linux/drivers/scsi/bfa/bfa_core.c

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/*
* Copyright (c) 2005-2010 Brocade Communications Systems, Inc.
* All rights reserved
* www.brocade.com
*
* Linux driver for Brocade Fibre Channel Host Bus 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.
*/
#include "bfa_modules.h"
#include "bfi_ctreg.h"
#include "bfad_drv.h"
BFA_TRC_FILE(HAL, CORE);
/*
* BFA IOC FC related definitions
*/
/*
* IOC local definitions
*/
#define BFA_IOCFC_TOV 5000 /* msecs */
enum {
BFA_IOCFC_ACT_NONE = 0,
BFA_IOCFC_ACT_INIT = 1,
BFA_IOCFC_ACT_STOP = 2,
BFA_IOCFC_ACT_DISABLE = 3,
};
#define DEF_CFG_NUM_FABRICS 1
#define DEF_CFG_NUM_LPORTS 256
#define DEF_CFG_NUM_CQS 4
#define DEF_CFG_NUM_IOIM_REQS (BFA_IOIM_MAX)
#define DEF_CFG_NUM_TSKIM_REQS 128
#define DEF_CFG_NUM_FCXP_REQS 64
#define DEF_CFG_NUM_UF_BUFS 64
#define DEF_CFG_NUM_RPORTS 1024
#define DEF_CFG_NUM_ITNIMS (DEF_CFG_NUM_RPORTS)
#define DEF_CFG_NUM_TINS 256
#define DEF_CFG_NUM_SGPGS 2048
#define DEF_CFG_NUM_REQQ_ELEMS 256
#define DEF_CFG_NUM_RSPQ_ELEMS 64
#define DEF_CFG_NUM_SBOOT_TGTS 16
#define DEF_CFG_NUM_SBOOT_LUNS 16
/*
* forward declaration for IOC FC functions
*/
static void bfa_iocfc_enable_cbfn(void *bfa_arg, enum bfa_status status);
static void bfa_iocfc_disable_cbfn(void *bfa_arg);
static void bfa_iocfc_hbfail_cbfn(void *bfa_arg);
static void bfa_iocfc_reset_cbfn(void *bfa_arg);
static struct bfa_ioc_cbfn_s bfa_iocfc_cbfn;
/*
* BFA Interrupt handling functions
*/
static void
bfa_msix_errint(struct bfa_s *bfa, u32 intr)
{
bfa_ioc_error_isr(&bfa->ioc);
}
static void
bfa_msix_lpu(struct bfa_s *bfa)
{
bfa_ioc_mbox_isr(&bfa->ioc);
}
static void
bfa_reqq_resume(struct bfa_s *bfa, int qid)
{
struct list_head *waitq, *qe, *qen;
struct bfa_reqq_wait_s *wqe;
waitq = bfa_reqq(bfa, qid);
list_for_each_safe(qe, qen, waitq) {
/*
* Callback only as long as there is room in request queue
*/
if (bfa_reqq_full(bfa, qid))
break;
list_del(qe);
wqe = (struct bfa_reqq_wait_s *) qe;
wqe->qresume(wqe->cbarg);
}
}
void
bfa_msix_all(struct bfa_s *bfa, int vec)
{
bfa_intx(bfa);
}
bfa_boolean_t
bfa_intx(struct bfa_s *bfa)
{
u32 intr, qintr;
int queue;
intr = readl(bfa->iocfc.bfa_regs.intr_status);
if (!intr)
return BFA_FALSE;
/*
* RME completion queue interrupt
*/
qintr = intr & __HFN_INT_RME_MASK;
writel(qintr, bfa->iocfc.bfa_regs.intr_status);
for (queue = 0; queue < BFI_IOC_MAX_CQS_ASIC; queue++) {
if (intr & (__HFN_INT_RME_Q0 << queue))
bfa_msix_rspq(bfa, queue & (BFI_IOC_MAX_CQS - 1));
}
intr &= ~qintr;
if (!intr)
return BFA_TRUE;
/*
* CPE completion queue interrupt
*/
qintr = intr & __HFN_INT_CPE_MASK;
writel(qintr, bfa->iocfc.bfa_regs.intr_status);
for (queue = 0; queue < BFI_IOC_MAX_CQS_ASIC; queue++) {
if (intr & (__HFN_INT_CPE_Q0 << queue))
bfa_msix_reqq(bfa, queue & (BFI_IOC_MAX_CQS - 1));
}
intr &= ~qintr;
if (!intr)
return BFA_TRUE;
bfa_msix_lpu_err(bfa, intr);
return BFA_TRUE;
}
void
bfa_isr_enable(struct bfa_s *bfa)
{
u32 intr_unmask;
int pci_func = bfa_ioc_pcifn(&bfa->ioc);
bfa_trc(bfa, pci_func);
bfa_msix_install(bfa);
intr_unmask = (__HFN_INT_ERR_EMC | __HFN_INT_ERR_LPU0 |
__HFN_INT_ERR_LPU1 | __HFN_INT_ERR_PSS |
__HFN_INT_LL_HALT);
if (pci_func == 0)
intr_unmask |= (__HFN_INT_CPE_Q0 | __HFN_INT_CPE_Q1 |
__HFN_INT_CPE_Q2 | __HFN_INT_CPE_Q3 |
__HFN_INT_RME_Q0 | __HFN_INT_RME_Q1 |
__HFN_INT_RME_Q2 | __HFN_INT_RME_Q3 |
__HFN_INT_MBOX_LPU0);
else
intr_unmask |= (__HFN_INT_CPE_Q4 | __HFN_INT_CPE_Q5 |
__HFN_INT_CPE_Q6 | __HFN_INT_CPE_Q7 |
__HFN_INT_RME_Q4 | __HFN_INT_RME_Q5 |
__HFN_INT_RME_Q6 | __HFN_INT_RME_Q7 |
__HFN_INT_MBOX_LPU1);
writel(intr_unmask, bfa->iocfc.bfa_regs.intr_status);
writel(~intr_unmask, bfa->iocfc.bfa_regs.intr_mask);
bfa->iocfc.intr_mask = ~intr_unmask;
bfa_isr_mode_set(bfa, bfa->msix.nvecs != 0);
}
void
bfa_isr_disable(struct bfa_s *bfa)
{
bfa_isr_mode_set(bfa, BFA_FALSE);
writel(-1L, bfa->iocfc.bfa_regs.intr_mask);
bfa_msix_uninstall(bfa);
}
void
bfa_msix_reqq(struct bfa_s *bfa, int qid)
{
struct list_head *waitq;
qid &= (BFI_IOC_MAX_CQS - 1);
bfa->iocfc.hwif.hw_reqq_ack(bfa, qid);
/*
* Resume any pending requests in the corresponding reqq.
*/
waitq = bfa_reqq(bfa, qid);
if (!list_empty(waitq))
bfa_reqq_resume(bfa, qid);
}
void
bfa_isr_unhandled(struct bfa_s *bfa, struct bfi_msg_s *m)
{
bfa_trc(bfa, m->mhdr.msg_class);
bfa_trc(bfa, m->mhdr.msg_id);
bfa_trc(bfa, m->mhdr.mtag.i2htok);
bfa_assert(0);
bfa_trc_stop(bfa->trcmod);
}
void
bfa_msix_rspq(struct bfa_s *bfa, int qid)
{
struct bfi_msg_s *m;
u32 pi, ci;
struct list_head *waitq;
bfa_trc_fp(bfa, qid);
qid &= (BFI_IOC_MAX_CQS - 1);
bfa->iocfc.hwif.hw_rspq_ack(bfa, qid);
ci = bfa_rspq_ci(bfa, qid);
pi = bfa_rspq_pi(bfa, qid);
bfa_trc_fp(bfa, ci);
bfa_trc_fp(bfa, pi);
if (bfa->rme_process) {
while (ci != pi) {
m = bfa_rspq_elem(bfa, qid, ci);
bfa_assert_fp(m->mhdr.msg_class < BFI_MC_MAX);
bfa_isrs[m->mhdr.msg_class] (bfa, m);
CQ_INCR(ci, bfa->iocfc.cfg.drvcfg.num_rspq_elems);
}
}
/*
* update CI
*/
bfa_rspq_ci(bfa, qid) = pi;
writel(pi, bfa->iocfc.bfa_regs.rme_q_ci[qid]);
mmiowb();
/*
* Resume any pending requests in the corresponding reqq.
*/
waitq = bfa_reqq(bfa, qid);
if (!list_empty(waitq))
bfa_reqq_resume(bfa, qid);
}
void
bfa_msix_lpu_err(struct bfa_s *bfa, int vec)
{
u32 intr, curr_value;
intr = readl(bfa->iocfc.bfa_regs.intr_status);
if (intr & (__HFN_INT_MBOX_LPU0 | __HFN_INT_MBOX_LPU1))
bfa_msix_lpu(bfa);
intr &= (__HFN_INT_ERR_EMC | __HFN_INT_ERR_LPU0 |
__HFN_INT_ERR_LPU1 | __HFN_INT_ERR_PSS | __HFN_INT_LL_HALT);
if (intr) {
if (intr & __HFN_INT_LL_HALT) {
/*
* If LL_HALT bit is set then FW Init Halt LL Port
* Register needs to be cleared as well so Interrupt
* Status Register will be cleared.
*/
curr_value = readl(bfa->ioc.ioc_regs.ll_halt);
curr_value &= ~__FW_INIT_HALT_P;
writel(curr_value, bfa->ioc.ioc_regs.ll_halt);
}
if (intr & __HFN_INT_ERR_PSS) {
/*
* ERR_PSS bit needs to be cleared as well in case
* interrups are shared so driver's interrupt handler is
* still called eventhough it is already masked out.
*/
curr_value = readl(
bfa->ioc.ioc_regs.pss_err_status_reg);
curr_value &= __PSS_ERR_STATUS_SET;
writel(curr_value,
bfa->ioc.ioc_regs.pss_err_status_reg);
}
writel(intr, bfa->iocfc.bfa_regs.intr_status);
bfa_msix_errint(bfa, intr);
}
}
/*
* BFA IOC FC related functions
*/
/*
* BFA IOC private functions
*/
static void
bfa_iocfc_cqs_sz(struct bfa_iocfc_cfg_s *cfg, u32 *dm_len)
{
int i, per_reqq_sz, per_rspq_sz;
per_reqq_sz = BFA_ROUNDUP((cfg->drvcfg.num_reqq_elems * BFI_LMSG_SZ),
BFA_DMA_ALIGN_SZ);
per_rspq_sz = BFA_ROUNDUP((cfg->drvcfg.num_rspq_elems * BFI_LMSG_SZ),
BFA_DMA_ALIGN_SZ);
/*
* Calculate CQ size
*/
for (i = 0; i < cfg->fwcfg.num_cqs; i++) {
*dm_len = *dm_len + per_reqq_sz;
*dm_len = *dm_len + per_rspq_sz;
}
/*
* Calculate Shadow CI/PI size
*/
for (i = 0; i < cfg->fwcfg.num_cqs; i++)
*dm_len += (2 * BFA_CACHELINE_SZ);
}
static void
bfa_iocfc_fw_cfg_sz(struct bfa_iocfc_cfg_s *cfg, u32 *dm_len)
{
*dm_len +=
BFA_ROUNDUP(sizeof(struct bfi_iocfc_cfg_s), BFA_CACHELINE_SZ);
*dm_len +=
BFA_ROUNDUP(sizeof(struct bfi_iocfc_cfgrsp_s),
BFA_CACHELINE_SZ);
}
/*
* Use the Mailbox interface to send BFI_IOCFC_H2I_CFG_REQ
*/
static void
bfa_iocfc_send_cfg(void *bfa_arg)
{
struct bfa_s *bfa = bfa_arg;
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
struct bfi_iocfc_cfg_req_s cfg_req;
struct bfi_iocfc_cfg_s *cfg_info = iocfc->cfginfo;
struct bfa_iocfc_cfg_s *cfg = &iocfc->cfg;
int i;
bfa_assert(cfg->fwcfg.num_cqs <= BFI_IOC_MAX_CQS);
bfa_trc(bfa, cfg->fwcfg.num_cqs);
bfa_iocfc_reset_queues(bfa);
/*
* initialize IOC configuration info
*/
cfg_info->endian_sig = BFI_IOC_ENDIAN_SIG;
cfg_info->num_cqs = cfg->fwcfg.num_cqs;
bfa_dma_be_addr_set(cfg_info->cfgrsp_addr, iocfc->cfgrsp_dma.pa);
/*
* dma map REQ and RSP circular queues and shadow pointers
*/
for (i = 0; i < cfg->fwcfg.num_cqs; i++) {
bfa_dma_be_addr_set(cfg_info->req_cq_ba[i],
iocfc->req_cq_ba[i].pa);
bfa_dma_be_addr_set(cfg_info->req_shadow_ci[i],
iocfc->req_cq_shadow_ci[i].pa);
cfg_info->req_cq_elems[i] =
cpu_to_be16(cfg->drvcfg.num_reqq_elems);
bfa_dma_be_addr_set(cfg_info->rsp_cq_ba[i],
iocfc->rsp_cq_ba[i].pa);
bfa_dma_be_addr_set(cfg_info->rsp_shadow_pi[i],
iocfc->rsp_cq_shadow_pi[i].pa);
cfg_info->rsp_cq_elems[i] =
cpu_to_be16(cfg->drvcfg.num_rspq_elems);
}
/*
* Enable interrupt coalescing if it is driver init path
* and not ioc disable/enable path.
*/
if (!iocfc->cfgdone)
cfg_info->intr_attr.coalesce = BFA_TRUE;
iocfc->cfgdone = BFA_FALSE;
/*
* dma map IOC configuration itself
*/
bfi_h2i_set(cfg_req.mh, BFI_MC_IOCFC, BFI_IOCFC_H2I_CFG_REQ,
bfa_lpuid(bfa));
bfa_dma_be_addr_set(cfg_req.ioc_cfg_dma_addr, iocfc->cfg_info.pa);
bfa_ioc_mbox_send(&bfa->ioc, &cfg_req,
sizeof(struct bfi_iocfc_cfg_req_s));
}
static void
bfa_iocfc_init_mem(struct bfa_s *bfa, void *bfad, struct bfa_iocfc_cfg_s *cfg,
struct bfa_pcidev_s *pcidev)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
bfa->bfad = bfad;
iocfc->bfa = bfa;
iocfc->action = BFA_IOCFC_ACT_NONE;
iocfc->cfg = *cfg;
/*
* Initialize chip specific handlers.
*/
if (bfa_asic_id_ct(bfa_ioc_devid(&bfa->ioc))) {
iocfc->hwif.hw_reginit = bfa_hwct_reginit;
iocfc->hwif.hw_reqq_ack = bfa_hwct_reqq_ack;
iocfc->hwif.hw_rspq_ack = bfa_hwct_rspq_ack;
iocfc->hwif.hw_msix_init = bfa_hwct_msix_init;
iocfc->hwif.hw_msix_install = bfa_hwct_msix_install;
iocfc->hwif.hw_msix_uninstall = bfa_hwct_msix_uninstall;
iocfc->hwif.hw_isr_mode_set = bfa_hwct_isr_mode_set;
iocfc->hwif.hw_msix_getvecs = bfa_hwct_msix_getvecs;
iocfc->hwif.hw_msix_get_rme_range = bfa_hwct_msix_get_rme_range;
} else {
iocfc->hwif.hw_reginit = bfa_hwcb_reginit;
iocfc->hwif.hw_reqq_ack = bfa_hwcb_reqq_ack;
iocfc->hwif.hw_rspq_ack = bfa_hwcb_rspq_ack;
iocfc->hwif.hw_msix_init = bfa_hwcb_msix_init;
iocfc->hwif.hw_msix_install = bfa_hwcb_msix_install;
iocfc->hwif.hw_msix_uninstall = bfa_hwcb_msix_uninstall;
iocfc->hwif.hw_isr_mode_set = bfa_hwcb_isr_mode_set;
iocfc->hwif.hw_msix_getvecs = bfa_hwcb_msix_getvecs;
iocfc->hwif.hw_msix_get_rme_range = bfa_hwcb_msix_get_rme_range;
}
iocfc->hwif.hw_reginit(bfa);
bfa->msix.nvecs = 0;
}
static void
bfa_iocfc_mem_claim(struct bfa_s *bfa, struct bfa_iocfc_cfg_s *cfg,
struct bfa_meminfo_s *meminfo)
{
u8 *dm_kva;
u64 dm_pa;
int i, per_reqq_sz, per_rspq_sz;
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
int dbgsz;
dm_kva = bfa_meminfo_dma_virt(meminfo);
dm_pa = bfa_meminfo_dma_phys(meminfo);
/*
* First allocate dma memory for IOC.
*/
bfa_ioc_mem_claim(&bfa->ioc, dm_kva, dm_pa);
dm_kva += bfa_ioc_meminfo();
dm_pa += bfa_ioc_meminfo();
/*
* Claim DMA-able memory for the request/response queues and for shadow
* ci/pi registers
*/
per_reqq_sz = BFA_ROUNDUP((cfg->drvcfg.num_reqq_elems * BFI_LMSG_SZ),
BFA_DMA_ALIGN_SZ);
per_rspq_sz = BFA_ROUNDUP((cfg->drvcfg.num_rspq_elems * BFI_LMSG_SZ),
BFA_DMA_ALIGN_SZ);
for (i = 0; i < cfg->fwcfg.num_cqs; i++) {
iocfc->req_cq_ba[i].kva = dm_kva;
iocfc->req_cq_ba[i].pa = dm_pa;
memset(dm_kva, 0, per_reqq_sz);
dm_kva += per_reqq_sz;
dm_pa += per_reqq_sz;
iocfc->rsp_cq_ba[i].kva = dm_kva;
iocfc->rsp_cq_ba[i].pa = dm_pa;
memset(dm_kva, 0, per_rspq_sz);
dm_kva += per_rspq_sz;
dm_pa += per_rspq_sz;
}
for (i = 0; i < cfg->fwcfg.num_cqs; i++) {
iocfc->req_cq_shadow_ci[i].kva = dm_kva;
iocfc->req_cq_shadow_ci[i].pa = dm_pa;
dm_kva += BFA_CACHELINE_SZ;
dm_pa += BFA_CACHELINE_SZ;
iocfc->rsp_cq_shadow_pi[i].kva = dm_kva;
iocfc->rsp_cq_shadow_pi[i].pa = dm_pa;
dm_kva += BFA_CACHELINE_SZ;
dm_pa += BFA_CACHELINE_SZ;
}
/*
* Claim DMA-able memory for the config info page
*/
bfa->iocfc.cfg_info.kva = dm_kva;
bfa->iocfc.cfg_info.pa = dm_pa;
bfa->iocfc.cfginfo = (struct bfi_iocfc_cfg_s *) dm_kva;
dm_kva += BFA_ROUNDUP(sizeof(struct bfi_iocfc_cfg_s), BFA_CACHELINE_SZ);
dm_pa += BFA_ROUNDUP(sizeof(struct bfi_iocfc_cfg_s), BFA_CACHELINE_SZ);
/*
* Claim DMA-able memory for the config response
*/
bfa->iocfc.cfgrsp_dma.kva = dm_kva;
bfa->iocfc.cfgrsp_dma.pa = dm_pa;
bfa->iocfc.cfgrsp = (struct bfi_iocfc_cfgrsp_s *) dm_kva;
dm_kva +=
BFA_ROUNDUP(sizeof(struct bfi_iocfc_cfgrsp_s),
BFA_CACHELINE_SZ);
dm_pa += BFA_ROUNDUP(sizeof(struct bfi_iocfc_cfgrsp_s),
BFA_CACHELINE_SZ);
bfa_meminfo_dma_virt(meminfo) = dm_kva;
bfa_meminfo_dma_phys(meminfo) = dm_pa;
dbgsz = bfa_ioc_debug_trcsz(bfa_auto_recover);
if (dbgsz > 0) {
bfa_ioc_debug_memclaim(&bfa->ioc, bfa_meminfo_kva(meminfo));
bfa_meminfo_kva(meminfo) += dbgsz;
}
}
/*
* Start BFA submodules.
*/
static void
bfa_iocfc_start_submod(struct bfa_s *bfa)
{
int i;
bfa->rme_process = BFA_TRUE;
for (i = 0; hal_mods[i]; i++)
hal_mods[i]->start(bfa);
}
/*
* Disable BFA submodules.
*/
static void
bfa_iocfc_disable_submod(struct bfa_s *bfa)
{
int i;
for (i = 0; hal_mods[i]; i++)
hal_mods[i]->iocdisable(bfa);
}
static void
bfa_iocfc_init_cb(void *bfa_arg, bfa_boolean_t complete)
{
struct bfa_s *bfa = bfa_arg;
if (complete) {
if (bfa->iocfc.cfgdone)
bfa_cb_init(bfa->bfad, BFA_STATUS_OK);
else
bfa_cb_init(bfa->bfad, BFA_STATUS_FAILED);
} else {
if (bfa->iocfc.cfgdone)
bfa->iocfc.action = BFA_IOCFC_ACT_NONE;
}
}
static void
bfa_iocfc_stop_cb(void *bfa_arg, bfa_boolean_t compl)
{
struct bfa_s *bfa = bfa_arg;
struct bfad_s *bfad = bfa->bfad;
if (compl)
complete(&bfad->comp);
else
bfa->iocfc.action = BFA_IOCFC_ACT_NONE;
}
static void
bfa_iocfc_disable_cb(void *bfa_arg, bfa_boolean_t compl)
{
struct bfa_s *bfa = bfa_arg;
struct bfad_s *bfad = bfa->bfad;
if (compl)
complete(&bfad->disable_comp);
}
/*
* Update BFA configuration from firmware configuration.
*/
static void
bfa_iocfc_cfgrsp(struct bfa_s *bfa)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
struct bfi_iocfc_cfgrsp_s *cfgrsp = iocfc->cfgrsp;
struct bfa_iocfc_fwcfg_s *fwcfg = &cfgrsp->fwcfg;
fwcfg->num_cqs = fwcfg->num_cqs;
fwcfg->num_ioim_reqs = be16_to_cpu(fwcfg->num_ioim_reqs);
fwcfg->num_tskim_reqs = be16_to_cpu(fwcfg->num_tskim_reqs);
fwcfg->num_fcxp_reqs = be16_to_cpu(fwcfg->num_fcxp_reqs);
fwcfg->num_uf_bufs = be16_to_cpu(fwcfg->num_uf_bufs);
fwcfg->num_rports = be16_to_cpu(fwcfg->num_rports);
iocfc->cfgdone = BFA_TRUE;
/*
* Configuration is complete - initialize/start submodules
*/
bfa_fcport_init(bfa);
if (iocfc->action == BFA_IOCFC_ACT_INIT)
bfa_cb_queue(bfa, &iocfc->init_hcb_qe, bfa_iocfc_init_cb, bfa);
else
bfa_iocfc_start_submod(bfa);
}
void
bfa_iocfc_reset_queues(struct bfa_s *bfa)
{
int q;
for (q = 0; q < BFI_IOC_MAX_CQS; q++) {
bfa_reqq_ci(bfa, q) = 0;
bfa_reqq_pi(bfa, q) = 0;
bfa_rspq_ci(bfa, q) = 0;
bfa_rspq_pi(bfa, q) = 0;
}
}
/*
* IOC enable request is complete
*/
static void
bfa_iocfc_enable_cbfn(void *bfa_arg, enum bfa_status status)
{
struct bfa_s *bfa = bfa_arg;
if (status != BFA_STATUS_OK) {
bfa_isr_disable(bfa);
if (bfa->iocfc.action == BFA_IOCFC_ACT_INIT)
bfa_cb_queue(bfa, &bfa->iocfc.init_hcb_qe,
bfa_iocfc_init_cb, bfa);
return;
}
bfa_iocfc_send_cfg(bfa);
}
/*
* IOC disable request is complete
*/
static void
bfa_iocfc_disable_cbfn(void *bfa_arg)
{
struct bfa_s *bfa = bfa_arg;
bfa_isr_disable(bfa);
bfa_iocfc_disable_submod(bfa);
if (bfa->iocfc.action == BFA_IOCFC_ACT_STOP)
bfa_cb_queue(bfa, &bfa->iocfc.stop_hcb_qe, bfa_iocfc_stop_cb,
bfa);
else {
bfa_assert(bfa->iocfc.action == BFA_IOCFC_ACT_DISABLE);
bfa_cb_queue(bfa, &bfa->iocfc.dis_hcb_qe, bfa_iocfc_disable_cb,
bfa);
}
}
/*
* Notify sub-modules of hardware failure.
*/
static void
bfa_iocfc_hbfail_cbfn(void *bfa_arg)
{
struct bfa_s *bfa = bfa_arg;
bfa->rme_process = BFA_FALSE;
bfa_isr_disable(bfa);
bfa_iocfc_disable_submod(bfa);
if (bfa->iocfc.action == BFA_IOCFC_ACT_INIT)
bfa_cb_queue(bfa, &bfa->iocfc.init_hcb_qe, bfa_iocfc_init_cb,
bfa);
}
/*
* Actions on chip-reset completion.
*/
static void
bfa_iocfc_reset_cbfn(void *bfa_arg)
{
struct bfa_s *bfa = bfa_arg;
bfa_iocfc_reset_queues(bfa);
bfa_isr_enable(bfa);
}
/*
* Query IOC memory requirement information.
*/
void
bfa_iocfc_meminfo(struct bfa_iocfc_cfg_s *cfg, u32 *km_len,
u32 *dm_len)
{
/* dma memory for IOC */
*dm_len += bfa_ioc_meminfo();
bfa_iocfc_fw_cfg_sz(cfg, dm_len);
bfa_iocfc_cqs_sz(cfg, dm_len);
*km_len += bfa_ioc_debug_trcsz(bfa_auto_recover);
}
/*
* Query IOC memory requirement information.
*/
void
bfa_iocfc_attach(struct bfa_s *bfa, void *bfad, struct bfa_iocfc_cfg_s *cfg,
struct bfa_meminfo_s *meminfo, struct bfa_pcidev_s *pcidev)
{
int i;
struct bfa_ioc_s *ioc = &bfa->ioc;
bfa_iocfc_cbfn.enable_cbfn = bfa_iocfc_enable_cbfn;
bfa_iocfc_cbfn.disable_cbfn = bfa_iocfc_disable_cbfn;
bfa_iocfc_cbfn.hbfail_cbfn = bfa_iocfc_hbfail_cbfn;
bfa_iocfc_cbfn.reset_cbfn = bfa_iocfc_reset_cbfn;
ioc->trcmod = bfa->trcmod;
bfa_ioc_attach(&bfa->ioc, bfa, &bfa_iocfc_cbfn, &bfa->timer_mod);
/*
* Set FC mode for BFA_PCI_DEVICE_ID_CT_FC.
*/
if (pcidev->device_id == BFA_PCI_DEVICE_ID_CT_FC)
bfa_ioc_set_fcmode(&bfa->ioc);
bfa_ioc_pci_init(&bfa->ioc, pcidev, BFI_MC_IOCFC);
bfa_ioc_mbox_register(&bfa->ioc, bfa_mbox_isrs);
bfa_iocfc_init_mem(bfa, bfad, cfg, pcidev);
bfa_iocfc_mem_claim(bfa, cfg, meminfo);
bfa_timer_init(&bfa->timer_mod);
INIT_LIST_HEAD(&bfa->comp_q);
for (i = 0; i < BFI_IOC_MAX_CQS; i++)
INIT_LIST_HEAD(&bfa->reqq_waitq[i]);
}
/*
* Query IOC memory requirement information.
*/
void
bfa_iocfc_detach(struct bfa_s *bfa)
{
bfa_ioc_detach(&bfa->ioc);
}
/*
* Query IOC memory requirement information.
*/
void
bfa_iocfc_init(struct bfa_s *bfa)
{
bfa->iocfc.action = BFA_IOCFC_ACT_INIT;
bfa_ioc_enable(&bfa->ioc);
}
/*
* IOC start called from bfa_start(). Called to start IOC operations
* at driver instantiation for this instance.
*/
void
bfa_iocfc_start(struct bfa_s *bfa)
{
if (bfa->iocfc.cfgdone)
bfa_iocfc_start_submod(bfa);
}
/*
* IOC stop called from bfa_stop(). Called only when driver is unloaded
* for this instance.
*/
void
bfa_iocfc_stop(struct bfa_s *bfa)
{
bfa->iocfc.action = BFA_IOCFC_ACT_STOP;
bfa->rme_process = BFA_FALSE;
bfa_ioc_disable(&bfa->ioc);
}
void
bfa_iocfc_isr(void *bfaarg, struct bfi_mbmsg_s *m)
{
struct bfa_s *bfa = bfaarg;
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
union bfi_iocfc_i2h_msg_u *msg;
msg = (union bfi_iocfc_i2h_msg_u *) m;
bfa_trc(bfa, msg->mh.msg_id);
switch (msg->mh.msg_id) {
case BFI_IOCFC_I2H_CFG_REPLY:
iocfc->cfg_reply = &msg->cfg_reply;
bfa_iocfc_cfgrsp(bfa);
break;
case BFI_IOCFC_I2H_UPDATEQ_RSP:
iocfc->updateq_cbfn(iocfc->updateq_cbarg, BFA_STATUS_OK);
break;
default:
bfa_assert(0);
}
}
void
bfa_iocfc_get_attr(struct bfa_s *bfa, struct bfa_iocfc_attr_s *attr)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
attr->intr_attr.coalesce = iocfc->cfginfo->intr_attr.coalesce;
attr->intr_attr.delay = iocfc->cfginfo->intr_attr.delay ?
be16_to_cpu(iocfc->cfginfo->intr_attr.delay) :
be16_to_cpu(iocfc->cfgrsp->intr_attr.delay);
attr->intr_attr.latency = iocfc->cfginfo->intr_attr.latency ?
be16_to_cpu(iocfc->cfginfo->intr_attr.latency) :
be16_to_cpu(iocfc->cfgrsp->intr_attr.latency);
attr->config = iocfc->cfg;
}
bfa_status_t
bfa_iocfc_israttr_set(struct bfa_s *bfa, struct bfa_iocfc_intr_attr_s *attr)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
struct bfi_iocfc_set_intr_req_s *m;
iocfc->cfginfo->intr_attr.coalesce = attr->coalesce;
iocfc->cfginfo->intr_attr.delay = cpu_to_be16(attr->delay);
iocfc->cfginfo->intr_attr.latency = cpu_to_be16(attr->latency);
if (!bfa_iocfc_is_operational(bfa))
return BFA_STATUS_OK;
m = bfa_reqq_next(bfa, BFA_REQQ_IOC);
if (!m)
return BFA_STATUS_DEVBUSY;
bfi_h2i_set(m->mh, BFI_MC_IOCFC, BFI_IOCFC_H2I_SET_INTR_REQ,
bfa_lpuid(bfa));
m->coalesce = iocfc->cfginfo->intr_attr.coalesce;
m->delay = iocfc->cfginfo->intr_attr.delay;
m->latency = iocfc->cfginfo->intr_attr.latency;
bfa_trc(bfa, attr->delay);
bfa_trc(bfa, attr->latency);
bfa_reqq_produce(bfa, BFA_REQQ_IOC);
return BFA_STATUS_OK;
}
void
bfa_iocfc_set_snsbase(struct bfa_s *bfa, u64 snsbase_pa)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
iocfc->cfginfo->sense_buf_len = (BFI_IOIM_SNSLEN - 1);
bfa_dma_be_addr_set(iocfc->cfginfo->ioim_snsbase, snsbase_pa);
}
/*
* Enable IOC after it is disabled.
*/
void
bfa_iocfc_enable(struct bfa_s *bfa)
{
bfa_plog_str(bfa->plog, BFA_PL_MID_HAL, BFA_PL_EID_MISC, 0,
"IOC Enable");
bfa_ioc_enable(&bfa->ioc);
}
void
bfa_iocfc_disable(struct bfa_s *bfa)
{
bfa_plog_str(bfa->plog, BFA_PL_MID_HAL, BFA_PL_EID_MISC, 0,
"IOC Disable");
bfa->iocfc.action = BFA_IOCFC_ACT_DISABLE;
bfa->rme_process = BFA_FALSE;
bfa_ioc_disable(&bfa->ioc);
}
bfa_boolean_t
bfa_iocfc_is_operational(struct bfa_s *bfa)
{
return bfa_ioc_is_operational(&bfa->ioc) && bfa->iocfc.cfgdone;
}
/*
* Return boot target port wwns -- read from boot information in flash.
*/
void
bfa_iocfc_get_bootwwns(struct bfa_s *bfa, u8 *nwwns, wwn_t *wwns)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
struct bfi_iocfc_cfgrsp_s *cfgrsp = iocfc->cfgrsp;
int i;
if (cfgrsp->pbc_cfg.boot_enabled && cfgrsp->pbc_cfg.nbluns) {
bfa_trc(bfa, cfgrsp->pbc_cfg.nbluns);
*nwwns = cfgrsp->pbc_cfg.nbluns;
for (i = 0; i < cfgrsp->pbc_cfg.nbluns; i++)
wwns[i] = cfgrsp->pbc_cfg.blun[i].tgt_pwwn;
return;
}
*nwwns = cfgrsp->bootwwns.nwwns;
memcpy(wwns, cfgrsp->bootwwns.wwn, sizeof(cfgrsp->bootwwns.wwn));
}
void
bfa_iocfc_get_pbc_boot_cfg(struct bfa_s *bfa, struct bfa_boot_pbc_s *pbcfg)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
struct bfi_iocfc_cfgrsp_s *cfgrsp = iocfc->cfgrsp;
pbcfg->enable = cfgrsp->pbc_cfg.boot_enabled;
pbcfg->nbluns = cfgrsp->pbc_cfg.nbluns;
pbcfg->speed = cfgrsp->pbc_cfg.port_speed;
memcpy(pbcfg->pblun, cfgrsp->pbc_cfg.blun, sizeof(pbcfg->pblun));
}
int
bfa_iocfc_get_pbc_vports(struct bfa_s *bfa, struct bfi_pbc_vport_s *pbc_vport)
{
struct bfa_iocfc_s *iocfc = &bfa->iocfc;
struct bfi_iocfc_cfgrsp_s *cfgrsp = iocfc->cfgrsp;
memcpy(pbc_vport, cfgrsp->pbc_cfg.vport, sizeof(cfgrsp->pbc_cfg.vport));
return cfgrsp->pbc_cfg.nvports;
}
/*
* Use this function query the memory requirement of the BFA library.
* This function needs to be called before bfa_attach() to get the
* memory required of the BFA layer for a given driver configuration.
*
* This call will fail, if the cap is out of range compared to pre-defined
* values within the BFA library
*
* @param[in] cfg - pointer to bfa_ioc_cfg_t. Driver layer should indicate
* its configuration in this structure.
* The default values for struct bfa_iocfc_cfg_s can be
* fetched using bfa_cfg_get_default() API.
*
* If cap's boundary check fails, the library will use
* the default bfa_cap_t values (and log a warning msg).
*
* @param[out] meminfo - pointer to bfa_meminfo_t. This content
* indicates the memory type (see bfa_mem_type_t) and
* amount of memory required.
*
* Driver should allocate the memory, populate the
* starting address for each block and provide the same
* structure as input parameter to bfa_attach() call.
*
* @return void
*
* Special Considerations: @note
*/
void
bfa_cfg_get_meminfo(struct bfa_iocfc_cfg_s *cfg, struct bfa_meminfo_s *meminfo)
{
int i;
u32 km_len = 0, dm_len = 0;
bfa_assert((cfg != NULL) && (meminfo != NULL));
memset((void *)meminfo, 0, sizeof(struct bfa_meminfo_s));
meminfo->meminfo[BFA_MEM_TYPE_KVA - 1].mem_type =
BFA_MEM_TYPE_KVA;
meminfo->meminfo[BFA_MEM_TYPE_DMA - 1].mem_type =
BFA_MEM_TYPE_DMA;
bfa_iocfc_meminfo(cfg, &km_len, &dm_len);
for (i = 0; hal_mods[i]; i++)
hal_mods[i]->meminfo(cfg, &km_len, &dm_len);
dm_len += bfa_port_meminfo();
meminfo->meminfo[BFA_MEM_TYPE_KVA - 1].mem_len = km_len;
meminfo->meminfo[BFA_MEM_TYPE_DMA - 1].mem_len = dm_len;
}
/*
* Use this function to do attach the driver instance with the BFA
* library. This function will not trigger any HW initialization
* process (which will be done in bfa_init() call)
*
* This call will fail, if the cap is out of range compared to
* pre-defined values within the BFA library
*
* @param[out] bfa Pointer to bfa_t.
* @param[in] bfad Opaque handle back to the driver's IOC structure
* @param[in] cfg Pointer to bfa_ioc_cfg_t. Should be same structure
* that was used in bfa_cfg_get_meminfo().
* @param[in] meminfo Pointer to bfa_meminfo_t. The driver should
* use the bfa_cfg_get_meminfo() call to
* find the memory blocks required, allocate the
* required memory and provide the starting addresses.
* @param[in] pcidev pointer to struct bfa_pcidev_s
*
* @return
* void
*
* Special Considerations:
*
* @note
*
*/
void
bfa_attach(struct bfa_s *bfa, void *bfad, struct bfa_iocfc_cfg_s *cfg,
struct bfa_meminfo_s *meminfo, struct bfa_pcidev_s *pcidev)
{
int i;
struct bfa_mem_elem_s *melem;
bfa->fcs = BFA_FALSE;
bfa_assert((cfg != NULL) && (meminfo != NULL));
/*
* initialize all memory pointers for iterative allocation
*/
for (i = 0; i < BFA_MEM_TYPE_MAX; i++) {
melem = meminfo->meminfo + i;
melem->kva_curp = melem->kva;
melem->dma_curp = melem->dma;
}
bfa_iocfc_attach(bfa, bfad, cfg, meminfo, pcidev);
for (i = 0; hal_mods[i]; i++)
hal_mods[i]->attach(bfa, bfad, cfg, meminfo, pcidev);
bfa_com_port_attach(bfa, meminfo);
}
/*
* Use this function to delete a BFA IOC. IOC should be stopped (by
* calling bfa_stop()) before this function call.
*
* @param[in] bfa - pointer to bfa_t.
*
* @return
* void
*
* Special Considerations:
*
* @note
*/
void
bfa_detach(struct bfa_s *bfa)
{
int i;
for (i = 0; hal_mods[i]; i++)
hal_mods[i]->detach(bfa);
bfa_iocfc_detach(bfa);
}
void
bfa_init_trc(struct bfa_s *bfa, struct bfa_trc_mod_s *trcmod)
{
bfa->trcmod = trcmod;
}
void
bfa_init_plog(struct bfa_s *bfa, struct bfa_plog_s *plog)
{
bfa->plog = plog;
}
/*
* Initialize IOC.
*
* This function will return immediately, when the IOC initialization is
* completed, the bfa_cb_init() will be called.
*
* @param[in] bfa instance
*
* @return void
*
* Special Considerations:
*
* @note
* When this function returns, the driver should register the interrupt service
* routine(s) and enable the device interrupts. If this is not done,
* bfa_cb_init() will never get called
*/
void
bfa_init(struct bfa_s *bfa)
{
bfa_iocfc_init(bfa);
}
/*
* Use this function initiate the IOC configuration setup. This function
* will return immediately.
*
* @param[in] bfa instance
*
* @return None
*/
void
bfa_start(struct bfa_s *bfa)
{
bfa_iocfc_start(bfa);
}
/*
* Use this function quiese the IOC. This function will return immediately,
* when the IOC is actually stopped, the bfad->comp will be set.
*
* @param[in]bfa - pointer to bfa_t.
*
* @return None
*
* Special Considerations:
* bfad->comp can be set before or after bfa_stop() returns.
*
* @note
* In case of any failure, we could handle it automatically by doing a
* reset and then succeed the bfa_stop() call.
*/
void
bfa_stop(struct bfa_s *bfa)
{
bfa_iocfc_stop(bfa);
}
void
bfa_comp_deq(struct bfa_s *bfa, struct list_head *comp_q)
{
INIT_LIST_HEAD(comp_q);
list_splice_tail_init(&bfa->comp_q, comp_q);
}
void
bfa_comp_process(struct bfa_s *bfa, struct list_head *comp_q)
{
struct list_head *qe;
struct list_head *qen;
struct bfa_cb_qe_s *hcb_qe;
list_for_each_safe(qe, qen, comp_q) {
hcb_qe = (struct bfa_cb_qe_s *) qe;
hcb_qe->cbfn(hcb_qe->cbarg, BFA_TRUE);
}
}
void
bfa_comp_free(struct bfa_s *bfa, struct list_head *comp_q)
{
struct list_head *qe;
struct bfa_cb_qe_s *hcb_qe;
while (!list_empty(comp_q)) {
bfa_q_deq(comp_q, &qe);
hcb_qe = (struct bfa_cb_qe_s *) qe;
hcb_qe->cbfn(hcb_qe->cbarg, BFA_FALSE);
}
}
void
bfa_attach_fcs(struct bfa_s *bfa)
{
bfa->fcs = BFA_TRUE;
}
/*
* Periodic timer heart beat from driver
*/
void
bfa_timer_tick(struct bfa_s *bfa)
{
bfa_timer_beat(&bfa->timer_mod);
}
/*
* Return the list of PCI vendor/device id lists supported by this
* BFA instance.
*/
void
bfa_get_pciids(struct bfa_pciid_s **pciids, int *npciids)
{
static struct bfa_pciid_s __pciids[] = {
{BFA_PCI_VENDOR_ID_BROCADE, BFA_PCI_DEVICE_ID_FC_8G2P},
{BFA_PCI_VENDOR_ID_BROCADE, BFA_PCI_DEVICE_ID_FC_8G1P},
{BFA_PCI_VENDOR_ID_BROCADE, BFA_PCI_DEVICE_ID_CT},
{BFA_PCI_VENDOR_ID_BROCADE, BFA_PCI_DEVICE_ID_CT_FC},
};
*npciids = sizeof(__pciids) / sizeof(__pciids[0]);
*pciids = __pciids;
}
/*
* Use this function query the default struct bfa_iocfc_cfg_s value (compiled
* into BFA layer). The OS driver can then turn back and overwrite entries that
* have been configured by the user.
*
* @param[in] cfg - pointer to bfa_ioc_cfg_t
*
* @return
* void
*
* Special Considerations:
* note
*/
void
bfa_cfg_get_default(struct bfa_iocfc_cfg_s *cfg)
{
cfg->fwcfg.num_fabrics = DEF_CFG_NUM_FABRICS;
cfg->fwcfg.num_lports = DEF_CFG_NUM_LPORTS;
cfg->fwcfg.num_rports = DEF_CFG_NUM_RPORTS;
cfg->fwcfg.num_ioim_reqs = DEF_CFG_NUM_IOIM_REQS;
cfg->fwcfg.num_tskim_reqs = DEF_CFG_NUM_TSKIM_REQS;
cfg->fwcfg.num_fcxp_reqs = DEF_CFG_NUM_FCXP_REQS;
cfg->fwcfg.num_uf_bufs = DEF_CFG_NUM_UF_BUFS;
cfg->fwcfg.num_cqs = DEF_CFG_NUM_CQS;
cfg->drvcfg.num_reqq_elems = DEF_CFG_NUM_REQQ_ELEMS;
cfg->drvcfg.num_rspq_elems = DEF_CFG_NUM_RSPQ_ELEMS;
cfg->drvcfg.num_sgpgs = DEF_CFG_NUM_SGPGS;
cfg->drvcfg.num_sboot_tgts = DEF_CFG_NUM_SBOOT_TGTS;
cfg->drvcfg.num_sboot_luns = DEF_CFG_NUM_SBOOT_LUNS;
cfg->drvcfg.path_tov = BFA_FCPIM_PATHTOV_DEF;
cfg->drvcfg.ioc_recover = BFA_FALSE;
cfg->drvcfg.delay_comp = BFA_FALSE;
}
void
bfa_cfg_get_min(struct bfa_iocfc_cfg_s *cfg)
{
bfa_cfg_get_default(cfg);
cfg->fwcfg.num_ioim_reqs = BFA_IOIM_MIN;
cfg->fwcfg.num_tskim_reqs = BFA_TSKIM_MIN;
cfg->fwcfg.num_fcxp_reqs = BFA_FCXP_MIN;
cfg->fwcfg.num_uf_bufs = BFA_UF_MIN;
cfg->fwcfg.num_rports = BFA_RPORT_MIN;
cfg->drvcfg.num_sgpgs = BFA_SGPG_MIN;
cfg->drvcfg.num_reqq_elems = BFA_REQQ_NELEMS_MIN;
cfg->drvcfg.num_rspq_elems = BFA_RSPQ_NELEMS_MIN;
cfg->drvcfg.min_cfg = BFA_TRUE;
}
void
bfa_get_attr(struct bfa_s *bfa, struct bfa_ioc_attr_s *ioc_attr)
{
bfa_ioc_get_attr(&bfa->ioc, ioc_attr);
}
/*
* Retrieve firmware trace information on IOC failure.
*/
bfa_status_t
bfa_debug_fwsave(struct bfa_s *bfa, void *trcdata, int *trclen)
{
return bfa_ioc_debug_fwsave(&bfa->ioc, trcdata, trclen);
}
/*
* Fetch firmware trace data.
*
* @param[in] bfa BFA instance
* @param[out] trcdata Firmware trace buffer
* @param[in,out] trclen Firmware trace buffer len
*
* @retval BFA_STATUS_OK Firmware trace is fetched.
* @retval BFA_STATUS_INPROGRESS Firmware trace fetch is in progress.
*/
bfa_status_t
bfa_debug_fwtrc(struct bfa_s *bfa, void *trcdata, int *trclen)
{
return bfa_ioc_debug_fwtrc(&bfa->ioc, trcdata, trclen);
}
/*
* Dump firmware memory.
*
* @param[in] bfa BFA instance
* @param[out] buf buffer for dump
* @param[in,out] offset smem offset to start read
* @param[in,out] buflen length of buffer
*
* @retval BFA_STATUS_OK Firmware memory is dumped.
* @retval BFA_STATUS_INPROGRESS Firmware memory dump is in progress.
*/
bfa_status_t
bfa_debug_fwcore(struct bfa_s *bfa, void *buf, u32 *offset, int *buflen)
{
return bfa_ioc_debug_fwcore(&bfa->ioc, buf, offset, buflen);
}