1 /* SPDX-License-Identifier: BSD-3-Clause
2 * Copyright(c) 2010-2014 Intel Corporation
10 #include <rte_atomic.h>
11 #include <rte_memory.h>
12 #include <rte_mempool.h>
15 #include "virtio_pci.h"
16 #include "virtio_ring.h"
17 #include "virtio_logs.h"
18 #include "virtio_rxtx.h"
22 #define DEFAULT_TX_FREE_THRESH 32
23 #define DEFAULT_RX_FREE_THRESH 32
25 #define VIRTIO_MBUF_BURST_SZ 64
27 * Per virtio_ring.h in Linux.
28 * For virtio_pci on SMP, we don't need to order with respect to MMIO
29 * accesses through relaxed memory I/O windows, so smp_mb() et al are
32 * For using virtio to talk to real devices (eg. vDPA) we do need real
36 virtio_mb(uint8_t weak_barriers)
45 virtio_rmb(uint8_t weak_barriers)
54 virtio_wmb(uint8_t weak_barriers)
62 static inline uint16_t
63 virtqueue_fetch_flags_packed(struct vring_packed_desc *dp,
64 uint8_t weak_barriers)
69 /* x86 prefers to using rte_smp_rmb over __atomic_load_n as it reports
70 * a better perf(~1.5%), which comes from the saved branch by the compiler.
71 * The if and else branch are identical with the smp and io barriers both
72 * defined as compiler barriers on x86.
74 #ifdef RTE_ARCH_X86_64
78 flags = __atomic_load_n(&dp->flags, __ATOMIC_ACQUIRE);
89 virtqueue_store_flags_packed(struct vring_packed_desc *dp,
90 uint16_t flags, uint8_t weak_barriers)
93 /* x86 prefers to using rte_smp_wmb over __atomic_store_n as it reports
94 * a better perf(~1.5%), which comes from the saved branch by the compiler.
95 * The if and else branch are identical with the smp and io barriers both
96 * defined as compiler barriers on x86.
98 #ifdef RTE_ARCH_X86_64
102 __atomic_store_n(&dp->flags, flags, __ATOMIC_RELEASE);
109 #ifdef RTE_PMD_PACKET_PREFETCH
110 #define rte_packet_prefetch(p) rte_prefetch1(p)
112 #define rte_packet_prefetch(p) do {} while(0)
115 #define VIRTQUEUE_MAX_NAME_SZ 32
117 #ifdef RTE_VIRTIO_USER
119 * Return the physical address (or virtual address in case of
120 * virtio-user) of mbuf data buffer.
122 * The address is firstly casted to the word size (sizeof(uintptr_t))
123 * before casting it to uint64_t. This is to make it work with different
124 * combination of word size (64 bit and 32 bit) and virtio device
125 * (virtio-pci and virtio-user).
127 #define VIRTIO_MBUF_ADDR(mb, vq) \
128 ((uint64_t)(*(uintptr_t *)((uintptr_t)(mb) + (vq)->offset)))
130 #define VIRTIO_MBUF_ADDR(mb, vq) ((mb)->buf_iova)
134 * Return the physical address (or virtual address in case of
135 * virtio-user) of mbuf data buffer, taking care of mbuf data offset
137 #define VIRTIO_MBUF_DATA_DMA_ADDR(mb, vq) \
138 (VIRTIO_MBUF_ADDR(mb, vq) + (mb)->data_off)
140 #define VTNET_SQ_RQ_QUEUE_IDX 0
141 #define VTNET_SQ_TQ_QUEUE_IDX 1
142 #define VTNET_SQ_CQ_QUEUE_IDX 2
144 enum { VTNET_RQ = 0, VTNET_TQ = 1, VTNET_CQ = 2 };
146 * The maximum virtqueue size is 2^15. Use that value as the end of
147 * descriptor chain terminator since it will never be a valid index
148 * in the descriptor table. This is used to verify we are correctly
149 * handling vq_free_cnt.
151 #define VQ_RING_DESC_CHAIN_END 32768
154 * Control the RX mode, ie. promiscuous, allmulti, etc...
155 * All commands require an "out" sg entry containing a 1 byte
156 * state value, zero = disable, non-zero = enable. Commands
157 * 0 and 1 are supported with the VIRTIO_NET_F_CTRL_RX feature.
158 * Commands 2-5 are added with VIRTIO_NET_F_CTRL_RX_EXTRA.
160 #define VIRTIO_NET_CTRL_RX 0
161 #define VIRTIO_NET_CTRL_RX_PROMISC 0
162 #define VIRTIO_NET_CTRL_RX_ALLMULTI 1
163 #define VIRTIO_NET_CTRL_RX_ALLUNI 2
164 #define VIRTIO_NET_CTRL_RX_NOMULTI 3
165 #define VIRTIO_NET_CTRL_RX_NOUNI 4
166 #define VIRTIO_NET_CTRL_RX_NOBCAST 5
171 * The MAC filter table is managed by the hypervisor, the guest should
172 * assume the size is infinite. Filtering should be considered
173 * non-perfect, ie. based on hypervisor resources, the guest may
174 * received packets from sources not specified in the filter list.
176 * In addition to the class/cmd header, the TABLE_SET command requires
177 * two out scatterlists. Each contains a 4 byte count of entries followed
178 * by a concatenated byte stream of the ETH_ALEN MAC addresses. The
179 * first sg list contains unicast addresses, the second is for multicast.
180 * This functionality is present if the VIRTIO_NET_F_CTRL_RX feature
183 * The ADDR_SET command requests one out scatterlist, it contains a
184 * 6 bytes MAC address. This functionality is present if the
185 * VIRTIO_NET_F_CTRL_MAC_ADDR feature is available.
187 struct virtio_net_ctrl_mac {
189 uint8_t macs[][RTE_ETHER_ADDR_LEN];
192 #define VIRTIO_NET_CTRL_MAC 1
193 #define VIRTIO_NET_CTRL_MAC_TABLE_SET 0
194 #define VIRTIO_NET_CTRL_MAC_ADDR_SET 1
197 * Control VLAN filtering
199 * The VLAN filter table is controlled via a simple ADD/DEL interface.
200 * VLAN IDs not added may be filtered by the hypervisor. Del is the
201 * opposite of add. Both commands expect an out entry containing a 2
202 * byte VLAN ID. VLAN filtering is available with the
203 * VIRTIO_NET_F_CTRL_VLAN feature bit.
205 #define VIRTIO_NET_CTRL_VLAN 2
206 #define VIRTIO_NET_CTRL_VLAN_ADD 0
207 #define VIRTIO_NET_CTRL_VLAN_DEL 1
210 * Control link announce acknowledgement
212 * The command VIRTIO_NET_CTRL_ANNOUNCE_ACK is used to indicate that
213 * driver has recevied the notification; device would clear the
214 * VIRTIO_NET_S_ANNOUNCE bit in the status field after it receives
217 #define VIRTIO_NET_CTRL_ANNOUNCE 3
218 #define VIRTIO_NET_CTRL_ANNOUNCE_ACK 0
220 struct virtio_net_ctrl_hdr {
225 typedef uint8_t virtio_net_ctrl_ack;
227 #define VIRTIO_NET_OK 0
228 #define VIRTIO_NET_ERR 1
230 #define VIRTIO_MAX_CTRL_DATA 2048
232 struct virtio_pmd_ctrl {
233 struct virtio_net_ctrl_hdr hdr;
234 virtio_net_ctrl_ack status;
235 uint8_t data[VIRTIO_MAX_CTRL_DATA];
238 struct vq_desc_extra {
245 struct virtio_hw *hw; /**< virtio_hw structure pointer. */
248 /**< vring keeping desc, used and avail */
253 /**< vring keeping descs and events */
254 struct vring_packed ring;
255 bool used_wrap_counter;
256 uint16_t cached_flags; /**< cached flags for descs */
257 uint16_t event_flags_shadow;
261 uint16_t vq_used_cons_idx; /**< last consumed descriptor */
262 uint16_t vq_nentries; /**< vring desc numbers */
263 uint16_t vq_free_cnt; /**< num of desc available */
264 uint16_t vq_avail_idx; /**< sync until needed */
265 uint16_t vq_free_thresh; /**< free threshold */
267 void *vq_ring_virt_mem; /**< linear address of vring*/
268 unsigned int vq_ring_size;
271 struct virtnet_rx rxq;
272 struct virtnet_tx txq;
273 struct virtnet_ctl cq;
276 rte_iova_t vq_ring_mem; /**< physical address of vring,
277 * or virtual address for virtio_user. */
280 * Head of the free chain in the descriptor table. If
281 * there are no free descriptors, this will be set to
282 * VQ_RING_DESC_CHAIN_END.
284 uint16_t vq_desc_head_idx;
285 uint16_t vq_desc_tail_idx;
286 uint16_t vq_queue_index; /**< PCI queue index */
287 uint16_t offset; /**< relative offset to obtain addr in mbuf */
288 uint16_t *notify_addr;
289 struct rte_mbuf **sw_ring; /**< RX software ring. */
290 struct vq_desc_extra vq_descx[0];
293 /* If multiqueue is provided by host, then we suppport it. */
294 #define VIRTIO_NET_CTRL_MQ 4
295 #define VIRTIO_NET_CTRL_MQ_VQ_PAIRS_SET 0
296 #define VIRTIO_NET_CTRL_MQ_VQ_PAIRS_MIN 1
297 #define VIRTIO_NET_CTRL_MQ_VQ_PAIRS_MAX 0x8000
300 * This is the first element of the scatter-gather list. If you don't
301 * specify GSO or CSUM features, you can simply ignore the header.
303 struct virtio_net_hdr {
304 #define VIRTIO_NET_HDR_F_NEEDS_CSUM 1 /**< Use csum_start,csum_offset*/
305 #define VIRTIO_NET_HDR_F_DATA_VALID 2 /**< Checksum is valid */
307 #define VIRTIO_NET_HDR_GSO_NONE 0 /**< Not a GSO frame */
308 #define VIRTIO_NET_HDR_GSO_TCPV4 1 /**< GSO frame, IPv4 TCP (TSO) */
309 #define VIRTIO_NET_HDR_GSO_UDP 3 /**< GSO frame, IPv4 UDP (UFO) */
310 #define VIRTIO_NET_HDR_GSO_TCPV6 4 /**< GSO frame, IPv6 TCP */
311 #define VIRTIO_NET_HDR_GSO_ECN 0x80 /**< TCP has ECN set */
313 uint16_t hdr_len; /**< Ethernet + IP + tcp/udp hdrs */
314 uint16_t gso_size; /**< Bytes to append to hdr_len per frame */
315 uint16_t csum_start; /**< Position to start checksumming from */
316 uint16_t csum_offset; /**< Offset after that to place checksum */
320 * This is the version of the header to use when the MRG_RXBUF
321 * feature has been negotiated.
323 struct virtio_net_hdr_mrg_rxbuf {
324 struct virtio_net_hdr hdr;
325 uint16_t num_buffers; /**< Number of merged rx buffers */
328 /* Region reserved to allow for transmit header and indirect ring */
329 #define VIRTIO_MAX_TX_INDIRECT 8
330 struct virtio_tx_region {
331 struct virtio_net_hdr_mrg_rxbuf tx_hdr;
333 struct vring_desc tx_indir[VIRTIO_MAX_TX_INDIRECT];
334 struct vring_packed_desc
335 tx_packed_indir[VIRTIO_MAX_TX_INDIRECT];
340 desc_is_used(struct vring_packed_desc *desc, struct virtqueue *vq)
342 uint16_t used, avail, flags;
344 flags = virtqueue_fetch_flags_packed(desc, vq->hw->weak_barriers);
345 used = !!(flags & VRING_PACKED_DESC_F_USED);
346 avail = !!(flags & VRING_PACKED_DESC_F_AVAIL);
348 return avail == used && used == vq->vq_packed.used_wrap_counter;
352 vring_desc_init_packed(struct virtqueue *vq, int n)
355 for (i = 0; i < n - 1; i++) {
356 vq->vq_packed.ring.desc[i].id = i;
357 vq->vq_descx[i].next = i + 1;
359 vq->vq_packed.ring.desc[i].id = i;
360 vq->vq_descx[i].next = VQ_RING_DESC_CHAIN_END;
363 /* Chain all the descriptors in the ring with an END */
365 vring_desc_init_split(struct vring_desc *dp, uint16_t n)
369 for (i = 0; i < n - 1; i++)
370 dp[i].next = (uint16_t)(i + 1);
371 dp[i].next = VQ_RING_DESC_CHAIN_END;
375 vring_desc_init_indirect_packed(struct vring_packed_desc *dp, int n)
378 for (i = 0; i < n; i++) {
379 dp[i].id = (uint16_t)i;
380 dp[i].flags = VRING_DESC_F_WRITE;
385 * Tell the backend not to interrupt us. Implementation for packed virtqueues.
388 virtqueue_disable_intr_packed(struct virtqueue *vq)
390 if (vq->vq_packed.event_flags_shadow != RING_EVENT_FLAGS_DISABLE) {
391 vq->vq_packed.event_flags_shadow = RING_EVENT_FLAGS_DISABLE;
392 vq->vq_packed.ring.driver->desc_event_flags =
393 vq->vq_packed.event_flags_shadow;
398 * Tell the backend not to interrupt us. Implementation for split virtqueues.
401 virtqueue_disable_intr_split(struct virtqueue *vq)
403 vq->vq_split.ring.avail->flags |= VRING_AVAIL_F_NO_INTERRUPT;
407 * Tell the backend not to interrupt us.
410 virtqueue_disable_intr(struct virtqueue *vq)
412 if (vtpci_packed_queue(vq->hw))
413 virtqueue_disable_intr_packed(vq);
415 virtqueue_disable_intr_split(vq);
419 * Tell the backend to interrupt. Implementation for packed virtqueues.
422 virtqueue_enable_intr_packed(struct virtqueue *vq)
424 if (vq->vq_packed.event_flags_shadow == RING_EVENT_FLAGS_DISABLE) {
425 vq->vq_packed.event_flags_shadow = RING_EVENT_FLAGS_ENABLE;
426 vq->vq_packed.ring.driver->desc_event_flags =
427 vq->vq_packed.event_flags_shadow;
432 * Tell the backend to interrupt. Implementation for split virtqueues.
435 virtqueue_enable_intr_split(struct virtqueue *vq)
437 vq->vq_split.ring.avail->flags &= (~VRING_AVAIL_F_NO_INTERRUPT);
441 * Tell the backend to interrupt us.
444 virtqueue_enable_intr(struct virtqueue *vq)
446 if (vtpci_packed_queue(vq->hw))
447 virtqueue_enable_intr_packed(vq);
449 virtqueue_enable_intr_split(vq);
453 * Dump virtqueue internal structures, for debug purpose only.
455 void virtqueue_dump(struct virtqueue *vq);
457 * Get all mbufs to be freed.
459 struct rte_mbuf *virtqueue_detach_unused(struct virtqueue *vq);
461 /* Flush the elements in the used ring. */
462 void virtqueue_rxvq_flush(struct virtqueue *vq);
464 int virtqueue_rxvq_reset_packed(struct virtqueue *vq);
466 int virtqueue_txvq_reset_packed(struct virtqueue *vq);
469 virtqueue_full(const struct virtqueue *vq)
471 return vq->vq_free_cnt == 0;
475 virtio_get_queue_type(struct virtio_hw *hw, uint16_t vtpci_queue_idx)
477 if (vtpci_queue_idx == hw->max_queue_pairs * 2)
479 else if (vtpci_queue_idx % 2 == 0)
485 /* virtqueue_nused has load-acquire or rte_io_rmb insed */
486 static inline uint16_t
487 virtqueue_nused(const struct virtqueue *vq)
491 if (vq->hw->weak_barriers) {
493 * x86 prefers to using rte_smp_rmb over __atomic_load_n as it
494 * reports a slightly better perf, which comes from the saved
495 * branch by the compiler.
496 * The if and else branches are identical with the smp and io
497 * barriers both defined as compiler barriers on x86.
499 #ifdef RTE_ARCH_X86_64
500 idx = vq->vq_split.ring.used->idx;
503 idx = __atomic_load_n(&(vq)->vq_split.ring.used->idx,
507 idx = vq->vq_split.ring.used->idx;
510 return idx - vq->vq_used_cons_idx;
513 void vq_ring_free_chain(struct virtqueue *vq, uint16_t desc_idx);
514 void vq_ring_free_chain_packed(struct virtqueue *vq, uint16_t used_idx);
515 void vq_ring_free_inorder(struct virtqueue *vq, uint16_t desc_idx,
519 vq_update_avail_idx(struct virtqueue *vq)
521 if (vq->hw->weak_barriers) {
522 /* x86 prefers to using rte_smp_wmb over __atomic_store_n as
523 * it reports a slightly better perf, which comes from the
524 * saved branch by the compiler.
525 * The if and else branches are identical with the smp and
526 * io barriers both defined as compiler barriers on x86.
528 #ifdef RTE_ARCH_X86_64
530 vq->vq_split.ring.avail->idx = vq->vq_avail_idx;
532 __atomic_store_n(&vq->vq_split.ring.avail->idx,
533 vq->vq_avail_idx, __ATOMIC_RELEASE);
537 vq->vq_split.ring.avail->idx = vq->vq_avail_idx;
542 vq_update_avail_ring(struct virtqueue *vq, uint16_t desc_idx)
546 * Place the head of the descriptor chain into the next slot and make
547 * it usable to the host. The chain is made available now rather than
548 * deferring to virtqueue_notify() in the hopes that if the host is
549 * currently running on another CPU, we can keep it processing the new
552 avail_idx = (uint16_t)(vq->vq_avail_idx & (vq->vq_nentries - 1));
553 if (unlikely(vq->vq_split.ring.avail->ring[avail_idx] != desc_idx))
554 vq->vq_split.ring.avail->ring[avail_idx] = desc_idx;
559 virtqueue_kick_prepare(struct virtqueue *vq)
562 * Ensure updated avail->idx is visible to vhost before reading
565 virtio_mb(vq->hw->weak_barriers);
566 return !(vq->vq_split.ring.used->flags & VRING_USED_F_NO_NOTIFY);
570 virtqueue_kick_prepare_packed(struct virtqueue *vq)
575 * Ensure updated data is visible to vhost before reading the flags.
577 virtio_mb(vq->hw->weak_barriers);
578 flags = vq->vq_packed.ring.device->desc_event_flags;
580 return flags != RING_EVENT_FLAGS_DISABLE;
584 * virtqueue_kick_prepare*() or the virtio_wmb() should be called
585 * before this function to be sure that all the data is visible to vhost.
588 virtqueue_notify(struct virtqueue *vq)
590 VTPCI_OPS(vq->hw)->notify_queue(vq->hw, vq);
593 #ifdef RTE_LIBRTE_VIRTIO_DEBUG_DUMP
594 #define VIRTQUEUE_DUMP(vq) do { \
595 uint16_t used_idx, nused; \
596 used_idx = __atomic_load_n(&(vq)->vq_split.ring.used->idx, \
598 nused = (uint16_t)(used_idx - (vq)->vq_used_cons_idx); \
599 if (vtpci_packed_queue((vq)->hw)) { \
600 PMD_INIT_LOG(DEBUG, \
601 "VQ: - size=%d; free=%d; used_cons_idx=%d; avail_idx=%d;" \
602 " cached_flags=0x%x; used_wrap_counter=%d", \
603 (vq)->vq_nentries, (vq)->vq_free_cnt, (vq)->vq_used_cons_idx, \
604 (vq)->vq_avail_idx, (vq)->vq_packed.cached_flags, \
605 (vq)->vq_packed.used_wrap_counter); \
608 PMD_INIT_LOG(DEBUG, \
609 "VQ: - size=%d; free=%d; used=%d; desc_head_idx=%d;" \
610 " avail.idx=%d; used_cons_idx=%d; used.idx=%d;" \
611 " avail.flags=0x%x; used.flags=0x%x", \
612 (vq)->vq_nentries, (vq)->vq_free_cnt, nused, (vq)->vq_desc_head_idx, \
613 (vq)->vq_split.ring.avail->idx, (vq)->vq_used_cons_idx, \
614 __atomic_load_n(&(vq)->vq_split.ring.used->idx, __ATOMIC_RELAXED), \
615 (vq)->vq_split.ring.avail->flags, (vq)->vq_split.ring.used->flags); \
618 #define VIRTQUEUE_DUMP(vq) do { } while (0)
621 /* avoid write operation when necessary, to lessen cache issues */
622 #define ASSIGN_UNLESS_EQUAL(var, val) do { \
623 typeof(var) *const var_ = &(var); \
624 typeof(val) const val_ = (val); \
629 #define virtqueue_clear_net_hdr(hdr) do { \
630 typeof(hdr) hdr_ = (hdr); \
631 ASSIGN_UNLESS_EQUAL((hdr_)->csum_start, 0); \
632 ASSIGN_UNLESS_EQUAL((hdr_)->csum_offset, 0); \
633 ASSIGN_UNLESS_EQUAL((hdr_)->flags, 0); \
634 ASSIGN_UNLESS_EQUAL((hdr_)->gso_type, 0); \
635 ASSIGN_UNLESS_EQUAL((hdr_)->gso_size, 0); \
636 ASSIGN_UNLESS_EQUAL((hdr_)->hdr_len, 0); \
640 virtqueue_xmit_offload(struct virtio_net_hdr *hdr,
641 struct rte_mbuf *cookie,
645 if (cookie->ol_flags & PKT_TX_TCP_SEG)
646 cookie->ol_flags |= PKT_TX_TCP_CKSUM;
648 switch (cookie->ol_flags & PKT_TX_L4_MASK) {
649 case PKT_TX_UDP_CKSUM:
650 hdr->csum_start = cookie->l2_len + cookie->l3_len;
651 hdr->csum_offset = offsetof(struct rte_udp_hdr,
653 hdr->flags = VIRTIO_NET_HDR_F_NEEDS_CSUM;
656 case PKT_TX_TCP_CKSUM:
657 hdr->csum_start = cookie->l2_len + cookie->l3_len;
658 hdr->csum_offset = offsetof(struct rte_tcp_hdr, cksum);
659 hdr->flags = VIRTIO_NET_HDR_F_NEEDS_CSUM;
663 ASSIGN_UNLESS_EQUAL(hdr->csum_start, 0);
664 ASSIGN_UNLESS_EQUAL(hdr->csum_offset, 0);
665 ASSIGN_UNLESS_EQUAL(hdr->flags, 0);
669 /* TCP Segmentation Offload */
670 if (cookie->ol_flags & PKT_TX_TCP_SEG) {
671 hdr->gso_type = (cookie->ol_flags & PKT_TX_IPV6) ?
672 VIRTIO_NET_HDR_GSO_TCPV6 :
673 VIRTIO_NET_HDR_GSO_TCPV4;
674 hdr->gso_size = cookie->tso_segsz;
680 ASSIGN_UNLESS_EQUAL(hdr->gso_type, 0);
681 ASSIGN_UNLESS_EQUAL(hdr->gso_size, 0);
682 ASSIGN_UNLESS_EQUAL(hdr->hdr_len, 0);
688 virtqueue_enqueue_xmit_packed(struct virtnet_tx *txvq, struct rte_mbuf *cookie,
689 uint16_t needed, int use_indirect, int can_push,
692 struct virtio_tx_region *txr = txvq->virtio_net_hdr_mz->addr;
693 struct vq_desc_extra *dxp;
694 struct virtqueue *vq = txvq->vq;
695 struct vring_packed_desc *start_dp, *head_dp;
696 uint16_t idx, id, head_idx, head_flags;
697 int16_t head_size = vq->hw->vtnet_hdr_size;
698 struct virtio_net_hdr *hdr;
700 bool prepend_header = false;
701 uint16_t seg_num = cookie->nb_segs;
703 id = in_order ? vq->vq_avail_idx : vq->vq_desc_head_idx;
705 dxp = &vq->vq_descx[id];
706 dxp->ndescs = needed;
707 dxp->cookie = cookie;
709 head_idx = vq->vq_avail_idx;
712 start_dp = vq->vq_packed.ring.desc;
714 head_dp = &vq->vq_packed.ring.desc[idx];
715 head_flags = cookie->next ? VRING_DESC_F_NEXT : 0;
716 head_flags |= vq->vq_packed.cached_flags;
719 /* prepend cannot fail, checked by caller */
720 hdr = rte_pktmbuf_mtod_offset(cookie, struct virtio_net_hdr *,
722 prepend_header = true;
724 /* if offload disabled, it is not zeroed below, do it now */
725 if (!vq->hw->has_tx_offload)
726 virtqueue_clear_net_hdr(hdr);
727 } else if (use_indirect) {
728 /* setup tx ring slot to point to indirect
729 * descriptor list stored in reserved region.
731 * the first slot in indirect ring is already preset
732 * to point to the header in reserved region
734 start_dp[idx].addr = txvq->virtio_net_hdr_mem +
735 RTE_PTR_DIFF(&txr[idx].tx_packed_indir, txr);
736 start_dp[idx].len = (seg_num + 1) *
737 sizeof(struct vring_packed_desc);
738 /* reset flags for indirect desc */
739 head_flags = VRING_DESC_F_INDIRECT;
740 head_flags |= vq->vq_packed.cached_flags;
741 hdr = (struct virtio_net_hdr *)&txr[idx].tx_hdr;
743 /* loop below will fill in rest of the indirect elements */
744 start_dp = txr[idx].tx_packed_indir;
747 /* setup first tx ring slot to point to header
748 * stored in reserved region.
750 start_dp[idx].addr = txvq->virtio_net_hdr_mem +
751 RTE_PTR_DIFF(&txr[idx].tx_hdr, txr);
752 start_dp[idx].len = vq->hw->vtnet_hdr_size;
753 hdr = (struct virtio_net_hdr *)&txr[idx].tx_hdr;
755 if (idx >= vq->vq_nentries) {
756 idx -= vq->vq_nentries;
757 vq->vq_packed.cached_flags ^=
758 VRING_PACKED_DESC_F_AVAIL_USED;
762 virtqueue_xmit_offload(hdr, cookie, vq->hw->has_tx_offload);
767 start_dp[idx].addr = VIRTIO_MBUF_DATA_DMA_ADDR(cookie, vq);
768 start_dp[idx].len = cookie->data_len;
769 if (prepend_header) {
770 start_dp[idx].addr -= head_size;
771 start_dp[idx].len += head_size;
772 prepend_header = false;
775 if (likely(idx != head_idx)) {
776 flags = cookie->next ? VRING_DESC_F_NEXT : 0;
777 flags |= vq->vq_packed.cached_flags;
778 start_dp[idx].flags = flags;
782 if (idx >= vq->vq_nentries) {
783 idx -= vq->vq_nentries;
784 vq->vq_packed.cached_flags ^=
785 VRING_PACKED_DESC_F_AVAIL_USED;
787 } while ((cookie = cookie->next) != NULL);
789 start_dp[prev].id = id;
793 if (++idx >= vq->vq_nentries) {
794 idx -= vq->vq_nentries;
795 vq->vq_packed.cached_flags ^=
796 VRING_PACKED_DESC_F_AVAIL_USED;
800 vq->vq_free_cnt = (uint16_t)(vq->vq_free_cnt - needed);
801 vq->vq_avail_idx = idx;
804 vq->vq_desc_head_idx = dxp->next;
805 if (vq->vq_desc_head_idx == VQ_RING_DESC_CHAIN_END)
806 vq->vq_desc_tail_idx = VQ_RING_DESC_CHAIN_END;
809 virtqueue_store_flags_packed(head_dp, head_flags,
810 vq->hw->weak_barriers);
814 vq_ring_free_id_packed(struct virtqueue *vq, uint16_t id)
816 struct vq_desc_extra *dxp;
818 dxp = &vq->vq_descx[id];
819 vq->vq_free_cnt += dxp->ndescs;
821 if (vq->vq_desc_tail_idx == VQ_RING_DESC_CHAIN_END)
822 vq->vq_desc_head_idx = id;
824 vq->vq_descx[vq->vq_desc_tail_idx].next = id;
826 vq->vq_desc_tail_idx = id;
827 dxp->next = VQ_RING_DESC_CHAIN_END;
831 virtio_xmit_cleanup_inorder_packed(struct virtqueue *vq, int num)
833 uint16_t used_idx, id, curr_id, free_cnt = 0;
834 uint16_t size = vq->vq_nentries;
835 struct vring_packed_desc *desc = vq->vq_packed.ring.desc;
836 struct vq_desc_extra *dxp;
838 used_idx = vq->vq_used_cons_idx;
839 /* desc_is_used has a load-acquire or rte_io_rmb inside
840 * and wait for used desc in virtqueue.
842 while (num > 0 && desc_is_used(&desc[used_idx], vq)) {
843 id = desc[used_idx].id;
846 dxp = &vq->vq_descx[used_idx];
847 used_idx += dxp->ndescs;
848 free_cnt += dxp->ndescs;
850 if (used_idx >= size) {
852 vq->vq_packed.used_wrap_counter ^= 1;
854 if (dxp->cookie != NULL) {
855 rte_pktmbuf_free(dxp->cookie);
858 } while (curr_id != id);
860 vq->vq_used_cons_idx = used_idx;
861 vq->vq_free_cnt += free_cnt;
865 virtio_xmit_cleanup_normal_packed(struct virtqueue *vq, int num)
867 uint16_t used_idx, id;
868 uint16_t size = vq->vq_nentries;
869 struct vring_packed_desc *desc = vq->vq_packed.ring.desc;
870 struct vq_desc_extra *dxp;
872 used_idx = vq->vq_used_cons_idx;
873 /* desc_is_used has a load-acquire or rte_io_rmb inside
874 * and wait for used desc in virtqueue.
876 while (num-- && desc_is_used(&desc[used_idx], vq)) {
877 id = desc[used_idx].id;
878 dxp = &vq->vq_descx[id];
879 vq->vq_used_cons_idx += dxp->ndescs;
880 if (vq->vq_used_cons_idx >= size) {
881 vq->vq_used_cons_idx -= size;
882 vq->vq_packed.used_wrap_counter ^= 1;
884 vq_ring_free_id_packed(vq, id);
885 if (dxp->cookie != NULL) {
886 rte_pktmbuf_free(dxp->cookie);
889 used_idx = vq->vq_used_cons_idx;
893 /* Cleanup from completed transmits. */
895 virtio_xmit_cleanup_packed(struct virtqueue *vq, int num, int in_order)
898 virtio_xmit_cleanup_inorder_packed(vq, num);
900 virtio_xmit_cleanup_normal_packed(vq, num);
904 virtio_xmit_cleanup(struct virtqueue *vq, uint16_t num)
906 uint16_t i, used_idx, desc_idx;
907 for (i = 0; i < num; i++) {
908 struct vring_used_elem *uep;
909 struct vq_desc_extra *dxp;
911 used_idx = (uint16_t)(vq->vq_used_cons_idx &
912 (vq->vq_nentries - 1));
913 uep = &vq->vq_split.ring.used->ring[used_idx];
915 desc_idx = (uint16_t)uep->id;
916 dxp = &vq->vq_descx[desc_idx];
917 vq->vq_used_cons_idx++;
918 vq_ring_free_chain(vq, desc_idx);
920 if (dxp->cookie != NULL) {
921 rte_pktmbuf_free(dxp->cookie);
927 /* Cleanup from completed inorder transmits. */
928 static __rte_always_inline void
929 virtio_xmit_cleanup_inorder(struct virtqueue *vq, uint16_t num)
931 uint16_t i, idx = vq->vq_used_cons_idx;
932 int16_t free_cnt = 0;
933 struct vq_desc_extra *dxp = NULL;
935 if (unlikely(num == 0))
938 for (i = 0; i < num; i++) {
939 dxp = &vq->vq_descx[idx++ & (vq->vq_nentries - 1)];
940 free_cnt += dxp->ndescs;
941 if (dxp->cookie != NULL) {
942 rte_pktmbuf_free(dxp->cookie);
947 vq->vq_free_cnt += free_cnt;
948 vq->vq_used_cons_idx = idx;
950 #endif /* _VIRTQUEUE_H_ */