MEM_T_TCB].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = sizeof(struct bna_tcb);
mem_info->num = num_txq;
q_size = txq_depth * BFI_TXQ_WI_SIZE;
q_size = ALIGN(q_size, PAGE_SIZE);
page_count = q_size >> PAGE_SHIFT;
res_info[BNA_TX_RES_MEM_T_QPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_TX_RES_MEM_T_QPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = page_count * sizeof(struct bna_dma_addr);
mem_info->num = num_txq;
res_info[BNA_TX_RES_MEM_T_SWQPT].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_TX_RES_MEM_T_SWQPT].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_KVA;
mem_info->len = page_count * sizeof(void *);
mem_info->num = num_txq;
res_info[BNA_TX_RES_MEM_T_PAGE].res_type = BNA_RES_T_MEM;
mem_info = &res_info[BNA_TX_RES_MEM_T_PAGE].res_u.mem_info;
mem_info->mem_type = BNA_MEM_T_DMA;
mem_info->len = PAGE_SIZE;
mem_info->num = num_txq * page_count;
res_info[BNA_TX_RES_INTR_T_TXCMPL].res_type = BNA_RES_T_INTR;
res_info[BNA_TX_RES_INTR_T_TXCMPL].res_u.intr_info.intr_type =
BNA_INTR_T_MSIX;
res_info[BNA_TX_RES_INTR_T_TXCMPL].res_u.intr_info.num = num_txq;
}
struct bna_tx *
bna_tx_create(struct bna *bna, struct bnad *bnad,
struct bna_tx_config *tx_cfg,
struct bna_tx_event_cbfn *tx_cbfn,
struct bna_res_info *res_info, void *priv)
{
struct bna_intr_info *intr_info;
struct bna_tx_mod *tx_mod = &bna->tx_mod;
struct bna_tx *tx;
struct bna_txq *txq;
struct list_head *qe;
struct bna_ib_mod *ib_mod = &bna->ib_mod;
struct bna_doorbell_qset *qset;
struct bna_ib_config ib_config;
int page_count;
int page_size;
int page_idx;
int i;
unsigned long off;
intr_info = &res_info[BNA_TX_RES_INTR_T_TXCMPL].res_u.intr_info;
page_count = (res_info[BNA_TX_RES_MEM_T_PAGE].res_u.mem_info.num) /
tx_cfg->num_txq;
page_size = res_info[BNA_TX_RES_MEM_T_PAGE].res_u.mem_info.len;
/**
* Get resources
*/
if ((intr_info->num != 1) && (intr_info->num != tx_cfg->num_txq))
return NULL;
/* Tx */
if (list_empty(&tx_mod->tx_free_q))
return NULL;
bfa_q_deq(&tx_mod->tx_free_q, &tx);
bfa_q_qe_init(&tx->qe);
/* TxQs */
INIT_LIST_HEAD(&tx->txq_q);
for (i = 0; i < tx_cfg->num_txq; i++) {
if (list_empty(&tx_mod->txq_free_q))
goto err_return;
bfa_q_deq(&tx_mod->txq_free_q, &txq);
bfa_q_qe_init(&txq->qe);
list_add_tail(&txq->qe, &tx->txq_q);
txq->ib = NULL;
txq->ib_seg_offset = -1;
txq->tx = tx;
}
/* IBs */
i = 0;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
if (intr_info->num == 1)
txq->ib = bna_ib_get(ib_mod, intr_info->intr_type,
intr_info->idl[0].vector);
else
txq->ib = bna_ib_get(ib_mod, intr_info->intr_type,
intr_info->idl[i].vector);
if (txq->ib == NULL)
goto err_return;
txq->ib_seg_offset = bna_ib_reserve_idx(txq->ib);
if (txq->ib_seg_offset == -1)
goto err_return;
i++;
}
/*
* Initialize
*/
/* Tx */
tx->tcb_setup_cbfn = tx_cbfn->tcb_setup_cbfn;
tx->tcb_destroy_cbfn = tx_cbfn->tcb_destroy_cbfn;
/* Following callbacks are mandatory */
tx->tx_stall_cbfn = tx_cbfn->tx_stall_cbfn;
tx->tx_resume_cbfn = tx_cbfn->tx_resume_cbfn;
tx->tx_cleanup_cbfn = tx_cbfn->tx_cleanup_cbfn;
list_add_tail(&tx->qe, &tx_mod->tx_active_q);
tx->bna = bna;
tx->priv = priv;
tx->txq_stop_wc.wc_resume = bna_tx_cb_txq_stopped_all;
tx->txq_stop_wc.wc_cbarg = tx;
tx->txq_stop_wc.wc_count = 0;
tx->type = tx_cfg->tx_type;
tx->flags = 0;
if (tx->bna->tx_mod.flags & BNA_TX_MOD_F_PORT_STARTED) {
switch (tx->type) {
case BNA_TX_T_REGULAR:
if (!(tx->bna->tx_mod.flags &
BNA_TX_MOD_F_PORT_LOOPBACK))
tx->flags |= BNA_TX_F_PORT_STARTED;
break;
case BNA_TX_T_LOOPBACK:
if (tx->bna->tx_mod.flags & BNA_TX_MOD_F_PORT_LOOPBACK)
tx->flags |= BNA_TX_F_PORT_STARTED;
break;
}
}
if (tx->bna->tx_mod.cee_link)
tx->flags |= BNA_TX_F_PRIO_LOCK;
/* TxQ */
i = 0;
page_idx = 0;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
txq->priority = tx_mod->priority;
txq->tcb = (struct bna_tcb *)
res_info[BNA_TX_RES_MEM_T_TCB].res_u.mem_info.mdl[i].kva;
txq->tx_packets = 0;
txq->tx_bytes = 0;
/* IB */
ib_config.coalescing_timeo = BFI_TX_COALESCING_TIMEO;
ib_config.interpkt_timeo = 0; /* Not used */
ib_config.interpkt_count = BFI_TX_INTERPKT_COUNT;
ib_config.ctrl_flags = (BFI_IB_CF_INTER_PKT_DMA |
BFI_IB_CF_INT_ENABLE |
BFI_IB_CF_COALESCING_MODE);
bna_ib_config(txq->ib, &ib_config);
/* TCB */
txq->tcb->producer_index = 0;
txq->tcb->consumer_index = 0;
txq->tcb->hw_consumer_index = (volatile u32 *)
((volatile u8 *)txq->ib->ib_seg_host_addr_kva +
(txq->ib_seg_offset * BFI_IBIDX_SIZE));
*(txq->tcb->hw_consumer_index) = 0;
txq->tcb->q_depth = tx_cfg->txq_depth;
txq->tcb->unmap_q = (void *)
res_info[BNA_TX_RES_MEM_T_UNMAPQ].res_u.mem_info.mdl[i].kva;
qset = (struct bna_doorbell_qset *)0;
off = (unsigned long)&qset[txq->txq_id].txq[0];
txq->tcb->q_dbell = off +
BNA_GET_DOORBELL_BASE_ADDR(bna->pcidev.pci_bar_kva);
txq->tcb->i_dbell = &txq->ib->door_bell;
txq->tcb->intr_type = intr_info->intr_type;
txq->tcb->intr_vector = (intr_info->num == 1) ?
intr_info->idl[0].vector :
intr_info->idl[i].vector;
txq->tcb->txq = txq;
txq->tcb->bnad = bnad;
txq->tcb->id = i;
/* QPT, SWQPT, Pages */
bna_txq_qpt_setup(txq, page_count, page_size,
&res_info[BNA_TX_RES_MEM_T_QPT].res_u.mem_info.mdl[i],
&res_info[BNA_TX_RES_MEM_T_SWQPT].res_u.mem_info.mdl[i],
&res_info[BNA_TX_RES_MEM_T_PAGE].
res_u.mem_info.mdl[page_idx]);
txq->tcb->page_idx = page_idx;
txq->tcb->page_count = page_count;
page_idx += page_count;
/* Callback to bnad for setting up TCB */
if (tx->tcb_setup_cbfn)
(tx->tcb_setup_cbfn)(bna->bnad, txq->tcb);
i++;
}
/* TxF */
tx->txf.ctrl_flags = BFI_TXF_CF_ENABLE | BFI_TXF_CF_VLAN_WI_BASED;
tx->txf.vlan = 0;
/* Mbox element */
bfa_q_qe_init(&tx->mbox_qe.qe);
bfa_fsm_set_state(tx, bna_tx_sm_stopped);
return tx;
err_return:
bna_tx_free(tx);
return NULL;
}
void
bna_tx_destroy(struct bna_tx *tx)
{
/* Callback to bnad for destroying TCB */
if (tx->tcb_destroy_cbfn) {
struct bna_txq *txq;
struct list_head *qe;
list_for_each(qe, &tx->txq_q) {
txq = (struct bna_txq *)qe;
(tx->tcb_destroy_cbfn)(tx->bna->bnad, txq->tcb);
}
}
bna_tx_free(tx);
}
void
bna_tx_enable(struct bna_tx *tx)
{
if (tx->fsm != (bfa_sm_t)bna_tx_sm_stopped)
return;
tx->flags |= BNA_TX_F_ENABLED;
if (tx->flags & BNA_TX_F_PORT_STARTED)
bfa_fsm_send_event(tx, TX_E_START);
}
void
bna_tx_disable(struct bna_tx *tx, enum bna_cleanup_type type,
void (*cbfn)(void *, struct bna_tx *, enum bna_cb_status))
{
if (type == BNA_SOFT_CLEANUP) {
(*cbfn)(tx->bna->bnad, tx, BNA_CB_SUCCESS);
return;
}
tx->stop_cbfn = cbfn;
tx->stop_cbarg = tx->bna->bnad;
tx->flags &= ~BNA_TX_F_ENABLED;
bfa_fsm_send_event(tx, TX_E_STOP);
}
int
bna_tx_state_get(struct bna_tx *tx)
{
return bfa_sm_to_state(tx_sm_table, tx->fsm);
}
void
bna_tx_mod_init(struct bna_tx_mod *tx_mod, struct bna *bna,
struct bna_res_info *res_info)
{
int i;
tx_mod->bna = bna;
tx_mod->flags = 0;
tx_mod->tx = (struct bna_tx *)
res_info[BNA_RES_MEM_T_TX_ARRAY].res_u.mem_info.mdl[0].kva;
tx_mod->txq = (struct bna_txq *)
res_info[BNA_RES_MEM_T_TXQ_ARRAY].res_u.mem_info.mdl[0].kva;
INIT_LIST_HEAD(&tx_mod->tx_free_q);
INIT_LIST_HEAD(&tx_mod->tx_active_q);
INIT_LIST_HEAD(&tx_mod->txq_free_q);
for (i = 0; i < BFI_MAX_TXQ; i++) {
tx_mod->tx[i].txf.txf_id = i;
bfa_q_qe_init(&tx_mod->tx[i].qe);
list_add_tail(&tx_mod->tx[i].qe, &tx_mod->tx_free_q);
tx_mod->txq[i].txq_id = i;
bfa_q_qe_init(&tx_mod->txq[i].qe);
list_add_tail(&tx_mod->txq[i].qe, &tx_mod->txq_free_q);
}
tx_mod->tx_stop_wc.wc_resume = bna_tx_mod_cb_tx_stopped_all;
tx_mod->tx_stop_wc.wc_cbarg = tx_mod;
tx_mod->tx_stop_wc.wc_count = 0;
}
void
bna_tx_mod_uninit(struct bna_tx_mod *tx_mod)
{
struct list_head *qe;
int i;
i = 0;
list_for_each(qe, &tx_mod->tx_free_q)
i++;
i = 0;
list_for_each(qe, &tx_mod->txq_free_q)
i++;
tx_mod->bna = NULL;
}
void
bna_tx_mod_start(struct bna_tx_mod *tx_mod, enum bna_tx_type type)
{
struct bna_tx *tx;
struct list_head *qe;
tx_mod->flags |= BNA_TX_MOD_F_PORT_STARTED;
if (type == BNA_TX_T_LOOPBACK)
tx_mod->flags |= BNA_TX_MOD_F_PORT_LOOPBACK;
list_for_each(qe, &tx_mod->tx_active_q) {
tx = (struct bna_tx *)qe;
if (tx->type == type)
bna_tx_start(tx);
}
}
void
bna_tx_mod_stop(struct bna_tx_mod *tx_mod, enum bna_tx_type type)
{
struct bna_tx *tx;
struct list_head *qe;
tx_mod->flags &= ~BNA_TX_MOD_F_PORT_STARTED;
tx_mod->flags &= ~BNA_TX_MOD_F_PORT_LOOPBACK;
tx_mod->stop_cbfn = bna_port_cb_tx_stopped;
/**
* Before calling bna_tx_stop(), increment tx_stop_wc as many times
* as we are going to call bna_tx_stop
*/
list_for_each(qe, &tx_mod->tx_active_q) {
tx = (struct bna_tx *)qe;
if (tx->type == type)
bfa_wc_up(&tx_mod->tx_stop_wc);
}
if (tx_mod->tx_stop_wc.wc_count == 0) {
tx_mod->stop_cbfn(&tx_mod->bna->port, BNA_CB_SUCCESS);
tx_mod->stop_cbfn = NULL;
return;
}
list_for_each(qe, &tx_mod->tx_active_q) {
tx = (struct bna_tx *)qe;
if (tx->type == type)
bna_tx_stop(tx);
}
}
void
bna_tx_mod_fail(struct bna_tx_mod *tx_mod)
{
struct bna_tx *tx;
struct list_head *qe;
tx_mod->flags &= ~BNA_TX_MOD_F_PORT_STARTED;
tx_mod->flags &= ~BNA_TX_MOD_F_PORT_LOOPBACK;
list_for_each(qe, &tx_mod->tx_active_q) {
tx = (struct bna_tx *)qe;
bna_tx_fail(tx);
}
}
void
bna_tx_mod_prio_changed(struct bna_tx_mod *tx_mod, int prio)
{
struct bna_tx *tx;
struct list_head *qe;
if (prio != tx_mod->priority) {
tx_mod->priority = prio;
list_for_each(qe, &tx_mod->tx_active_q) {
tx = (struct bna_tx *)qe;
bna_tx_prio_changed(tx, prio);
}
}
}
void
bna_tx_mod_cee_link_status(struct bna_tx_mod *tx_mod, int cee_link)
{
struct bna_tx *tx;
struct list_head *qe;
tx_mod->cee_link = cee_link;
list_for_each(qe, &tx_mod->tx_active_q) {
tx = (struct bna_tx *)qe;
bna_tx_cee_link_status(tx, cee_link);
}
}