linux/drivers/crypto/cavium/nitrox/nitrox_mbx.c
Herbert Xu cd078cb6a0 crypto: cavium/nitrox - Fix sparse warnings
This patch fixes all the sparse warnings in cavium/nitrox:

- Fix endianness warnings by adding the correct markers to unions.
- Add missing header inclusions for prototypes.
- Move nitrox_sriov_configure prototype into the isr header file.

Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
2020-11-13 20:38:45 +11:00

214 lines
4.9 KiB
C

// SPDX-License-Identifier: GPL-2.0
#include <linux/workqueue.h>
#include "nitrox_csr.h"
#include "nitrox_hal.h"
#include "nitrox_dev.h"
#include "nitrox_mbx.h"
#define RING_TO_VFNO(_x, _y) ((_x) / (_y))
/**
* mbx_msg_type - Mailbox message types
*/
enum mbx_msg_type {
MBX_MSG_TYPE_NOP,
MBX_MSG_TYPE_REQ,
MBX_MSG_TYPE_ACK,
MBX_MSG_TYPE_NACK,
};
/**
* mbx_msg_opcode - Mailbox message opcodes
*/
enum mbx_msg_opcode {
MSG_OP_VF_MODE = 1,
MSG_OP_VF_UP,
MSG_OP_VF_DOWN,
MSG_OP_CHIPID_VFID,
MSG_OP_MCODE_INFO = 11,
};
struct pf2vf_work {
struct nitrox_vfdev *vfdev;
struct nitrox_device *ndev;
struct work_struct pf2vf_resp;
};
static inline u64 pf2vf_read_mbox(struct nitrox_device *ndev, int ring)
{
u64 reg_addr;
reg_addr = NPS_PKT_MBOX_VF_PF_PFDATAX(ring);
return nitrox_read_csr(ndev, reg_addr);
}
static inline void pf2vf_write_mbox(struct nitrox_device *ndev, u64 value,
int ring)
{
u64 reg_addr;
reg_addr = NPS_PKT_MBOX_PF_VF_PFDATAX(ring);
nitrox_write_csr(ndev, reg_addr, value);
}
static void pf2vf_send_response(struct nitrox_device *ndev,
struct nitrox_vfdev *vfdev)
{
union mbox_msg msg;
msg.value = vfdev->msg.value;
switch (vfdev->msg.opcode) {
case MSG_OP_VF_MODE:
msg.data = ndev->mode;
break;
case MSG_OP_VF_UP:
vfdev->nr_queues = vfdev->msg.data;
atomic_set(&vfdev->state, __NDEV_READY);
break;
case MSG_OP_CHIPID_VFID:
msg.id.chipid = ndev->idx;
msg.id.vfid = vfdev->vfno;
break;
case MSG_OP_VF_DOWN:
vfdev->nr_queues = 0;
atomic_set(&vfdev->state, __NDEV_NOT_READY);
break;
case MSG_OP_MCODE_INFO:
msg.data = 0;
msg.mcode_info.count = 2;
msg.mcode_info.info = MCODE_TYPE_SE_SSL | (MCODE_TYPE_AE << 5);
msg.mcode_info.next_se_grp = 1;
msg.mcode_info.next_ae_grp = 1;
break;
default:
msg.type = MBX_MSG_TYPE_NOP;
break;
}
if (msg.type == MBX_MSG_TYPE_NOP)
return;
/* send ACK to VF */
msg.type = MBX_MSG_TYPE_ACK;
pf2vf_write_mbox(ndev, msg.value, vfdev->ring);
vfdev->msg.value = 0;
atomic64_inc(&vfdev->mbx_resp);
}
static void pf2vf_resp_handler(struct work_struct *work)
{
struct pf2vf_work *pf2vf_resp = container_of(work, struct pf2vf_work,
pf2vf_resp);
struct nitrox_vfdev *vfdev = pf2vf_resp->vfdev;
struct nitrox_device *ndev = pf2vf_resp->ndev;
switch (vfdev->msg.type) {
case MBX_MSG_TYPE_REQ:
/* process the request from VF */
pf2vf_send_response(ndev, vfdev);
break;
case MBX_MSG_TYPE_ACK:
case MBX_MSG_TYPE_NACK:
break;
}
kfree(pf2vf_resp);
}
void nitrox_pf2vf_mbox_handler(struct nitrox_device *ndev)
{
struct nitrox_vfdev *vfdev;
struct pf2vf_work *pfwork;
u64 value, reg_addr;
u32 i;
int vfno;
/* loop for VF(0..63) */
reg_addr = NPS_PKT_MBOX_INT_LO;
value = nitrox_read_csr(ndev, reg_addr);
for_each_set_bit(i, (const unsigned long *)&value, BITS_PER_LONG) {
/* get the vfno from ring */
vfno = RING_TO_VFNO(i, ndev->iov.max_vf_queues);
vfdev = ndev->iov.vfdev + vfno;
vfdev->ring = i;
/* fill the vf mailbox data */
vfdev->msg.value = pf2vf_read_mbox(ndev, vfdev->ring);
pfwork = kzalloc(sizeof(*pfwork), GFP_ATOMIC);
if (!pfwork)
continue;
pfwork->vfdev = vfdev;
pfwork->ndev = ndev;
INIT_WORK(&pfwork->pf2vf_resp, pf2vf_resp_handler);
queue_work(ndev->iov.pf2vf_wq, &pfwork->pf2vf_resp);
/* clear the corresponding vf bit */
nitrox_write_csr(ndev, reg_addr, BIT_ULL(i));
}
/* loop for VF(64..127) */
reg_addr = NPS_PKT_MBOX_INT_HI;
value = nitrox_read_csr(ndev, reg_addr);
for_each_set_bit(i, (const unsigned long *)&value, BITS_PER_LONG) {
/* get the vfno from ring */
vfno = RING_TO_VFNO(i + 64, ndev->iov.max_vf_queues);
vfdev = ndev->iov.vfdev + vfno;
vfdev->ring = (i + 64);
/* fill the vf mailbox data */
vfdev->msg.value = pf2vf_read_mbox(ndev, vfdev->ring);
pfwork = kzalloc(sizeof(*pfwork), GFP_ATOMIC);
if (!pfwork)
continue;
pfwork->vfdev = vfdev;
pfwork->ndev = ndev;
INIT_WORK(&pfwork->pf2vf_resp, pf2vf_resp_handler);
queue_work(ndev->iov.pf2vf_wq, &pfwork->pf2vf_resp);
/* clear the corresponding vf bit */
nitrox_write_csr(ndev, reg_addr, BIT_ULL(i));
}
}
int nitrox_mbox_init(struct nitrox_device *ndev)
{
struct nitrox_vfdev *vfdev;
int i;
ndev->iov.vfdev = kcalloc(ndev->iov.num_vfs,
sizeof(struct nitrox_vfdev), GFP_KERNEL);
if (!ndev->iov.vfdev)
return -ENOMEM;
for (i = 0; i < ndev->iov.num_vfs; i++) {
vfdev = ndev->iov.vfdev + i;
vfdev->vfno = i;
}
/* allocate pf2vf response workqueue */
ndev->iov.pf2vf_wq = alloc_workqueue("nitrox_pf2vf", 0, 0);
if (!ndev->iov.pf2vf_wq) {
kfree(ndev->iov.vfdev);
return -ENOMEM;
}
/* enable pf2vf mailbox interrupts */
enable_pf2vf_mbox_interrupts(ndev);
return 0;
}
void nitrox_mbox_cleanup(struct nitrox_device *ndev)
{
/* disable pf2vf mailbox interrupts */
disable_pf2vf_mbox_interrupts(ndev);
/* destroy workqueue */
if (ndev->iov.pf2vf_wq)
destroy_workqueue(ndev->iov.pf2vf_wq);
kfree(ndev->iov.vfdev);
ndev->iov.pf2vf_wq = NULL;
ndev->iov.vfdev = NULL;
}