vdev = rq->vdev;
for (i = 0; i < blks; i++) {
- rq->bufs[i] = kzalloc(VNIC_RQ_BUF_BLK_SZ, GFP_ATOMIC);
+ rq->bufs[i] = kzalloc(VNIC_RQ_BUF_BLK_SZ(count), GFP_ATOMIC);
if (!rq->bufs[i]) {
pr_err("Failed to alloc rq_bufs\n");
return -ENOMEM;
for (i = 0; i < blks; i++) {
buf = rq->bufs[i];
- for (j = 0; j < VNIC_RQ_BUF_BLK_ENTRIES; j++) {
- buf->index = i * VNIC_RQ_BUF_BLK_ENTRIES + j;
+ for (j = 0; j < VNIC_RQ_BUF_BLK_ENTRIES(count); j++) {
+ buf->index = i * VNIC_RQ_BUF_BLK_ENTRIES(count) + j;
buf->desc = (u8 *)rq->ring.descs +
rq->ring.desc_size * buf->index;
if (buf->index + 1 == count) {
buf->next = rq->bufs[0];
break;
- } else if (j + 1 == VNIC_RQ_BUF_BLK_ENTRIES) {
+ } else if (j + 1 == VNIC_RQ_BUF_BLK_ENTRIES(count)) {
buf->next = rq->bufs[i + 1];
} else {
buf->next = buf + 1;
unsigned int error_interrupt_offset)
{
u64 paddr;
+ unsigned int count = rq->ring.desc_count;
paddr = (u64)rq->ring.base_addr | VNIC_PADDR_TARGET;
writeq(paddr, &rq->ctrl->ring_base);
- iowrite32(rq->ring.desc_count, &rq->ctrl->ring_size);
+ iowrite32(count, &rq->ctrl->ring_size);
iowrite32(cq_index, &rq->ctrl->cq_index);
iowrite32(error_interrupt_enable, &rq->ctrl->error_interrupt_enable);
iowrite32(error_interrupt_offset, &rq->ctrl->error_interrupt_offset);
iowrite32(posted_index, &rq->ctrl->posted_index);
rq->to_use = rq->to_clean =
- &rq->bufs[fetch_index / VNIC_RQ_BUF_BLK_ENTRIES]
- [fetch_index % VNIC_RQ_BUF_BLK_ENTRIES];
+ &rq->bufs[fetch_index / VNIC_RQ_BUF_BLK_ENTRIES(count)]
+ [fetch_index % VNIC_RQ_BUF_BLK_ENTRIES(count)];
}
void vnic_rq_init(struct vnic_rq *rq, unsigned int cq_index,
{
struct vnic_rq_buf *buf;
u32 fetch_index;
+ unsigned int count = rq->ring.desc_count;
BUG_ON(ioread32(&rq->ctrl->enable));
/* Use current fetch_index as the ring starting point */
fetch_index = ioread32(&rq->ctrl->fetch_index);
rq->to_use = rq->to_clean =
- &rq->bufs[fetch_index / VNIC_RQ_BUF_BLK_ENTRIES]
- [fetch_index % VNIC_RQ_BUF_BLK_ENTRIES];
+ &rq->bufs[fetch_index / VNIC_RQ_BUF_BLK_ENTRIES(count)]
+ [fetch_index % VNIC_RQ_BUF_BLK_ENTRIES(count)];
iowrite32(fetch_index, &rq->ctrl->posted_index);
vnic_dev_clear_desc_ring(&rq->ring);
u32 pad10;
};
-/* Break the vnic_rq_buf allocations into blocks of 64 entries */
-#define VNIC_RQ_BUF_BLK_ENTRIES 64
-#define VNIC_RQ_BUF_BLK_SZ \
- (VNIC_RQ_BUF_BLK_ENTRIES * sizeof(struct vnic_rq_buf))
+/* Break the vnic_rq_buf allocations into blocks of 32/64 entries */
+#define VNIC_RQ_BUF_MIN_BLK_ENTRIES 32
+#define VNIC_RQ_BUF_DFLT_BLK_ENTRIES 64
+#define VNIC_RQ_BUF_BLK_ENTRIES(entries) \
+ ((unsigned int)((entries < VNIC_RQ_BUF_DFLT_BLK_ENTRIES) ? \
+ VNIC_RQ_BUF_MIN_BLK_ENTRIES : VNIC_RQ_BUF_DFLT_BLK_ENTRIES))
+#define VNIC_RQ_BUF_BLK_SZ(entries) \
+ (VNIC_RQ_BUF_BLK_ENTRIES(entries) * sizeof(struct vnic_rq_buf))
#define VNIC_RQ_BUF_BLKS_NEEDED(entries) \
- DIV_ROUND_UP(entries, VNIC_RQ_BUF_BLK_ENTRIES)
+ DIV_ROUND_UP(entries, VNIC_RQ_BUF_BLK_ENTRIES(entries))
#define VNIC_RQ_BUF_BLKS_MAX VNIC_RQ_BUF_BLKS_NEEDED(4096)
struct vnic_rq_buf {
vdev = wq->vdev;
for (i = 0; i < blks; i++) {
- wq->bufs[i] = kzalloc(VNIC_WQ_BUF_BLK_SZ, GFP_ATOMIC);
+ wq->bufs[i] = kzalloc(VNIC_WQ_BUF_BLK_SZ(count), GFP_ATOMIC);
if (!wq->bufs[i]) {
pr_err("Failed to alloc wq_bufs\n");
return -ENOMEM;
for (i = 0; i < blks; i++) {
buf = wq->bufs[i];
- for (j = 0; j < VNIC_WQ_BUF_BLK_ENTRIES; j++) {
- buf->index = i * VNIC_WQ_BUF_BLK_ENTRIES + j;
+ for (j = 0; j < VNIC_WQ_BUF_BLK_ENTRIES(count); j++) {
+ buf->index = i * VNIC_WQ_BUF_BLK_ENTRIES(count) + j;
buf->desc = (u8 *)wq->ring.descs +
wq->ring.desc_size * buf->index;
if (buf->index + 1 == count) {
buf->next = wq->bufs[0];
break;
- } else if (j + 1 == VNIC_WQ_BUF_BLK_ENTRIES) {
+ } else if (j + 1 == VNIC_WQ_BUF_BLK_ENTRIES(count)) {
buf->next = wq->bufs[i + 1];
} else {
buf->next = buf + 1;
unsigned int error_interrupt_offset)
{
u64 paddr;
+ unsigned int count = wq->ring.desc_count;
paddr = (u64)wq->ring.base_addr | VNIC_PADDR_TARGET;
writeq(paddr, &wq->ctrl->ring_base);
- iowrite32(wq->ring.desc_count, &wq->ctrl->ring_size);
+ iowrite32(count, &wq->ctrl->ring_size);
iowrite32(fetch_index, &wq->ctrl->fetch_index);
iowrite32(posted_index, &wq->ctrl->posted_index);
iowrite32(cq_index, &wq->ctrl->cq_index);
iowrite32(0, &wq->ctrl->error_status);
wq->to_use = wq->to_clean =
- &wq->bufs[fetch_index / VNIC_WQ_BUF_BLK_ENTRIES]
- [fetch_index % VNIC_WQ_BUF_BLK_ENTRIES];
+ &wq->bufs[fetch_index / VNIC_WQ_BUF_BLK_ENTRIES(count)]
+ [fetch_index % VNIC_WQ_BUF_BLK_ENTRIES(count)];
}
void vnic_wq_init(struct vnic_wq *wq, unsigned int cq_index,
void *desc;
};
-/* Break the vnic_wq_buf allocations into blocks of 64 entries */
-#define VNIC_WQ_BUF_BLK_ENTRIES 64
-#define VNIC_WQ_BUF_BLK_SZ \
- (VNIC_WQ_BUF_BLK_ENTRIES * sizeof(struct vnic_wq_buf))
+/* Break the vnic_wq_buf allocations into blocks of 32/64 entries */
+#define VNIC_WQ_BUF_MIN_BLK_ENTRIES 32
+#define VNIC_WQ_BUF_DFLT_BLK_ENTRIES 64
+#define VNIC_WQ_BUF_BLK_ENTRIES(entries) \
+ ((unsigned int)((entries < VNIC_WQ_BUF_DFLT_BLK_ENTRIES) ? \
+ VNIC_WQ_BUF_MIN_BLK_ENTRIES : VNIC_WQ_BUF_DFLT_BLK_ENTRIES))
+#define VNIC_WQ_BUF_BLK_SZ(entries) \
+ (VNIC_WQ_BUF_BLK_ENTRIES(entries) * sizeof(struct vnic_wq_buf))
#define VNIC_WQ_BUF_BLKS_NEEDED(entries) \
- DIV_ROUND_UP(entries, VNIC_WQ_BUF_BLK_ENTRIES)
+ DIV_ROUND_UP(entries, VNIC_WQ_BUF_BLK_ENTRIES(entries))
#define VNIC_WQ_BUF_BLKS_MAX VNIC_WQ_BUF_BLKS_NEEDED(4096)
struct vnic_wq {