/* * Copyright (c) 2007, 2014 Mellanox Technologies. All rights reserved. * * This software is available to you under a choice of one of two * licenses. You may choose to be licensed under the terms of the GNU * General Public License (GPL) Version 2, available from the file * COPYING in the main directory of this source tree, or the * OpenIB.org BSD license below: * * Redistribution and use in source and binary forms, with or * without modification, are permitted provided that the following * conditions are met: * * - Redistributions of source code must retain the above * copyright notice, this list of conditions and the following * disclaimer. * * - Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following * disclaimer in the documentation and/or other materials * provided with the distribution. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "mlx4_en.h" #include "utils.h" enum { MAX_INLINE = 104, /* 128 - 16 - 4 - 4 */ MAX_BF = 256, MIN_PKT_LEN = 17, }; static int inline_thold __read_mostly = MAX_INLINE; module_param_named(inline_thold, inline_thold, uint, 0444); MODULE_PARM_DESC(inline_thold, "threshold for using inline data"); int mlx4_en_create_tx_ring(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring **pring, u32 size, u16 stride, int node, int queue_idx) { struct mlx4_en_dev *mdev = priv->mdev; struct mlx4_en_tx_ring *ring; int tmp; int err; ring = kzalloc_node(sizeof(struct mlx4_en_tx_ring), GFP_KERNEL, node); if (!ring) { ring = kzalloc(sizeof(struct mlx4_en_tx_ring), GFP_KERNEL); if (!ring) { en_err(priv, "Failed allocating TX ring\n"); return -ENOMEM; } } ring->size = size; ring->size_mask = size - 1; ring->stride = stride; ring->full_size = ring->size - HEADROOM - MAX_DESC_TXBBS; ring->inline_thold = min(inline_thold, MAX_INLINE); mtx_init(&ring->tx_lock.m, "mlx4 tx", NULL, MTX_DEF); mtx_init(&ring->comp_lock.m, "mlx4 comp", NULL, MTX_DEF); /* Allocate the buf ring */ ring->br = buf_ring_alloc(MLX4_EN_DEF_TX_QUEUE_SIZE, M_DEVBUF, M_WAITOK, &ring->tx_lock.m); if (ring->br == NULL) { en_err(priv, "Failed allocating tx_info ring\n"); return -ENOMEM; } tmp = size * sizeof(struct mlx4_en_tx_info); ring->tx_info = vmalloc_node(tmp, node); if (!ring->tx_info) { ring->tx_info = vmalloc(tmp); if (!ring->tx_info) { err = -ENOMEM; goto err_ring; } } en_dbg(DRV, priv, "Allocated tx_info ring at addr:%p size:%d\n", ring->tx_info, tmp); ring->bounce_buf = kmalloc_node(MAX_DESC_SIZE, GFP_KERNEL, node); if (!ring->bounce_buf) { ring->bounce_buf = kmalloc(MAX_DESC_SIZE, GFP_KERNEL); if (!ring->bounce_buf) { err = -ENOMEM; goto err_info; } } ring->buf_size = ALIGN(size * ring->stride, MLX4_EN_PAGE_SIZE); /* Allocate HW buffers on provided NUMA node */ err = mlx4_alloc_hwq_res(mdev->dev, &ring->wqres, ring->buf_size, 2 * PAGE_SIZE); if (err) { en_err(priv, "Failed allocating hwq resources\n"); goto err_bounce; } err = mlx4_en_map_buffer(&ring->wqres.buf); if (err) { en_err(priv, "Failed to map TX buffer\n"); goto err_hwq_res; } ring->buf = ring->wqres.buf.direct.buf; en_dbg(DRV, priv, "Allocated TX ring (addr:%p) - buf:%p size:%d " "buf_size:%d dma:%llx\n", ring, ring->buf, ring->size, ring->buf_size, (unsigned long long) ring->wqres.buf.direct.map); err = mlx4_qp_reserve_range(mdev->dev, 1, 1, &ring->qpn, MLX4_RESERVE_BF_QP); if (err) { en_err(priv, "failed reserving qp for TX ring\n"); goto err_map; } err = mlx4_qp_alloc(mdev->dev, ring->qpn, &ring->qp); if (err) { en_err(priv, "Failed allocating qp %d\n", ring->qpn); goto err_reserve; } ring->qp.event = mlx4_en_sqp_event; err = mlx4_bf_alloc(mdev->dev, &ring->bf, node); if (err) { en_dbg(DRV, priv, "working without blueflame (%d)", err); ring->bf.uar = &mdev->priv_uar; ring->bf.uar->map = mdev->uar_map; ring->bf_enabled = false; } else ring->bf_enabled = true; ring->queue_index = queue_idx; if (queue_idx < priv->num_tx_rings_p_up ) CPU_SET(queue_idx, &ring->affinity_mask); *pring = ring; return 0; err_reserve: mlx4_qp_release_range(mdev->dev, ring->qpn, 1); err_map: mlx4_en_unmap_buffer(&ring->wqres.buf); err_hwq_res: mlx4_free_hwq_res(mdev->dev, &ring->wqres, ring->buf_size); err_bounce: kfree(ring->bounce_buf); err_info: vfree(ring->tx_info); err_ring: buf_ring_free(ring->br, M_DEVBUF); kfree(ring); return err; } void mlx4_en_destroy_tx_ring(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring **pring) { struct mlx4_en_dev *mdev = priv->mdev; struct mlx4_en_tx_ring *ring = *pring; en_dbg(DRV, priv, "Destroying tx ring, qpn: %d\n", ring->qpn); buf_ring_free(ring->br, M_DEVBUF); if (ring->bf_enabled) mlx4_bf_free(mdev->dev, &ring->bf); mlx4_qp_remove(mdev->dev, &ring->qp); mlx4_qp_free(mdev->dev, &ring->qp); mlx4_qp_release_range(priv->mdev->dev, ring->qpn, 1); mlx4_en_unmap_buffer(&ring->wqres.buf); mlx4_free_hwq_res(mdev->dev, &ring->wqres, ring->buf_size); kfree(ring->bounce_buf); vfree(ring->tx_info); mtx_destroy(&ring->tx_lock.m); mtx_destroy(&ring->comp_lock.m); kfree(ring); *pring = NULL; } int mlx4_en_activate_tx_ring(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring *ring, int cq, int user_prio) { struct mlx4_en_dev *mdev = priv->mdev; int err; ring->cqn = cq; ring->prod = 0; ring->cons = 0xffffffff; ring->last_nr_txbb = 1; ring->poll_cnt = 0; ring->blocked = 0; memset(ring->tx_info, 0, ring->size * sizeof(struct mlx4_en_tx_info)); memset(ring->buf, 0, ring->buf_size); ring->qp_state = MLX4_QP_STATE_RST; ring->doorbell_qpn = ring->qp.qpn << 8; mlx4_en_fill_qp_context(priv, ring->size, ring->stride, 1, 0, ring->qpn, ring->cqn, user_prio, &ring->context); if (ring->bf_enabled) ring->context.usr_page = cpu_to_be32(ring->bf.uar->index); err = mlx4_qp_to_ready(mdev->dev, &ring->wqres.mtt, &ring->context, &ring->qp, &ring->qp_state); return err; } void mlx4_en_deactivate_tx_ring(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring *ring) { struct mlx4_en_dev *mdev = priv->mdev; mlx4_qp_modify(mdev->dev, NULL, ring->qp_state, MLX4_QP_STATE_RST, NULL, 0, 0, &ring->qp); } static void mlx4_en_stamp_wqe(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring *ring, int index, u8 owner) { struct mlx4_en_tx_info *tx_info = &ring->tx_info[index]; struct mlx4_en_tx_desc *tx_desc = ring->buf + index * TXBB_SIZE; void *end = ring->buf + ring->buf_size; __be32 *ptr = (__be32 *)tx_desc; __be32 stamp = cpu_to_be32(STAMP_VAL | (!!owner << STAMP_SHIFT)); int i; /* Optimize the common case when there are no wraparounds */ if (likely((void *)tx_desc + tx_info->nr_txbb * TXBB_SIZE <= end)) /* Stamp the freed descriptor */ for (i = 0; i < tx_info->nr_txbb * TXBB_SIZE; i += STAMP_STRIDE) { *ptr = stamp; ptr += STAMP_DWORDS; } else /* Stamp the freed descriptor */ for (i = 0; i < tx_info->nr_txbb * TXBB_SIZE; i += STAMP_STRIDE) { *ptr = stamp; ptr += STAMP_DWORDS; if ((void *)ptr >= end) { ptr = ring->buf; stamp ^= cpu_to_be32(0x80000000); } } } static u32 mlx4_en_free_tx_desc(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring *ring, int index, u8 owner, u64 timestamp) { struct mlx4_en_dev *mdev = priv->mdev; struct mlx4_en_tx_info *tx_info = &ring->tx_info[index]; struct mlx4_en_tx_desc *tx_desc = ring->buf + index * TXBB_SIZE; struct mlx4_wqe_data_seg *data = (void *) tx_desc + tx_info->data_offset; struct mbuf *mb = tx_info->mb; void *end = ring->buf + ring->buf_size; int frags = tx_info->nr_segs;; int i; /* Optimize the common case when there are no wraparounds */ if (likely((void *) tx_desc + tx_info->nr_txbb * TXBB_SIZE <= end)) { if (!tx_info->inl) { if (tx_info->linear) { dma_unmap_single(priv->ddev, (dma_addr_t) be64_to_cpu(data->addr), be32_to_cpu(data->byte_count), PCI_DMA_TODEVICE); ++data; } for (i = 0; i < frags; i++) { pci_unmap_single(mdev->pdev, (dma_addr_t) be64_to_cpu(data[i].addr), data[i].byte_count, PCI_DMA_TODEVICE); } } } else { if (!tx_info->inl) { if ((void *) data >= end) { data = ring->buf + ((void *)data - end); } if (tx_info->linear) { dma_unmap_single(priv->ddev, (dma_addr_t) be64_to_cpu(data->addr), be32_to_cpu(data->byte_count), PCI_DMA_TODEVICE); ++data; } for (i = 0; i < frags; i++) { /* Check for wraparound before unmapping */ if ((void *) data >= end) data = ring->buf; pci_unmap_single(mdev->pdev, (dma_addr_t) be64_to_cpu(data->addr), data->byte_count, PCI_DMA_TODEVICE); ++data; } } } /* Send a copy of the frame to the BPF listener */ if (priv->dev && priv->dev->if_bpf) ETHER_BPF_MTAP(priv->dev, mb); m_freem(mb); return tx_info->nr_txbb; } int mlx4_en_free_tx_buf(struct net_device *dev, struct mlx4_en_tx_ring *ring) { struct mlx4_en_priv *priv = netdev_priv(dev); int cnt = 0; /* Skip last polled descriptor */ ring->cons += ring->last_nr_txbb; en_dbg(DRV, priv, "Freeing Tx buf - cons:0x%x prod:0x%x\n", ring->cons, ring->prod); if ((u32) (ring->prod - ring->cons) > ring->size) { en_warn(priv, "Tx consumer passed producer!\n"); return 0; } while (ring->cons != ring->prod) { ring->last_nr_txbb = mlx4_en_free_tx_desc(priv, ring, ring->cons & ring->size_mask, !!(ring->cons & ring->size), 0); ring->cons += ring->last_nr_txbb; cnt++; } if (cnt) en_dbg(DRV, priv, "Freed %d uncompleted tx descriptors\n", cnt); return cnt; } static int mlx4_en_process_tx_cq(struct net_device *dev, struct mlx4_en_cq *cq) { struct mlx4_en_priv *priv = netdev_priv(dev); struct mlx4_cq *mcq = &cq->mcq; struct mlx4_en_tx_ring *ring = priv->tx_ring[cq->ring]; struct mlx4_cqe *cqe; u16 index; u16 new_index, ring_index, stamp_index; u32 txbbs_skipped = 0; u32 txbbs_stamp = 0; u32 cons_index = mcq->cons_index; int size = cq->size; u32 size_mask = ring->size_mask; struct mlx4_cqe *buf = cq->buf; u32 packets = 0; u32 bytes = 0; int factor = priv->cqe_factor; u64 timestamp = 0; int done = 0; if (!priv->port_up) return 0; index = cons_index & size_mask; cqe = &buf[(index << factor) + factor]; ring_index = ring->cons & size_mask; stamp_index = ring_index; /* Process all completed CQEs */ while (XNOR(cqe->owner_sr_opcode & MLX4_CQE_OWNER_MASK, cons_index & size)) { /* * make sure we read the CQE after we read the * ownership bit */ rmb(); if (unlikely((cqe->owner_sr_opcode & MLX4_CQE_OPCODE_MASK) == MLX4_CQE_OPCODE_ERROR)) { en_err(priv, "CQE completed in error - vendor syndrom: 0x%x syndrom: 0x%x\n", ((struct mlx4_err_cqe *)cqe)-> vendor_err_syndrome, ((struct mlx4_err_cqe *)cqe)->syndrome); } /* Skip over last polled CQE */ new_index = be16_to_cpu(cqe->wqe_index) & size_mask; do { txbbs_skipped += ring->last_nr_txbb; ring_index = (ring_index + ring->last_nr_txbb) & size_mask; /* free next descriptor */ ring->last_nr_txbb = mlx4_en_free_tx_desc( priv, ring, ring_index, !!((ring->cons + txbbs_skipped) & ring->size), timestamp); mlx4_en_stamp_wqe(priv, ring, stamp_index, !!((ring->cons + txbbs_stamp) & ring->size)); stamp_index = ring_index; txbbs_stamp = txbbs_skipped; packets++; bytes += ring->tx_info[ring_index].nr_bytes; } while (ring_index != new_index); ++cons_index; index = cons_index & size_mask; cqe = &buf[(index << factor) + factor]; } /* * To prevent CQ overflow we first update CQ consumer and only then * the ring consumer. */ mcq->cons_index = cons_index; mlx4_cq_set_ci(mcq); wmb(); ring->cons += txbbs_skipped; /* Wakeup Tx queue if it was stopped and ring is not full */ if (unlikely(ring->blocked) && (ring->prod - ring->cons) <= ring->full_size) { ring->blocked = 0; if (atomic_fetchadd_int(&priv->blocked, -1) == 1) atomic_clear_int(&dev->if_drv_flags ,IFF_DRV_OACTIVE); ring->wake_queue++; priv->port_stats.wake_queue++; } return done; } void mlx4_en_tx_irq(struct mlx4_cq *mcq) { struct mlx4_en_cq *cq = container_of(mcq, struct mlx4_en_cq, mcq); struct mlx4_en_priv *priv = netdev_priv(cq->dev); struct mlx4_en_tx_ring *ring = priv->tx_ring[cq->ring]; if (!spin_trylock(&ring->comp_lock)) return; mlx4_en_process_tx_cq(cq->dev, cq); mod_timer(&cq->timer, jiffies + 1); spin_unlock(&ring->comp_lock); } void mlx4_en_poll_tx_cq(unsigned long data) { struct mlx4_en_cq *cq = (struct mlx4_en_cq *) data; struct mlx4_en_priv *priv = netdev_priv(cq->dev); struct mlx4_en_tx_ring *ring = priv->tx_ring[cq->ring]; u32 inflight; INC_PERF_COUNTER(priv->pstats.tx_poll); if (!spin_trylock(&ring->comp_lock)) { mod_timer(&cq->timer, jiffies + MLX4_EN_TX_POLL_TIMEOUT); return; } mlx4_en_process_tx_cq(cq->dev, cq); inflight = (u32) (ring->prod - ring->cons - ring->last_nr_txbb); /* If there are still packets in flight and the timer has not already * been scheduled by the Tx routine then schedule it here to guarantee * completion processing of these packets */ if (inflight && priv->port_up) mod_timer(&cq->timer, jiffies + MLX4_EN_TX_POLL_TIMEOUT); spin_unlock(&ring->comp_lock); } static struct mlx4_en_tx_desc *mlx4_en_bounce_to_desc(struct mlx4_en_priv *priv, struct mlx4_en_tx_ring *ring, u32 index, unsigned int desc_size) { u32 copy = (ring->size - index) * TXBB_SIZE; int i; for (i = desc_size - copy - 4; i >= 0; i -= 4) { if ((i & (TXBB_SIZE - 1)) == 0) wmb(); *((u32 *) (ring->buf + i)) = *((u32 *) (ring->bounce_buf + copy + i)); } for (i = copy - 4; i >= 4 ; i -= 4) { if ((i & (TXBB_SIZE - 1)) == 0) wmb(); *((u32 *) (ring->buf + index * TXBB_SIZE + i)) = *((u32 *) (ring->bounce_buf + i)); } /* Return real descriptor location */ return ring->buf + index * TXBB_SIZE; } static inline void mlx4_en_xmit_poll(struct mlx4_en_priv *priv, int tx_ind) { struct mlx4_en_cq *cq = priv->tx_cq[tx_ind]; struct mlx4_en_tx_ring *ring = priv->tx_ring[tx_ind]; /* If we don't have a pending timer, set one up to catch our recent post in case the interface becomes idle */ if (!timer_pending(&cq->timer)) mod_timer(&cq->timer, jiffies + MLX4_EN_TX_POLL_TIMEOUT); /* Poll the CQ every mlx4_en_TX_MODER_POLL packets */ if ((++ring->poll_cnt & (MLX4_EN_TX_POLL_MODER - 1)) == 0) if (spin_trylock(&ring->comp_lock)) { mlx4_en_process_tx_cq(priv->dev, cq); spin_unlock(&ring->comp_lock); } } static int is_inline(struct mbuf *mb, int thold) { if (thold && mb->m_pkthdr.len <= thold && (mb->m_pkthdr.csum_flags & CSUM_TSO) == 0) return 1; return 0; } static int inline_size(struct mbuf *mb) { int len; len = mb->m_pkthdr.len; if (len + CTRL_SIZE + sizeof(struct mlx4_wqe_inline_seg) <= MLX4_INLINE_ALIGN) return ALIGN(len + CTRL_SIZE + sizeof(struct mlx4_wqe_inline_seg), 16); else return ALIGN(len + CTRL_SIZE + 2 * sizeof(struct mlx4_wqe_inline_seg), 16); } static int get_head_size(struct mbuf *mb) { struct ether_vlan_header *eh; struct tcphdr *th; struct ip *ip; int ip_hlen, tcp_hlen; struct ip6_hdr *ip6; uint16_t eth_type; int eth_hdr_len; eh = mtod(mb, struct ether_vlan_header *); if (mb->m_len < ETHER_HDR_LEN) return (0); if (eh->evl_encap_proto == htons(ETHERTYPE_VLAN)) { eth_type = ntohs(eh->evl_proto); eth_hdr_len = ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN; } else { eth_type = ntohs(eh->evl_encap_proto); eth_hdr_len = ETHER_HDR_LEN; } if (mb->m_len < eth_hdr_len) return (0); switch (eth_type) { case ETHERTYPE_IP: ip = (struct ip *)(mb->m_data + eth_hdr_len); if (mb->m_len < eth_hdr_len + sizeof(*ip)) return (0); if (ip->ip_p != IPPROTO_TCP) return (0); ip_hlen = ip->ip_hl << 2; eth_hdr_len += ip_hlen; break; case ETHERTYPE_IPV6: ip6 = (struct ip6_hdr *)(mb->m_data + eth_hdr_len); if (mb->m_len < eth_hdr_len + sizeof(*ip6)) return (0); if (ip6->ip6_nxt != IPPROTO_TCP) return (0); eth_hdr_len += sizeof(*ip6); break; default: return (0); } if (mb->m_len < eth_hdr_len + sizeof(*th)) return (0); th = (struct tcphdr *)(mb->m_data + eth_hdr_len); tcp_hlen = th->th_off << 2; eth_hdr_len += tcp_hlen; if (mb->m_len < eth_hdr_len) return (0); return (eth_hdr_len); } static int get_real_size(struct mbuf *mb, struct net_device *dev, int *p_n_segs, int *lso_header_size, int inl) { struct mbuf *m; int nr_segs = 0; for (m = mb; m != NULL; m = m->m_next) if (m->m_len) nr_segs++; if (mb->m_pkthdr.csum_flags & CSUM_TSO) { *lso_header_size = get_head_size(mb); if (*lso_header_size) { if (mb->m_len == *lso_header_size) nr_segs--; *p_n_segs = nr_segs; return CTRL_SIZE + nr_segs * DS_SIZE + ALIGN(*lso_header_size + 4, DS_SIZE); } } else *lso_header_size = 0; *p_n_segs = nr_segs; if (inl) return inline_size(mb); return (CTRL_SIZE + nr_segs * DS_SIZE); } static struct mbuf *mb_copy(struct mbuf *mb, int *offp, char *data, int len) { int bytes; int off; off = *offp; while (len) { bytes = min(mb->m_len - off, len); if (bytes) memcpy(data, mb->m_data + off, bytes); len -= bytes; data += bytes; off += bytes; if (off == mb->m_len) { off = 0; mb = mb->m_next; } } *offp = off; return (mb); } static void build_inline_wqe(struct mlx4_en_tx_desc *tx_desc, struct mbuf *mb, int real_size, u16 *vlan_tag, int tx_ind) { struct mlx4_wqe_inline_seg *inl = &tx_desc->inl; int spc = MLX4_INLINE_ALIGN - CTRL_SIZE - sizeof *inl; int len; int off; off = 0; len = mb->m_pkthdr.len; if (len <= spc) { inl->byte_count = cpu_to_be32(1 << 31 | (max_t(typeof(len), len, MIN_PKT_LEN))); mb_copy(mb, &off, (void *)(inl + 1), len); if (len < MIN_PKT_LEN) memset(((void *)(inl + 1)) + len, 0, MIN_PKT_LEN - len); } else { inl->byte_count = cpu_to_be32(1 << 31 | spc); mb = mb_copy(mb, &off, (void *)(inl + 1), spc); inl = (void *) (inl + 1) + spc; mb_copy(mb, &off, (void *)(inl + 1), len - spc); wmb(); inl->byte_count = cpu_to_be32(1 << 31 | (len - spc)); } tx_desc->ctrl.vlan_tag = cpu_to_be16(*vlan_tag); tx_desc->ctrl.ins_vlan = MLX4_WQE_CTRL_INS_VLAN * !!(*vlan_tag); tx_desc->ctrl.fence_size = (real_size / 16) & 0x3f; } static unsigned long hashrandom; static void hashrandom_init(void *arg) { hashrandom = random(); } SYSINIT(hashrandom_init, SI_SUB_KLD, SI_ORDER_SECOND, &hashrandom_init, NULL); u16 mlx4_en_select_queue(struct net_device *dev, struct mbuf *mb) { struct mlx4_en_priv *priv = netdev_priv(dev); u32 rings_p_up = priv->num_tx_rings_p_up; u32 vlan_tag = 0; u32 up = 0; u32 queue_index; /* Obtain VLAN information if present */ if (mb->m_flags & M_VLANTAG) { vlan_tag = mb->m_pkthdr.ether_vtag; up = (vlan_tag >> 13); } /* hash mbuf */ queue_index = mlx4_en_hashmbuf(MLX4_F_HASHL3 | MLX4_F_HASHL4, mb, hashrandom); return ((queue_index % rings_p_up) + (up * rings_p_up)); } static void mlx4_bf_copy(void __iomem *dst, unsigned long *src, unsigned bytecnt) { __iowrite64_copy(dst, src, bytecnt / 8); } static u64 mlx4_en_mac_to_u64(u8 *addr) { u64 mac = 0; int i; for (i = 0; i < ETHER_ADDR_LEN; i++) { mac <<= 8; mac |= addr[i]; } return mac; } static int mlx4_en_xmit(struct net_device *dev, int tx_ind, struct mbuf **mbp) { struct mlx4_en_priv *priv = netdev_priv(dev); struct mlx4_en_dev *mdev = priv->mdev; struct mlx4_en_tx_ring *ring; struct mlx4_en_cq *cq; struct mlx4_en_tx_desc *tx_desc; struct mlx4_wqe_data_seg *data; struct mlx4_en_tx_info *tx_info; struct mbuf *m; int nr_txbb; int nr_segs; int desc_size; int real_size; dma_addr_t dma; u32 index, bf_index, ring_size; __be32 op_own; u16 vlan_tag = 0; int i; int lso_header_size; bool bounce = false; bool inl = false; struct mbuf *mb; mb = *mbp; int defrag = 1; if (!priv->port_up) goto tx_drop; ring = priv->tx_ring[tx_ind]; ring_size = ring->size; inl = is_inline(mb, ring->inline_thold); retry: real_size = get_real_size(mb, dev, &nr_segs, &lso_header_size, inl); if (unlikely(!real_size)) goto tx_drop; /* Align descriptor to TXBB size */ desc_size = ALIGN(real_size, TXBB_SIZE); nr_txbb = desc_size / TXBB_SIZE; if (unlikely(nr_txbb > MAX_DESC_TXBBS)) { if (defrag) { mb = m_defrag(*mbp, M_NOWAIT); if (mb == NULL) { mb = *mbp; goto tx_drop; } *mbp = mb; defrag = 0; goto retry; } en_warn(priv, "Oversized header or SG list\n"); goto tx_drop; } /* Obtain VLAN information if present */ if (mb->m_flags & M_VLANTAG) { vlan_tag = mb->m_pkthdr.ether_vtag; } /* Check available TXBBs and 2K spare for prefetch * Even if netif_tx_stop_queue() will be called * driver will send current packet to ensure * that at least one completion will be issued after * stopping the queue */ if (unlikely((int)(ring->prod - ring->cons) > ring->full_size)) { /* every full Tx ring stops queue */ if (ring->blocked == 0) atomic_add_int(&priv->blocked, 1); /* Set HW-queue-is-full flag */ atomic_set_int(&dev->if_drv_flags, IFF_DRV_OACTIVE); ring->blocked = 1; priv->port_stats.queue_stopped++; ring->queue_stopped++; /* Use interrupts to find out when queue opened */ cq = priv->tx_cq[tx_ind]; mlx4_en_arm_cq(priv, cq); return EBUSY; } /* Track current inflight packets for performance analysis */ AVG_PERF_COUNTER(priv->pstats.inflight_avg, (u32) (ring->prod - ring->cons - 1)); /* Packet is good - grab an index and transmit it */ index = ring->prod & ring->size_mask; bf_index = ring->prod; /* See if we have enough space for whole descriptor TXBB for setting * SW ownership on next descriptor; if not, use a bounce buffer. */ if (likely(index + nr_txbb <= ring_size)) tx_desc = ring->buf + index * TXBB_SIZE; else { tx_desc = (struct mlx4_en_tx_desc *) ring->bounce_buf; bounce = true; } /* Save mb in tx_info ring */ tx_info = &ring->tx_info[index]; tx_info->mb = mb; tx_info->nr_txbb = nr_txbb; tx_info->nr_segs = nr_segs; if (lso_header_size) { memcpy(tx_desc->lso.header, mb->m_data, lso_header_size); data = ((void *)&tx_desc->lso + ALIGN(lso_header_size + 4, DS_SIZE)); /* lso header is part of m_data. * need to omit when mapping DMA */ mb->m_data += lso_header_size; mb->m_len -= lso_header_size; } else data = &tx_desc->data; /* valid only for none inline segments */ tx_info->data_offset = (void *)data - (void *)tx_desc; if (inl) { tx_info->inl = 1; } else { for (i = 0, m = mb; i < nr_segs; i++, m = m->m_next) { if (m->m_len == 0) { i--; continue; } dma = pci_map_single(mdev->dev->pdev, m->m_data, m->m_len, PCI_DMA_TODEVICE); data->addr = cpu_to_be64(dma); data->lkey = cpu_to_be32(mdev->mr.key); wmb(); data->byte_count = cpu_to_be32(m->m_len); data++; } if (lso_header_size) { mb->m_data -= lso_header_size; mb->m_len += lso_header_size; } tx_info->inl = 0; } /* Prepare ctrl segement apart opcode+ownership, which depends on * whether LSO is used */ tx_desc->ctrl.vlan_tag = cpu_to_be16(vlan_tag); tx_desc->ctrl.ins_vlan = MLX4_WQE_CTRL_INS_VLAN * !!vlan_tag; tx_desc->ctrl.fence_size = (real_size / 16) & 0x3f; tx_desc->ctrl.srcrb_flags = priv->ctrl_flags; if (mb->m_pkthdr.csum_flags & (CSUM_IP | CSUM_TSO | CSUM_TCP | CSUM_UDP | CSUM_TCP_IPV6 | CSUM_UDP_IPV6)) { if (mb->m_pkthdr.csum_flags & (CSUM_IP | CSUM_TSO)) tx_desc->ctrl.srcrb_flags |= cpu_to_be32(MLX4_WQE_CTRL_IP_CSUM); if (mb->m_pkthdr.csum_flags & (CSUM_TCP | CSUM_UDP | CSUM_UDP_IPV6 | CSUM_TCP_IPV6 | CSUM_TSO)) tx_desc->ctrl.srcrb_flags |= cpu_to_be32(MLX4_WQE_CTRL_TCP_UDP_CSUM); priv->port_stats.tx_chksum_offload++; ring->tx_csum++; } if (unlikely(priv->validate_loopback)) { /* Copy dst mac address to wqe */ struct ether_header *ethh; u64 mac; u32 mac_l, mac_h; ethh = mtod(mb, struct ether_header *); mac = mlx4_en_mac_to_u64(ethh->ether_dhost); if (mac) { mac_h = (u32) ((mac & 0xffff00000000ULL) >> 16); mac_l = (u32) (mac & 0xffffffff); tx_desc->ctrl.srcrb_flags |= cpu_to_be32(mac_h); tx_desc->ctrl.imm = cpu_to_be32(mac_l); } } /* Handle LSO (TSO) packets */ if (lso_header_size) { int segsz; /* Mark opcode as LSO */ op_own = cpu_to_be32(MLX4_OPCODE_LSO | (1 << 6)) | ((ring->prod & ring_size) ? cpu_to_be32(MLX4_EN_BIT_DESC_OWN) : 0); /* Fill in the LSO prefix */ tx_desc->lso.mss_hdr_size = cpu_to_be32( mb->m_pkthdr.tso_segsz << 16 | lso_header_size); priv->port_stats.tso_packets++; segsz = mb->m_pkthdr.tso_segsz; i = ((mb->m_pkthdr.len - lso_header_size + segsz - 1) / segsz); tx_info->nr_bytes= mb->m_pkthdr.len + (i - 1) * lso_header_size; ring->packets += i; } else { /* Normal (Non LSO) packet */ op_own = cpu_to_be32(MLX4_OPCODE_SEND) | ((ring->prod & ring_size) ? cpu_to_be32(MLX4_EN_BIT_DESC_OWN) : 0); tx_info->nr_bytes = max(mb->m_pkthdr.len, (unsigned int)ETHER_MIN_LEN - ETHER_CRC_LEN); ring->packets++; } ring->bytes += tx_info->nr_bytes; AVG_PERF_COUNTER(priv->pstats.tx_pktsz_avg, mb->m_pkthdr.len); if (tx_info->inl) { build_inline_wqe(tx_desc, mb, real_size, &vlan_tag, tx_ind); tx_info->inl = 1; } ring->prod += nr_txbb; /* If we used a bounce buffer then copy descriptor back into place */ if (unlikely(bounce)) tx_desc = mlx4_en_bounce_to_desc(priv, ring, index, desc_size); if (ring->bf_enabled && desc_size <= MAX_BF && !bounce && !vlan_tag) { *(__be32 *) (&tx_desc->ctrl.vlan_tag) |= cpu_to_be32(ring->doorbell_qpn); op_own |= htonl((bf_index & 0xffff) << 8); /* Ensure new descirptor hits memory * before setting ownership of this descriptor to HW */ wmb(); tx_desc->ctrl.owner_opcode = op_own; wmb(); mlx4_bf_copy(ring->bf.reg + ring->bf.offset, (unsigned long *) &tx_desc->ctrl, desc_size); wmb(); ring->bf.offset ^= ring->bf.buf_size; } else { /* Ensure new descirptor hits memory * before setting ownership of this descriptor to HW */ wmb(); tx_desc->ctrl.owner_opcode = op_own; wmb(); writel(cpu_to_be32(ring->doorbell_qpn), ring->bf.uar->map + MLX4_SEND_DOORBELL); } return 0; tx_drop: *mbp = NULL; m_freem(mb); return EINVAL; } static int mlx4_en_transmit_locked(struct ifnet *dev, int tx_ind, struct mbuf *m) { struct mlx4_en_priv *priv = netdev_priv(dev); struct mlx4_en_tx_ring *ring; struct mbuf *next; int enqueued, err = 0; ring = priv->tx_ring[tx_ind]; if ((dev->if_drv_flags & (IFF_DRV_RUNNING | IFF_DRV_OACTIVE)) != IFF_DRV_RUNNING || priv->port_up == 0) { if (m != NULL) err = drbr_enqueue(dev, ring->br, m); return (err); } enqueued = 0; if (m != NULL) { if ((err = drbr_enqueue(dev, ring->br, m)) != 0) return (err); } /* Process the queue */ while ((next = drbr_peek(dev, ring->br)) != NULL) { if ((err = mlx4_en_xmit(dev, tx_ind, &next)) != 0) { if (next == NULL) { drbr_advance(dev, ring->br); } else { drbr_putback(dev, ring->br, next); } break; } drbr_advance(dev, ring->br); enqueued++; if ((dev->if_drv_flags & IFF_DRV_RUNNING) == 0) break; } if (enqueued > 0) ring->watchdog_time = ticks; return (err); } void mlx4_en_tx_que(void *context, int pending) { struct mlx4_en_tx_ring *ring; struct mlx4_en_priv *priv; struct net_device *dev; struct mlx4_en_cq *cq; int tx_ind; cq = context; dev = cq->dev; priv = dev->if_softc; tx_ind = cq->ring; ring = priv->tx_ring[tx_ind]; if (dev->if_drv_flags & IFF_DRV_RUNNING) { mlx4_en_xmit_poll(priv, tx_ind); spin_lock(&ring->tx_lock); if (!drbr_empty(dev, ring->br)) mlx4_en_transmit_locked(dev, tx_ind, NULL); spin_unlock(&ring->tx_lock); } } int mlx4_en_transmit(struct ifnet *dev, struct mbuf *m) { struct mlx4_en_priv *priv = netdev_priv(dev); struct mlx4_en_tx_ring *ring; struct mlx4_en_cq *cq; int i = 0, err = 0; /* Which queue to use */ if ((m->m_flags & (M_FLOWID | M_VLANTAG)) == M_FLOWID) { i = m->m_pkthdr.flowid % (priv->tx_ring_num - 1); } else { i = mlx4_en_select_queue(dev, m); } ring = priv->tx_ring[i]; if (spin_trylock(&ring->tx_lock)) { err = mlx4_en_transmit_locked(dev, i, m); spin_unlock(&ring->tx_lock); /* Poll CQ here */ mlx4_en_xmit_poll(priv, i); } else { err = drbr_enqueue(dev, ring->br, m); cq = priv->tx_cq[i]; taskqueue_enqueue(cq->tq, &cq->cq_task); } return (err); } /* * Flush ring buffers. */ void mlx4_en_qflush(struct ifnet *dev) { struct mlx4_en_priv *priv = netdev_priv(dev); struct mlx4_en_tx_ring *ring; struct mbuf *m; for (int i = 0; i < priv->tx_ring_num; i++) { ring = priv->tx_ring[i]; spin_lock(&ring->tx_lock); while ((m = buf_ring_dequeue_sc(ring->br)) != NULL) m_freem(m); spin_unlock(&ring->tx_lock); } if_qflush(dev); }