[dpdk.git] / drivers / net / hns3 / hns3_rxtx.c

/* SPDX-License-Identifier: BSD-3-Clause
 * Copyright(c) 2018-2021 HiSilicon Limited.
 */

#include <rte_bus_pci.h>
#include <rte_common.h>
#include <rte_cycles.h>
#include <rte_geneve.h>
#include <rte_vxlan.h>
#include <ethdev_driver.h>
#include <rte_io.h>
#include <rte_net.h>
#include <rte_malloc.h>
#if defined(RTE_ARCH_ARM64) && defined(__ARM_FEATURE_SVE)
#include <rte_cpuflags.h>
#endif

#include "hns3_ethdev.h"
#include "hns3_rxtx.h"
#include "hns3_regs.h"
#include "hns3_logs.h"

#define HNS3_CFG_DESC_NUM(num)  ((num) / 8 - 1)
#define HNS3_RX_RING_PREFETCTH_MASK     3

static void
hns3_rx_queue_release_mbufs(struct hns3_rx_queue *rxq)
{
        uint16_t i;

        /* Note: Fake rx queue will not enter here */
        if (rxq->sw_ring == NULL)
                return;

        if (rxq->rx_rearm_nb == 0) {
                for (i = 0; i < rxq->nb_rx_desc; i++) {
                        if (rxq->sw_ring[i].mbuf != NULL) {
                                rte_pktmbuf_free_seg(rxq->sw_ring[i].mbuf);
                                rxq->sw_ring[i].mbuf = NULL;
                        }
                }
        } else {
                for (i = rxq->next_to_use;
                     i != rxq->rx_rearm_start;
                     i = (i + 1) % rxq->nb_rx_desc) {
                        if (rxq->sw_ring[i].mbuf != NULL) {
                                rte_pktmbuf_free_seg(rxq->sw_ring[i].mbuf);
                                rxq->sw_ring[i].mbuf = NULL;
                        }
                }
        }

        for (i = 0; i < rxq->bulk_mbuf_num; i++)
                rte_pktmbuf_free_seg(rxq->bulk_mbuf[i]);
        rxq->bulk_mbuf_num = 0;

        if (rxq->pkt_first_seg) {
                rte_pktmbuf_free(rxq->pkt_first_seg);
                rxq->pkt_first_seg = NULL;
        }
}

static void
hns3_tx_queue_release_mbufs(struct hns3_tx_queue *txq)
{
        uint16_t i;

        /* Note: Fake tx queue will not enter here */
        if (txq->sw_ring) {
                for (i = 0; i < txq->nb_tx_desc; i++) {
                        if (txq->sw_ring[i].mbuf) {
                                rte_pktmbuf_free_seg(txq->sw_ring[i].mbuf);
                                txq->sw_ring[i].mbuf = NULL;
                        }
                }
        }
}

static void
hns3_rx_queue_release(void *queue)
{
        struct hns3_rx_queue *rxq = queue;
        if (rxq) {
                hns3_rx_queue_release_mbufs(rxq);
                if (rxq->mz)
                        rte_memzone_free(rxq->mz);
                if (rxq->sw_ring)
                        rte_free(rxq->sw_ring);
                rte_free(rxq);
        }
}

static void
hns3_tx_queue_release(void *queue)
{
        struct hns3_tx_queue *txq = queue;
        if (txq) {
                hns3_tx_queue_release_mbufs(txq);
                if (txq->mz)
                        rte_memzone_free(txq->mz);
                if (txq->sw_ring)
                        rte_free(txq->sw_ring);
                if (txq->free)
                        rte_free(txq->free);
                rte_free(txq);
        }
}

void
hns3_dev_rx_queue_release(void *queue)
{
        struct hns3_rx_queue *rxq = queue;
        struct hns3_adapter *hns;

        if (rxq == NULL)
                return;

        hns = rxq->hns;
        rte_spinlock_lock(&hns->hw.lock);
        hns3_rx_queue_release(queue);
        rte_spinlock_unlock(&hns->hw.lock);
}

void
hns3_dev_tx_queue_release(void *queue)
{
        struct hns3_tx_queue *txq = queue;
        struct hns3_adapter *hns;

        if (txq == NULL)
                return;

        hns = txq->hns;
        rte_spinlock_lock(&hns->hw.lock);
        hns3_tx_queue_release(queue);
        rte_spinlock_unlock(&hns->hw.lock);
}

static void
hns3_fake_rx_queue_release(struct hns3_rx_queue *queue)
{
        struct hns3_rx_queue *rxq = queue;
        struct hns3_adapter *hns;
        struct hns3_hw *hw;
        uint16_t idx;

        if (rxq == NULL)
                return;

        hns = rxq->hns;
        hw = &hns->hw;
        idx = rxq->queue_id;
        if (hw->fkq_data.rx_queues[idx]) {
                hns3_rx_queue_release(hw->fkq_data.rx_queues[idx]);
                hw->fkq_data.rx_queues[idx] = NULL;
        }

        /* free fake rx queue arrays */
        if (idx == (hw->fkq_data.nb_fake_rx_queues - 1)) {
                hw->fkq_data.nb_fake_rx_queues = 0;
                rte_free(hw->fkq_data.rx_queues);
                hw->fkq_data.rx_queues = NULL;
        }
}

static void
hns3_fake_tx_queue_release(struct hns3_tx_queue *queue)
{
        struct hns3_tx_queue *txq = queue;
        struct hns3_adapter *hns;
        struct hns3_hw *hw;
        uint16_t idx;

        if (txq == NULL)
                return;

        hns = txq->hns;
        hw = &hns->hw;
        idx = txq->queue_id;
        if (hw->fkq_data.tx_queues[idx]) {
                hns3_tx_queue_release(hw->fkq_data.tx_queues[idx]);
                hw->fkq_data.tx_queues[idx] = NULL;
        }

        /* free fake tx queue arrays */
        if (idx == (hw->fkq_data.nb_fake_tx_queues - 1)) {
                hw->fkq_data.nb_fake_tx_queues = 0;
                rte_free(hw->fkq_data.tx_queues);
                hw->fkq_data.tx_queues = NULL;
        }
}

static void
hns3_free_rx_queues(struct rte_eth_dev *dev)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_fake_queue_data *fkq_data;
        struct hns3_hw *hw = &hns->hw;
        uint16_t nb_rx_q;
        uint16_t i;

        nb_rx_q = hw->data->nb_rx_queues;
        for (i = 0; i < nb_rx_q; i++) {
                if (dev->data->rx_queues[i]) {
                        hns3_rx_queue_release(dev->data->rx_queues[i]);
                        dev->data->rx_queues[i] = NULL;
                }
        }

        /* Free fake Rx queues */
        fkq_data = &hw->fkq_data;
        for (i = 0; i < fkq_data->nb_fake_rx_queues; i++) {
                if (fkq_data->rx_queues[i])
                        hns3_fake_rx_queue_release(fkq_data->rx_queues[i]);
        }
}

static void
hns3_free_tx_queues(struct rte_eth_dev *dev)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_fake_queue_data *fkq_data;
        struct hns3_hw *hw = &hns->hw;
        uint16_t nb_tx_q;
        uint16_t i;

        nb_tx_q = hw->data->nb_tx_queues;
        for (i = 0; i < nb_tx_q; i++) {
                if (dev->data->tx_queues[i]) {
                        hns3_tx_queue_release(dev->data->tx_queues[i]);
                        dev->data->tx_queues[i] = NULL;
                }
        }

        /* Free fake Tx queues */
        fkq_data = &hw->fkq_data;
        for (i = 0; i < fkq_data->nb_fake_tx_queues; i++) {
                if (fkq_data->tx_queues[i])
                        hns3_fake_tx_queue_release(fkq_data->tx_queues[i]);
        }
}

void
hns3_free_all_queues(struct rte_eth_dev *dev)
{
        hns3_free_rx_queues(dev);
        hns3_free_tx_queues(dev);
}

static int
hns3_alloc_rx_queue_mbufs(struct hns3_hw *hw, struct hns3_rx_queue *rxq)
{
        struct rte_mbuf *mbuf;
        uint64_t dma_addr;
        uint16_t i;

        for (i = 0; i < rxq->nb_rx_desc; i++) {
                mbuf = rte_mbuf_raw_alloc(rxq->mb_pool);
                if (unlikely(mbuf == NULL)) {
                        hns3_err(hw, "Failed to allocate RXD[%u] for rx queue!",
                                 i);
                        hns3_rx_queue_release_mbufs(rxq);
                        return -ENOMEM;
                }

                rte_mbuf_refcnt_set(mbuf, 1);
                mbuf->next = NULL;
                mbuf->data_off = RTE_PKTMBUF_HEADROOM;
                mbuf->nb_segs = 1;
                mbuf->port = rxq->port_id;

                rxq->sw_ring[i].mbuf = mbuf;
                dma_addr = rte_cpu_to_le_64(rte_mbuf_data_iova_default(mbuf));
                rxq->rx_ring[i].addr = dma_addr;
                rxq->rx_ring[i].rx.bd_base_info = 0;
        }

        return 0;
}

static int
hns3_buf_size2type(uint32_t buf_size)
{
        int bd_size_type;

        switch (buf_size) {
        case 512:
                bd_size_type = HNS3_BD_SIZE_512_TYPE;
                break;
        case 1024:
                bd_size_type = HNS3_BD_SIZE_1024_TYPE;
                break;
        case 4096:
                bd_size_type = HNS3_BD_SIZE_4096_TYPE;
                break;
        default:
                bd_size_type = HNS3_BD_SIZE_2048_TYPE;
        }

        return bd_size_type;
}

static void
hns3_init_rx_queue_hw(struct hns3_rx_queue *rxq)
{
        uint32_t rx_buf_len = rxq->rx_buf_len;
        uint64_t dma_addr = rxq->rx_ring_phys_addr;

        hns3_write_dev(rxq, HNS3_RING_RX_BASEADDR_L_REG, (uint32_t)dma_addr);
        hns3_write_dev(rxq, HNS3_RING_RX_BASEADDR_H_REG,
                       (uint32_t)((dma_addr >> 31) >> 1));

        hns3_write_dev(rxq, HNS3_RING_RX_BD_LEN_REG,
                       hns3_buf_size2type(rx_buf_len));
        hns3_write_dev(rxq, HNS3_RING_RX_BD_NUM_REG,
                       HNS3_CFG_DESC_NUM(rxq->nb_rx_desc));
}

static void
hns3_init_tx_queue_hw(struct hns3_tx_queue *txq)
{
        uint64_t dma_addr = txq->tx_ring_phys_addr;

        hns3_write_dev(txq, HNS3_RING_TX_BASEADDR_L_REG, (uint32_t)dma_addr);
        hns3_write_dev(txq, HNS3_RING_TX_BASEADDR_H_REG,
                       (uint32_t)((dma_addr >> 31) >> 1));

        hns3_write_dev(txq, HNS3_RING_TX_BD_NUM_REG,
                       HNS3_CFG_DESC_NUM(txq->nb_tx_desc));
}

void
hns3_update_all_queues_pvid_proc_en(struct hns3_hw *hw)
{
        uint16_t nb_rx_q = hw->data->nb_rx_queues;
        uint16_t nb_tx_q = hw->data->nb_tx_queues;
        struct hns3_rx_queue *rxq;
        struct hns3_tx_queue *txq;
        bool pvid_en;
        int i;

        pvid_en = hw->port_base_vlan_cfg.state == HNS3_PORT_BASE_VLAN_ENABLE;
        for (i = 0; i < hw->cfg_max_queues; i++) {
                if (i < nb_rx_q) {
                        rxq = hw->data->rx_queues[i];
                        if (rxq != NULL)
                                rxq->pvid_sw_discard_en = pvid_en;
                }
                if (i < nb_tx_q) {
                        txq = hw->data->tx_queues[i];
                        if (txq != NULL)
                                txq->pvid_sw_shift_en = pvid_en;
                }
        }
}

static void
hns3_stop_unused_queue(void *tqp_base, enum hns3_ring_type queue_type)
{
        uint32_t reg_offset;
        uint32_t reg;

        reg_offset = queue_type == HNS3_RING_TYPE_TX ?
                                   HNS3_RING_TX_EN_REG : HNS3_RING_RX_EN_REG;
        reg = hns3_read_reg(tqp_base, reg_offset);
        reg &= ~BIT(HNS3_RING_EN_B);
        hns3_write_reg(tqp_base, reg_offset, reg);
}

void
hns3_enable_all_queues(struct hns3_hw *hw, bool en)
{
        uint16_t nb_rx_q = hw->data->nb_rx_queues;
        uint16_t nb_tx_q = hw->data->nb_tx_queues;
        struct hns3_rx_queue *rxq;
        struct hns3_tx_queue *txq;
        uint32_t rcb_reg;
        void *tqp_base;
        int i;

        for (i = 0; i < hw->cfg_max_queues; i++) {
                if (hns3_dev_indep_txrx_supported(hw)) {
                        rxq = i < nb_rx_q ? hw->data->rx_queues[i] : NULL;
                        txq = i < nb_tx_q ? hw->data->tx_queues[i] : NULL;

                        tqp_base = (void *)((char *)hw->io_base +
                                        hns3_get_tqp_reg_offset(i));
                        /*
                         * If queue struct is not initialized, it means the
                         * related HW ring has not been initialized yet.
                         * So, these queues should be disabled before enable
                         * the tqps to avoid a HW exception since the queues
                         * are enabled by default.
                         */
                        if (rxq == NULL)
                                hns3_stop_unused_queue(tqp_base,
                                                        HNS3_RING_TYPE_RX);
                        if (txq == NULL)
                                hns3_stop_unused_queue(tqp_base,
                                                        HNS3_RING_TYPE_TX);
                } else {
                        rxq = i < nb_rx_q ? hw->data->rx_queues[i] :
                              hw->fkq_data.rx_queues[i - nb_rx_q];

                        tqp_base = rxq->io_base;
                }
                /*
                 * This is the master switch that used to control the enabling
                 * of a pair of Tx and Rx queues. Both the Rx and Tx point to
                 * the same register
                 */
                rcb_reg = hns3_read_reg(tqp_base, HNS3_RING_EN_REG);
                if (en)
                        rcb_reg |= BIT(HNS3_RING_EN_B);
                else
                        rcb_reg &= ~BIT(HNS3_RING_EN_B);
                hns3_write_reg(tqp_base, HNS3_RING_EN_REG, rcb_reg);
        }
}

static void
hns3_enable_txq(struct hns3_tx_queue *txq, bool en)
{
        struct hns3_hw *hw = &txq->hns->hw;
        uint32_t reg;

        if (hns3_dev_indep_txrx_supported(hw)) {
                reg = hns3_read_dev(txq, HNS3_RING_TX_EN_REG);
                if (en)
                        reg |= BIT(HNS3_RING_EN_B);
                else
                        reg &= ~BIT(HNS3_RING_EN_B);
                hns3_write_dev(txq, HNS3_RING_TX_EN_REG, reg);
        }
        txq->enabled = en;
}

static void
hns3_enable_rxq(struct hns3_rx_queue *rxq, bool en)
{
        struct hns3_hw *hw = &rxq->hns->hw;
        uint32_t reg;

        if (hns3_dev_indep_txrx_supported(hw)) {
                reg = hns3_read_dev(rxq, HNS3_RING_RX_EN_REG);
                if (en)
                        reg |= BIT(HNS3_RING_EN_B);
                else
                        reg &= ~BIT(HNS3_RING_EN_B);
                hns3_write_dev(rxq, HNS3_RING_RX_EN_REG, reg);
        }
        rxq->enabled = en;
}

int
hns3_start_all_txqs(struct rte_eth_dev *dev)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_tx_queue *txq;
        uint16_t i, j;

        for (i = 0; i < dev->data->nb_tx_queues; i++) {
                txq = hw->data->tx_queues[i];
                if (!txq) {
                        hns3_err(hw, "Tx queue %u not available or setup.", i);
                        goto start_txqs_fail;
                }
                /*
                 * Tx queue is enabled by default. Therefore, the Tx queues
                 * needs to be disabled when deferred_start is set. There is
                 * another master switch used to control the enabling of a pair
                 * of Tx and Rx queues. And the master switch is disabled by
                 * default.
                 */
                if (txq->tx_deferred_start)
                        hns3_enable_txq(txq, false);
                else
                        hns3_enable_txq(txq, true);
        }
        return 0;

start_txqs_fail:
        for (j = 0; j < i; j++) {
                txq = hw->data->tx_queues[j];
                hns3_enable_txq(txq, false);
        }
        return -EINVAL;
}

int
hns3_start_all_rxqs(struct rte_eth_dev *dev)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_rx_queue *rxq;
        uint16_t i, j;

        for (i = 0; i < dev->data->nb_rx_queues; i++) {
                rxq = hw->data->rx_queues[i];
                if (!rxq) {
                        hns3_err(hw, "Rx queue %u not available or setup.", i);
                        goto start_rxqs_fail;
                }
                /*
                 * Rx queue is enabled by default. Therefore, the Rx queues
                 * needs to be disabled when deferred_start is set. There is
                 * another master switch used to control the enabling of a pair
                 * of Tx and Rx queues. And the master switch is disabled by
                 * default.
                 */
                if (rxq->rx_deferred_start)
                        hns3_enable_rxq(rxq, false);
                else
                        hns3_enable_rxq(rxq, true);
        }
        return 0;

start_rxqs_fail:
        for (j = 0; j < i; j++) {
                rxq = hw->data->rx_queues[j];
                hns3_enable_rxq(rxq, false);
        }
        return -EINVAL;
}

void
hns3_restore_tqp_enable_state(struct hns3_hw *hw)
{
        struct hns3_rx_queue *rxq;
        struct hns3_tx_queue *txq;
        uint16_t i;

        for (i = 0; i < hw->data->nb_rx_queues; i++) {
                rxq = hw->data->rx_queues[i];
                if (rxq != NULL)
                        hns3_enable_rxq(rxq, rxq->enabled);
        }

        for (i = 0; i < hw->data->nb_tx_queues; i++) {
                txq = hw->data->tx_queues[i];
                if (txq != NULL)
                        hns3_enable_txq(txq, txq->enabled);
        }
}

void
hns3_stop_all_txqs(struct rte_eth_dev *dev)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_tx_queue *txq;
        uint16_t i;

        for (i = 0; i < dev->data->nb_tx_queues; i++) {
                txq = hw->data->tx_queues[i];
                if (!txq)
                        continue;
                hns3_enable_txq(txq, false);
        }
}

static int
hns3_tqp_enable(struct hns3_hw *hw, uint16_t queue_id, bool enable)
{
        struct hns3_cfg_com_tqp_queue_cmd *req;
        struct hns3_cmd_desc desc;
        int ret;

        req = (struct hns3_cfg_com_tqp_queue_cmd *)desc.data;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_CFG_COM_TQP_QUEUE, false);
        req->tqp_id = rte_cpu_to_le_16(queue_id);
        req->stream_id = 0;
        hns3_set_bit(req->enable, HNS3_TQP_ENABLE_B, enable ? 1 : 0);

        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret)
                hns3_err(hw, "TQP enable fail, ret = %d", ret);

        return ret;
}

static int
hns3_send_reset_tqp_cmd(struct hns3_hw *hw, uint16_t queue_id, bool enable)
{
        struct hns3_reset_tqp_queue_cmd *req;
        struct hns3_cmd_desc desc;
        int ret;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_RESET_TQP_QUEUE, false);

        req = (struct hns3_reset_tqp_queue_cmd *)desc.data;
        req->tqp_id = rte_cpu_to_le_16(queue_id);
        hns3_set_bit(req->reset_req, HNS3_TQP_RESET_B, enable ? 1 : 0);
        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret)
                hns3_err(hw, "send tqp reset cmd error, queue_id = %u, "
                             "ret = %d", queue_id, ret);

        return ret;
}

static int
hns3_get_tqp_reset_status(struct hns3_hw *hw, uint16_t queue_id,
                          uint8_t *reset_status)
{
        struct hns3_reset_tqp_queue_cmd *req;
        struct hns3_cmd_desc desc;
        int ret;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_RESET_TQP_QUEUE, true);

        req = (struct hns3_reset_tqp_queue_cmd *)desc.data;
        req->tqp_id = rte_cpu_to_le_16(queue_id);

        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret) {
                hns3_err(hw, "get tqp reset status error, queue_id = %u, "
                             "ret = %d.", queue_id, ret);
                return ret;
        }
        *reset_status = hns3_get_bit(req->ready_to_reset, HNS3_TQP_RESET_B);
        return ret;
}

static int
hns3pf_reset_tqp(struct hns3_hw *hw, uint16_t queue_id)
{
#define HNS3_TQP_RESET_TRY_MS   200
        uint16_t wait_time = 0;
        uint8_t reset_status;
        int ret;

        /*
         * In current version VF is not supported when PF is driven by DPDK
         * driver, all task queue pairs are mapped to PF function, so PF's queue
         * id is equals to the global queue id in PF range.
         */
        ret = hns3_send_reset_tqp_cmd(hw, queue_id, true);
        if (ret) {
                hns3_err(hw, "Send reset tqp cmd fail, ret = %d", ret);
                return ret;
        }

        do {
                /* Wait for tqp hw reset */
                rte_delay_ms(HNS3_POLL_RESPONE_MS);
                wait_time += HNS3_POLL_RESPONE_MS;
                ret = hns3_get_tqp_reset_status(hw, queue_id, &reset_status);
                if (ret)
                        goto tqp_reset_fail;

                if (reset_status)
                        break;
        } while (wait_time < HNS3_TQP_RESET_TRY_MS);

        if (!reset_status) {
                ret = -ETIMEDOUT;
                hns3_err(hw, "reset tqp timeout, queue_id = %u, ret = %d",
                             queue_id, ret);
                goto tqp_reset_fail;
        }

        ret = hns3_send_reset_tqp_cmd(hw, queue_id, false);
        if (ret)
                hns3_err(hw, "Deassert the soft reset fail, ret = %d", ret);

        return ret;

tqp_reset_fail:
        hns3_send_reset_tqp_cmd(hw, queue_id, false);
        return ret;
}

static int
hns3vf_reset_tqp(struct hns3_hw *hw, uint16_t queue_id)
{
        uint8_t msg_data[2];
        int ret;

        memcpy(msg_data, &queue_id, sizeof(uint16_t));

        ret = hns3_send_mbx_msg(hw, HNS3_MBX_QUEUE_RESET, 0, msg_data,
                                 sizeof(msg_data), true, NULL, 0);
        if (ret)
                hns3_err(hw, "fail to reset tqp, queue_id = %u, ret = %d.",
                         queue_id, ret);
        return ret;
}

static int
hns3_reset_rcb_cmd(struct hns3_hw *hw, uint8_t *reset_status)
{
        struct hns3_reset_cmd *req;
        struct hns3_cmd_desc desc;
        int ret;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_CFG_RST_TRIGGER, false);
        req = (struct hns3_reset_cmd *)desc.data;
        hns3_set_bit(req->mac_func_reset, HNS3_CFG_RESET_RCB_B, 1);

        /*
         * The start qid should be the global qid of the first tqp of the
         * function which should be reset in this port. Since our PF not
         * support take over of VFs, so we only need to reset function 0,
         * and its start qid is always 0.
         */
        req->fun_reset_rcb_vqid_start = rte_cpu_to_le_16(0);
        req->fun_reset_rcb_vqid_num = rte_cpu_to_le_16(hw->cfg_max_queues);

        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret) {
                hns3_err(hw, "fail to send rcb reset cmd, ret = %d.", ret);
                return ret;
        }

        *reset_status = req->fun_reset_rcb_return_status;
        return 0;
}

static int
hns3pf_reset_all_tqps(struct hns3_hw *hw)
{
#define HNS3_RESET_RCB_NOT_SUPPORT      0U
#define HNS3_RESET_ALL_TQP_SUCCESS      1U
        uint8_t reset_status;
        int ret;
        int i;

        ret = hns3_reset_rcb_cmd(hw, &reset_status);
        if (ret)
                return ret;

        /*
         * If the firmware version is low, it may not support the rcb reset
         * which means reset all the tqps at a time. In this case, we should
         * reset tqps one by one.
         */
        if (reset_status == HNS3_RESET_RCB_NOT_SUPPORT) {
                for (i = 0; i < hw->cfg_max_queues; i++) {
                        ret = hns3pf_reset_tqp(hw, i);
                        if (ret) {
                                hns3_err(hw,
                                  "fail to reset tqp, queue_id = %d, ret = %d.",
                                  i, ret);
                                return ret;
                        }
                }
        } else if (reset_status != HNS3_RESET_ALL_TQP_SUCCESS) {
                hns3_err(hw, "fail to reset all tqps, reset_status = %u.",
                                reset_status);
                return -EIO;
        }

        return 0;
}

static int
hns3vf_reset_all_tqps(struct hns3_hw *hw)
{
#define HNS3VF_RESET_ALL_TQP_DONE       1U
        uint8_t reset_status;
        uint8_t msg_data[2];
        int ret;
        int i;

        memset(msg_data, 0, sizeof(uint16_t));
        ret = hns3_send_mbx_msg(hw, HNS3_MBX_QUEUE_RESET, 0, msg_data,
                                sizeof(msg_data), true, &reset_status,
                                sizeof(reset_status));
        if (ret) {
                hns3_err(hw, "fail to send rcb reset mbx, ret = %d.", ret);
                return ret;
        }

        if (reset_status == HNS3VF_RESET_ALL_TQP_DONE)
                return 0;

        /*
         * If the firmware version or kernel PF version is low, it may not
         * support the rcb reset which means reset all the tqps at a time.
         * In this case, we should reset tqps one by one.
         */
        for (i = 1; i < hw->cfg_max_queues; i++) {
                ret = hns3vf_reset_tqp(hw, i);
                if (ret)
                        return ret;
        }

        return 0;
}

int
hns3_reset_all_tqps(struct hns3_adapter *hns)
{
        struct hns3_hw *hw = &hns->hw;
        int ret, i;

        /* Disable all queues before reset all queues */
        for (i = 0; i < hw->cfg_max_queues; i++) {
                ret = hns3_tqp_enable(hw, i, false);
                if (ret) {
                        hns3_err(hw,
                            "fail to disable tqps before tqps reset, ret = %d.",
                            ret);
                        return ret;
                }
        }

        if (hns->is_vf)
                return hns3vf_reset_all_tqps(hw);
        else
                return hns3pf_reset_all_tqps(hw);
}

static int
hns3_send_reset_queue_cmd(struct hns3_hw *hw, uint16_t queue_id,
                          enum hns3_ring_type queue_type, bool enable)
{
        struct hns3_reset_tqp_queue_cmd *req;
        struct hns3_cmd_desc desc;
        int queue_direction;
        int ret;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_RESET_TQP_QUEUE_INDEP, false);

        req = (struct hns3_reset_tqp_queue_cmd *)desc.data;
        req->tqp_id = rte_cpu_to_le_16(queue_id);
        queue_direction = queue_type == HNS3_RING_TYPE_TX ? 0 : 1;
        req->queue_direction = rte_cpu_to_le_16(queue_direction);
        hns3_set_bit(req->reset_req, HNS3_TQP_RESET_B, enable ? 1 : 0);

        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret)
                hns3_err(hw, "send queue reset cmd error, queue_id = %u, "
                         "queue_type = %s, ret = %d.", queue_id,
                         queue_type == HNS3_RING_TYPE_TX ? "Tx" : "Rx", ret);
        return ret;
}

static int
hns3_get_queue_reset_status(struct hns3_hw *hw, uint16_t queue_id,
                            enum hns3_ring_type queue_type,
                            uint8_t *reset_status)
{
        struct hns3_reset_tqp_queue_cmd *req;
        struct hns3_cmd_desc desc;
        int queue_direction;
        int ret;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_RESET_TQP_QUEUE_INDEP, true);

        req = (struct hns3_reset_tqp_queue_cmd *)desc.data;
        req->tqp_id = rte_cpu_to_le_16(queue_id);
        queue_direction = queue_type == HNS3_RING_TYPE_TX ? 0 : 1;
        req->queue_direction = rte_cpu_to_le_16(queue_direction);

        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret) {
                hns3_err(hw, "get queue reset status error, queue_id = %u "
                         "queue_type = %s, ret = %d.", queue_id,
                         queue_type == HNS3_RING_TYPE_TX ? "Tx" : "Rx", ret);
                return ret;
        }

        *reset_status = hns3_get_bit(req->ready_to_reset, HNS3_TQP_RESET_B);
        return  ret;
}

static int
hns3_reset_queue(struct hns3_hw *hw, uint16_t queue_id,
                 enum hns3_ring_type queue_type)
{
#define HNS3_QUEUE_RESET_TRY_MS 200
        struct hns3_tx_queue *txq;
        struct hns3_rx_queue *rxq;
        uint32_t reset_wait_times;
        uint32_t max_wait_times;
        uint8_t reset_status;
        int ret;

        if (queue_type == HNS3_RING_TYPE_TX) {
                txq = hw->data->tx_queues[queue_id];
                hns3_enable_txq(txq, false);
        } else {
                rxq = hw->data->rx_queues[queue_id];
                hns3_enable_rxq(rxq, false);
        }

        ret = hns3_send_reset_queue_cmd(hw, queue_id, queue_type, true);
        if (ret) {
                hns3_err(hw, "send reset queue cmd fail, ret = %d.", ret);
                return ret;
        }

        reset_wait_times = 0;
        max_wait_times = HNS3_QUEUE_RESET_TRY_MS / HNS3_POLL_RESPONE_MS;
        while (reset_wait_times < max_wait_times) {
                /* Wait for queue hw reset */
                rte_delay_ms(HNS3_POLL_RESPONE_MS);
                ret = hns3_get_queue_reset_status(hw, queue_id,
                                                queue_type, &reset_status);
                if (ret)
                        goto queue_reset_fail;

                if (reset_status)
                        break;
                reset_wait_times++;
        }

        if (!reset_status) {
                hns3_err(hw, "reset queue timeout, queue_id = %u, "
                             "queue_type = %s", queue_id,
                             queue_type == HNS3_RING_TYPE_TX ? "Tx" : "Rx");
                ret = -ETIMEDOUT;
                goto queue_reset_fail;
        }

        ret = hns3_send_reset_queue_cmd(hw, queue_id, queue_type, false);
        if (ret)
                hns3_err(hw, "deassert queue reset fail, ret = %d.", ret);

        return ret;

queue_reset_fail:
        hns3_send_reset_queue_cmd(hw, queue_id, queue_type, false);
        return ret;
}

uint32_t
hns3_get_tqp_intr_reg_offset(uint16_t tqp_intr_id)
{
        uint32_t reg_offset;

        /* Need an extend offset to config queues > 64 */
        if (tqp_intr_id < HNS3_MIN_EXT_TQP_INTR_ID)
                reg_offset = HNS3_TQP_INTR_REG_BASE +
                             tqp_intr_id * HNS3_TQP_INTR_LOW_ORDER_OFFSET;
        else
                reg_offset = HNS3_TQP_INTR_EXT_REG_BASE +
                             tqp_intr_id / HNS3_MIN_EXT_TQP_INTR_ID *
                             HNS3_TQP_INTR_HIGH_ORDER_OFFSET +
                             tqp_intr_id % HNS3_MIN_EXT_TQP_INTR_ID *
                             HNS3_TQP_INTR_LOW_ORDER_OFFSET;

        return reg_offset;
}

void
hns3_set_queue_intr_gl(struct hns3_hw *hw, uint16_t queue_id,
                       uint8_t gl_idx, uint16_t gl_value)
{
        uint32_t offset[] = {HNS3_TQP_INTR_GL0_REG,
                             HNS3_TQP_INTR_GL1_REG,
                             HNS3_TQP_INTR_GL2_REG};
        uint32_t addr, value;

        if (gl_idx >= RTE_DIM(offset) || gl_value > HNS3_TQP_INTR_GL_MAX)
                return;

        addr = offset[gl_idx] + hns3_get_tqp_intr_reg_offset(queue_id);
        if (hw->intr.gl_unit == HNS3_INTR_COALESCE_GL_UINT_1US)
                value = gl_value | HNS3_TQP_INTR_GL_UNIT_1US;
        else
                value = HNS3_GL_USEC_TO_REG(gl_value);

        hns3_write_dev(hw, addr, value);
}

void
hns3_set_queue_intr_rl(struct hns3_hw *hw, uint16_t queue_id, uint16_t rl_value)
{
        uint32_t addr, value;

        if (rl_value > HNS3_TQP_INTR_RL_MAX)
                return;

        addr = HNS3_TQP_INTR_RL_REG + hns3_get_tqp_intr_reg_offset(queue_id);
        value = HNS3_RL_USEC_TO_REG(rl_value);
        if (value > 0)
                value |= HNS3_TQP_INTR_RL_ENABLE_MASK;

        hns3_write_dev(hw, addr, value);
}

void
hns3_set_queue_intr_ql(struct hns3_hw *hw, uint16_t queue_id, uint16_t ql_value)
{
        uint32_t addr;

        /*
         * int_ql_max == 0 means the hardware does not support QL,
         * QL regs config is not permitted if QL is not supported,
         * here just return.
         */
        if (hw->intr.int_ql_max == HNS3_INTR_QL_NONE)
                return;

        addr = HNS3_TQP_INTR_TX_QL_REG + hns3_get_tqp_intr_reg_offset(queue_id);
        hns3_write_dev(hw, addr, ql_value);

        addr = HNS3_TQP_INTR_RX_QL_REG + hns3_get_tqp_intr_reg_offset(queue_id);
        hns3_write_dev(hw, addr, ql_value);
}

static void
hns3_queue_intr_enable(struct hns3_hw *hw, uint16_t queue_id, bool en)
{
        uint32_t addr, value;

        addr = HNS3_TQP_INTR_CTRL_REG + hns3_get_tqp_intr_reg_offset(queue_id);
        value = en ? 1 : 0;

        hns3_write_dev(hw, addr, value);
}

/*
 * Enable all rx queue interrupt when in interrupt rx mode.
 * This api was called before enable queue rx&tx (in normal start or reset
 * recover scenes), used to fix hardware rx queue interrupt enable was clear
 * when FLR.
 */
void
hns3_dev_all_rx_queue_intr_enable(struct hns3_hw *hw, bool en)
{
        struct rte_eth_dev *dev = &rte_eth_devices[hw->data->port_id];
        uint16_t nb_rx_q = hw->data->nb_rx_queues;
        int i;

        if (dev->data->dev_conf.intr_conf.rxq == 0)
                return;

        for (i = 0; i < nb_rx_q; i++)
                hns3_queue_intr_enable(hw, i, en);
}

int
hns3_dev_rx_queue_intr_enable(struct rte_eth_dev *dev, uint16_t queue_id)
{
        struct rte_pci_device *pci_dev = RTE_ETH_DEV_TO_PCI(dev);
        struct rte_intr_handle *intr_handle = &pci_dev->intr_handle;
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);

        if (dev->data->dev_conf.intr_conf.rxq == 0)
                return -ENOTSUP;

        hns3_queue_intr_enable(hw, queue_id, true);

        return rte_intr_ack(intr_handle);
}

int
hns3_dev_rx_queue_intr_disable(struct rte_eth_dev *dev, uint16_t queue_id)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);

        if (dev->data->dev_conf.intr_conf.rxq == 0)
                return -ENOTSUP;

        hns3_queue_intr_enable(hw, queue_id, false);

        return 0;
}

static int
hns3_init_rxq(struct hns3_adapter *hns, uint16_t idx)
{
        struct hns3_hw *hw = &hns->hw;
        struct hns3_rx_queue *rxq;
        int ret;

        PMD_INIT_FUNC_TRACE();

        rxq = (struct hns3_rx_queue *)hw->data->rx_queues[idx];
        ret = hns3_alloc_rx_queue_mbufs(hw, rxq);
        if (ret) {
                hns3_err(hw, "fail to alloc mbuf for Rx queue %u, ret = %d.",
                         idx, ret);
                return ret;
        }

        rxq->next_to_use = 0;
        rxq->rx_rearm_start = 0;
        rxq->rx_free_hold = 0;
        rxq->rx_rearm_nb = 0;
        rxq->pkt_first_seg = NULL;
        rxq->pkt_last_seg = NULL;
        hns3_init_rx_queue_hw(rxq);
        hns3_rxq_vec_setup(rxq);

        return 0;
}

static void
hns3_init_fake_rxq(struct hns3_adapter *hns, uint16_t idx)
{
        struct hns3_hw *hw = &hns->hw;
        struct hns3_rx_queue *rxq;

        rxq = (struct hns3_rx_queue *)hw->fkq_data.rx_queues[idx];
        rxq->next_to_use = 0;
        rxq->rx_free_hold = 0;
        rxq->rx_rearm_start = 0;
        rxq->rx_rearm_nb = 0;
        hns3_init_rx_queue_hw(rxq);
}

static void
hns3_init_txq(struct hns3_tx_queue *txq)
{
        struct hns3_desc *desc;
        int i;

        /* Clear tx bd */
        desc = txq->tx_ring;
        for (i = 0; i < txq->nb_tx_desc; i++) {
                desc->tx.tp_fe_sc_vld_ra_ri = 0;
                desc++;
        }

        txq->next_to_use = 0;
        txq->next_to_clean = 0;
        txq->tx_bd_ready = txq->nb_tx_desc - 1;
        hns3_init_tx_queue_hw(txq);
}

static void
hns3_init_tx_ring_tc(struct hns3_adapter *hns)
{
        struct hns3_hw *hw = &hns->hw;
        struct hns3_tx_queue *txq;
        int i, num;

        for (i = 0; i < HNS3_MAX_TC_NUM; i++) {
                struct hns3_tc_queue_info *tc_queue = &hw->tc_queue[i];
                int j;

                if (!tc_queue->enable)
                        continue;

                for (j = 0; j < tc_queue->tqp_count; j++) {
                        num = tc_queue->tqp_offset + j;
                        txq = (struct hns3_tx_queue *)hw->data->tx_queues[num];
                        if (txq == NULL)
                                continue;

                        hns3_write_dev(txq, HNS3_RING_TX_TC_REG, tc_queue->tc);
                }
        }
}

static int
hns3_init_rx_queues(struct hns3_adapter *hns)
{
        struct hns3_hw *hw = &hns->hw;
        struct hns3_rx_queue *rxq;
        uint16_t i, j;
        int ret;

        /* Initialize RSS for queues */
        ret = hns3_config_rss(hns);
        if (ret) {
                hns3_err(hw, "failed to configure rss, ret = %d.", ret);
                return ret;
        }

        for (i = 0; i < hw->data->nb_rx_queues; i++) {
                rxq = (struct hns3_rx_queue *)hw->data->rx_queues[i];
                if (!rxq) {
                        hns3_err(hw, "Rx queue %u not available or setup.", i);
                        goto out;
                }

                if (rxq->rx_deferred_start)
                        continue;

                ret = hns3_init_rxq(hns, i);
                if (ret) {
                        hns3_err(hw, "failed to init Rx queue %u, ret = %d.", i,
                                 ret);
                        goto out;
                }
        }

        for (i = 0; i < hw->fkq_data.nb_fake_rx_queues; i++)
                hns3_init_fake_rxq(hns, i);

        return 0;

out:
        for (j = 0; j < i; j++) {
                rxq = (struct hns3_rx_queue *)hw->data->rx_queues[j];
                hns3_rx_queue_release_mbufs(rxq);
        }

        return ret;
}

static int
hns3_init_tx_queues(struct hns3_adapter *hns)
{
        struct hns3_hw *hw = &hns->hw;
        struct hns3_tx_queue *txq;
        uint16_t i;

        for (i = 0; i < hw->data->nb_tx_queues; i++) {
                txq = (struct hns3_tx_queue *)hw->data->tx_queues[i];
                if (!txq) {
                        hns3_err(hw, "Tx queue %u not available or setup.", i);
                        return -EINVAL;
                }

                if (txq->tx_deferred_start)
                        continue;
                hns3_init_txq(txq);
        }

        for (i = 0; i < hw->fkq_data.nb_fake_tx_queues; i++) {
                txq = (struct hns3_tx_queue *)hw->fkq_data.tx_queues[i];
                hns3_init_txq(txq);
        }
        hns3_init_tx_ring_tc(hns);

        return 0;
}

/*
 * Init all queues.
 * Note: just init and setup queues, and don't enable tqps.
 */
int
hns3_init_queues(struct hns3_adapter *hns, bool reset_queue)
{
        struct hns3_hw *hw = &hns->hw;
        int ret;

        if (reset_queue) {
                ret = hns3_reset_all_tqps(hns);
                if (ret) {
                        hns3_err(hw, "failed to reset all queues, ret = %d.",
                                 ret);
                        return ret;
                }
        }

        ret = hns3_init_rx_queues(hns);
        if (ret) {
                hns3_err(hw, "failed to init rx queues, ret = %d.", ret);
                return ret;
        }

        ret = hns3_init_tx_queues(hns);
        if (ret) {
                hns3_dev_release_mbufs(hns);
                hns3_err(hw, "failed to init tx queues, ret = %d.", ret);
        }

        return ret;
}

void
hns3_start_tqps(struct hns3_hw *hw)
{
        struct hns3_tx_queue *txq;
        struct hns3_rx_queue *rxq;
        uint16_t i;

        hns3_enable_all_queues(hw, true);

        for (i = 0; i < hw->data->nb_tx_queues; i++) {
                txq = hw->data->tx_queues[i];
                if (txq->enabled)
                        hw->data->tx_queue_state[i] =
                                RTE_ETH_QUEUE_STATE_STARTED;
        }

        for (i = 0; i < hw->data->nb_rx_queues; i++) {
                rxq = hw->data->rx_queues[i];
                if (rxq->enabled)
                        hw->data->rx_queue_state[i] =
                                RTE_ETH_QUEUE_STATE_STARTED;
        }
}

void
hns3_stop_tqps(struct hns3_hw *hw)
{
        uint16_t i;

        hns3_enable_all_queues(hw, false);

        for (i = 0; i < hw->data->nb_tx_queues; i++)
                hw->data->tx_queue_state[i] = RTE_ETH_QUEUE_STATE_STOPPED;

        for (i = 0; i < hw->data->nb_rx_queues; i++)
                hw->data->rx_queue_state[i] = RTE_ETH_QUEUE_STATE_STOPPED;
}

/*
 * Iterate over all Rx Queue, and call the callback() function for each Rx
 * queue.
 *
 * @param[in] dev
 *   The target eth dev.
 * @param[in] callback
 *   The function to call for each queue.
 *   if callback function return nonzero will stop iterate and return it's value
 * @param[in] arg
 *   The arguments to provide the callback function with.
 *
 * @return
 *   0 on success, otherwise with errno set.
 */
int
hns3_rxq_iterate(struct rte_eth_dev *dev,
                 int (*callback)(struct hns3_rx_queue *, void *), void *arg)
{
        uint32_t i;
        int ret;

        if (dev->data->rx_queues == NULL)
                return -EINVAL;

        for (i = 0; i < dev->data->nb_rx_queues; i++) {
                ret = callback(dev->data->rx_queues[i], arg);
                if (ret != 0)
                        return ret;
        }

        return 0;
}

static void*
hns3_alloc_rxq_and_dma_zone(struct rte_eth_dev *dev,
                            struct hns3_queue_info *q_info)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        const struct rte_memzone *rx_mz;
        struct hns3_rx_queue *rxq;
        unsigned int rx_desc;

        rxq = rte_zmalloc_socket(q_info->type, sizeof(struct hns3_rx_queue),
                                 RTE_CACHE_LINE_SIZE, q_info->socket_id);
        if (rxq == NULL) {
                hns3_err(hw, "Failed to allocate memory for No.%u rx ring!",
                         q_info->idx);
                return NULL;
        }

        /* Allocate rx ring hardware descriptors. */
        rxq->queue_id = q_info->idx;
        rxq->nb_rx_desc = q_info->nb_desc;

        /*
         * Allocate a litter more memory because rx vector functions
         * don't check boundaries each time.
         */
        rx_desc = (rxq->nb_rx_desc + HNS3_DEFAULT_RX_BURST) *
                        sizeof(struct hns3_desc);
        rx_mz = rte_eth_dma_zone_reserve(dev, q_info->ring_name, q_info->idx,
                                         rx_desc, HNS3_RING_BASE_ALIGN,
                                         q_info->socket_id);
        if (rx_mz == NULL) {
                hns3_err(hw, "Failed to reserve DMA memory for No.%u rx ring!",
                         q_info->idx);
                hns3_rx_queue_release(rxq);
                return NULL;
        }
        rxq->mz = rx_mz;
        rxq->rx_ring = (struct hns3_desc *)rx_mz->addr;
        rxq->rx_ring_phys_addr = rx_mz->iova;

        hns3_dbg(hw, "No.%u rx descriptors iova 0x%" PRIx64, q_info->idx,
                 rxq->rx_ring_phys_addr);

        return rxq;
}

static int
hns3_fake_rx_queue_setup(struct rte_eth_dev *dev, uint16_t idx,
                         uint16_t nb_desc, unsigned int socket_id)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_hw *hw = &hns->hw;
        struct hns3_queue_info q_info;
        struct hns3_rx_queue *rxq;
        uint16_t nb_rx_q;

        if (hw->fkq_data.rx_queues[idx]) {
                hns3_rx_queue_release(hw->fkq_data.rx_queues[idx]);
                hw->fkq_data.rx_queues[idx] = NULL;
        }

        q_info.idx = idx;
        q_info.socket_id = socket_id;
        q_info.nb_desc = nb_desc;
        q_info.type = "hns3 fake RX queue";
        q_info.ring_name = "rx_fake_ring";
        rxq = hns3_alloc_rxq_and_dma_zone(dev, &q_info);
        if (rxq == NULL) {
                hns3_err(hw, "Failed to setup No.%u fake rx ring.", idx);
                return -ENOMEM;
        }

        /* Don't need alloc sw_ring, because upper applications don't use it */
        rxq->sw_ring = NULL;

        rxq->hns = hns;
        rxq->rx_deferred_start = false;
        rxq->port_id = dev->data->port_id;
        rxq->configured = true;
        nb_rx_q = dev->data->nb_rx_queues;
        rxq->io_base = (void *)((char *)hw->io_base + HNS3_TQP_REG_OFFSET +
                                (nb_rx_q + idx) * HNS3_TQP_REG_SIZE);
        rxq->rx_buf_len = HNS3_MIN_BD_BUF_SIZE;

        rte_spinlock_lock(&hw->lock);
        hw->fkq_data.rx_queues[idx] = rxq;
        rte_spinlock_unlock(&hw->lock);

        return 0;
}

static void*
hns3_alloc_txq_and_dma_zone(struct rte_eth_dev *dev,
                            struct hns3_queue_info *q_info)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        const struct rte_memzone *tx_mz;
        struct hns3_tx_queue *txq;
        struct hns3_desc *desc;
        unsigned int tx_desc;
        int i;

        txq = rte_zmalloc_socket(q_info->type, sizeof(struct hns3_tx_queue),
                                 RTE_CACHE_LINE_SIZE, q_info->socket_id);
        if (txq == NULL) {
                hns3_err(hw, "Failed to allocate memory for No.%u tx ring!",
                         q_info->idx);
                return NULL;
        }

        /* Allocate tx ring hardware descriptors. */
        txq->queue_id = q_info->idx;
        txq->nb_tx_desc = q_info->nb_desc;
        tx_desc = txq->nb_tx_desc * sizeof(struct hns3_desc);
        tx_mz = rte_eth_dma_zone_reserve(dev, q_info->ring_name, q_info->idx,
                                         tx_desc, HNS3_RING_BASE_ALIGN,
                                         q_info->socket_id);
        if (tx_mz == NULL) {
                hns3_err(hw, "Failed to reserve DMA memory for No.%u tx ring!",
                         q_info->idx);
                hns3_tx_queue_release(txq);
                return NULL;
        }
        txq->mz = tx_mz;
        txq->tx_ring = (struct hns3_desc *)tx_mz->addr;
        txq->tx_ring_phys_addr = tx_mz->iova;

        hns3_dbg(hw, "No.%u tx descriptors iova 0x%" PRIx64, q_info->idx,
                 txq->tx_ring_phys_addr);

        /* Clear tx bd */
        desc = txq->tx_ring;
        for (i = 0; i < txq->nb_tx_desc; i++) {
                desc->tx.tp_fe_sc_vld_ra_ri = 0;
                desc++;
        }

        return txq;
}

static int
hns3_fake_tx_queue_setup(struct rte_eth_dev *dev, uint16_t idx,
                         uint16_t nb_desc, unsigned int socket_id)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_hw *hw = &hns->hw;
        struct hns3_queue_info q_info;
        struct hns3_tx_queue *txq;
        uint16_t nb_tx_q;

        if (hw->fkq_data.tx_queues[idx] != NULL) {
                hns3_tx_queue_release(hw->fkq_data.tx_queues[idx]);
                hw->fkq_data.tx_queues[idx] = NULL;
        }

        q_info.idx = idx;
        q_info.socket_id = socket_id;
        q_info.nb_desc = nb_desc;
        q_info.type = "hns3 fake TX queue";
        q_info.ring_name = "tx_fake_ring";
        txq = hns3_alloc_txq_and_dma_zone(dev, &q_info);
        if (txq == NULL) {
                hns3_err(hw, "Failed to setup No.%u fake tx ring.", idx);
                return -ENOMEM;
        }

        /* Don't need alloc sw_ring, because upper applications don't use it */
        txq->sw_ring = NULL;
        txq->free = NULL;

        txq->hns = hns;
        txq->tx_deferred_start = false;
        txq->port_id = dev->data->port_id;
        txq->configured = true;
        nb_tx_q = dev->data->nb_tx_queues;
        txq->io_base = (void *)((char *)hw->io_base + HNS3_TQP_REG_OFFSET +
                                (nb_tx_q + idx) * HNS3_TQP_REG_SIZE);

        rte_spinlock_lock(&hw->lock);
        hw->fkq_data.tx_queues[idx] = txq;
        rte_spinlock_unlock(&hw->lock);

        return 0;
}

static int
hns3_fake_rx_queue_config(struct hns3_hw *hw, uint16_t nb_queues)
{
        uint16_t old_nb_queues = hw->fkq_data.nb_fake_rx_queues;
        void **rxq;
        uint16_t i;

        if (hw->fkq_data.rx_queues == NULL && nb_queues != 0) {
                /* first time configuration */
                uint32_t size;
                size = sizeof(hw->fkq_data.rx_queues[0]) * nb_queues;
                hw->fkq_data.rx_queues = rte_zmalloc("fake_rx_queues", size,
                                                     RTE_CACHE_LINE_SIZE);
                if (hw->fkq_data.rx_queues == NULL) {
                        hw->fkq_data.nb_fake_rx_queues = 0;
                        return -ENOMEM;
                }
        } else if (hw->fkq_data.rx_queues != NULL && nb_queues != 0) {
                /* re-configure */
                rxq = hw->fkq_data.rx_queues;
                for (i = nb_queues; i < old_nb_queues; i++)
                        hns3_dev_rx_queue_release(rxq[i]);

                rxq = rte_realloc(rxq, sizeof(rxq[0]) * nb_queues,
                                  RTE_CACHE_LINE_SIZE);
                if (rxq == NULL)
                        return -ENOMEM;
                if (nb_queues > old_nb_queues) {
                        uint16_t new_qs = nb_queues - old_nb_queues;
                        memset(rxq + old_nb_queues, 0, sizeof(rxq[0]) * new_qs);
                }

                hw->fkq_data.rx_queues = rxq;
        } else if (hw->fkq_data.rx_queues != NULL && nb_queues == 0) {
                rxq = hw->fkq_data.rx_queues;
                for (i = nb_queues; i < old_nb_queues; i++)
                        hns3_dev_rx_queue_release(rxq[i]);

                rte_free(hw->fkq_data.rx_queues);
                hw->fkq_data.rx_queues = NULL;
        }

        hw->fkq_data.nb_fake_rx_queues = nb_queues;

        return 0;
}

static int
hns3_fake_tx_queue_config(struct hns3_hw *hw, uint16_t nb_queues)
{
        uint16_t old_nb_queues = hw->fkq_data.nb_fake_tx_queues;
        void **txq;
        uint16_t i;

        if (hw->fkq_data.tx_queues == NULL && nb_queues != 0) {
                /* first time configuration */
                uint32_t size;
                size = sizeof(hw->fkq_data.tx_queues[0]) * nb_queues;
                hw->fkq_data.tx_queues = rte_zmalloc("fake_tx_queues", size,
                                                     RTE_CACHE_LINE_SIZE);
                if (hw->fkq_data.tx_queues == NULL) {
                        hw->fkq_data.nb_fake_tx_queues = 0;
                        return -ENOMEM;
                }
        } else if (hw->fkq_data.tx_queues != NULL && nb_queues != 0) {
                /* re-configure */
                txq = hw->fkq_data.tx_queues;
                for (i = nb_queues; i < old_nb_queues; i++)
                        hns3_dev_tx_queue_release(txq[i]);
                txq = rte_realloc(txq, sizeof(txq[0]) * nb_queues,
                                  RTE_CACHE_LINE_SIZE);
                if (txq == NULL)
                        return -ENOMEM;
                if (nb_queues > old_nb_queues) {
                        uint16_t new_qs = nb_queues - old_nb_queues;
                        memset(txq + old_nb_queues, 0, sizeof(txq[0]) * new_qs);
                }

                hw->fkq_data.tx_queues = txq;
        } else if (hw->fkq_data.tx_queues != NULL && nb_queues == 0) {
                txq = hw->fkq_data.tx_queues;
                for (i = nb_queues; i < old_nb_queues; i++)
                        hns3_dev_tx_queue_release(txq[i]);

                rte_free(hw->fkq_data.tx_queues);
                hw->fkq_data.tx_queues = NULL;
        }
        hw->fkq_data.nb_fake_tx_queues = nb_queues;

        return 0;
}

int
hns3_set_fake_rx_or_tx_queues(struct rte_eth_dev *dev, uint16_t nb_rx_q,
                              uint16_t nb_tx_q)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        uint16_t rx_need_add_nb_q;
        uint16_t tx_need_add_nb_q;
        uint16_t port_id;
        uint16_t q;
        int ret;

        /* Setup new number of fake RX/TX queues and reconfigure device. */
        rx_need_add_nb_q = hw->cfg_max_queues - nb_rx_q;
        tx_need_add_nb_q = hw->cfg_max_queues - nb_tx_q;
        ret = hns3_fake_rx_queue_config(hw, rx_need_add_nb_q);
        if (ret) {
                hns3_err(hw, "Fail to configure fake rx queues: %d", ret);
                return ret;
        }

        ret = hns3_fake_tx_queue_config(hw, tx_need_add_nb_q);
        if (ret) {
                hns3_err(hw, "Fail to configure fake rx queues: %d", ret);
                goto cfg_fake_tx_q_fail;
        }

        /* Allocate and set up fake RX queue per Ethernet port. */
        port_id = hw->data->port_id;
        for (q = 0; q < rx_need_add_nb_q; q++) {
                ret = hns3_fake_rx_queue_setup(dev, q, HNS3_MIN_RING_DESC,
                                               rte_eth_dev_socket_id(port_id));
                if (ret)
                        goto setup_fake_rx_q_fail;
        }

        /* Allocate and set up fake TX queue per Ethernet port. */
        for (q = 0; q < tx_need_add_nb_q; q++) {
                ret = hns3_fake_tx_queue_setup(dev, q, HNS3_MIN_RING_DESC,
                                               rte_eth_dev_socket_id(port_id));
                if (ret)
                        goto setup_fake_tx_q_fail;
        }

        return 0;

setup_fake_tx_q_fail:
setup_fake_rx_q_fail:
        (void)hns3_fake_tx_queue_config(hw, 0);
cfg_fake_tx_q_fail:
        (void)hns3_fake_rx_queue_config(hw, 0);

        return ret;
}

void
hns3_dev_release_mbufs(struct hns3_adapter *hns)
{
        struct rte_eth_dev_data *dev_data = hns->hw.data;
        struct hns3_rx_queue *rxq;
        struct hns3_tx_queue *txq;
        int i;

        if (dev_data->rx_queues)
                for (i = 0; i < dev_data->nb_rx_queues; i++) {
                        rxq = dev_data->rx_queues[i];
                        if (rxq == NULL)
                                continue;
                        hns3_rx_queue_release_mbufs(rxq);
                }

        if (dev_data->tx_queues)
                for (i = 0; i < dev_data->nb_tx_queues; i++) {
                        txq = dev_data->tx_queues[i];
                        if (txq == NULL)
                                continue;
                        hns3_tx_queue_release_mbufs(txq);
                }
}

static int
hns3_rx_buf_len_calc(struct rte_mempool *mp, uint16_t *rx_buf_len)
{
        uint16_t vld_buf_size;
        uint16_t num_hw_specs;
        uint16_t i;

        /*
         * hns3 network engine only support to set 4 typical specification, and
         * different buffer size will affect the max packet_len and the max
         * number of segmentation when hw gro is turned on in receive side. The
         * relationship between them is as follows:
         *      rx_buf_size     |  max_gro_pkt_len  |  max_gro_nb_seg
         * ---------------------|-------------------|----------------
         * HNS3_4K_BD_BUF_SIZE  |        60KB       |       15
         * HNS3_2K_BD_BUF_SIZE  |        62KB       |       31
         * HNS3_1K_BD_BUF_SIZE  |        63KB       |       63
         * HNS3_512_BD_BUF_SIZE |      31.5KB       |       63
         */
        static const uint16_t hw_rx_buf_size[] = {
                HNS3_4K_BD_BUF_SIZE,
                HNS3_2K_BD_BUF_SIZE,
                HNS3_1K_BD_BUF_SIZE,
                HNS3_512_BD_BUF_SIZE
        };

        vld_buf_size = (uint16_t)(rte_pktmbuf_data_room_size(mp) -
                        RTE_PKTMBUF_HEADROOM);
        if (vld_buf_size < HNS3_MIN_BD_BUF_SIZE)
                return -EINVAL;

        num_hw_specs = RTE_DIM(hw_rx_buf_size);
        for (i = 0; i < num_hw_specs; i++) {
                if (vld_buf_size >= hw_rx_buf_size[i]) {
                        *rx_buf_len = hw_rx_buf_size[i];
                        break;
                }
        }
        return 0;
}

static int
hns3_rxq_conf_runtime_check(struct hns3_hw *hw, uint16_t buf_size,
                                uint16_t nb_desc)
{
        struct rte_eth_dev *dev = &rte_eth_devices[hw->data->port_id];
        struct rte_eth_rxmode *rxmode = &hw->data->dev_conf.rxmode;
        eth_rx_burst_t pkt_burst = dev->rx_pkt_burst;
        uint16_t min_vec_bds;

        /*
         * HNS3 hardware network engine set scattered as default. If the driver
         * is not work in scattered mode and the pkts greater than buf_size
         * but smaller than max_rx_pkt_len will be distributed to multiple BDs.
         * Driver cannot handle this situation.
         */
        if (!hw->data->scattered_rx && rxmode->max_rx_pkt_len > buf_size) {
                hns3_err(hw, "max_rx_pkt_len is not allowed to be set greater "
                             "than rx_buf_len if scattered is off.");
                return -EINVAL;
        }

        if (pkt_burst == hns3_recv_pkts_vec) {
                min_vec_bds = HNS3_DEFAULT_RXQ_REARM_THRESH +
                              HNS3_DEFAULT_RX_BURST;
                if (nb_desc < min_vec_bds ||
                    nb_desc % HNS3_DEFAULT_RXQ_REARM_THRESH) {
                        hns3_err(hw, "if Rx burst mode is vector, "
                                 "number of descriptor is required to be "
                                 "bigger than min vector bds:%u, and could be "
                                 "divided by rxq rearm thresh:%u.",
                                 min_vec_bds, HNS3_DEFAULT_RXQ_REARM_THRESH);
                        return -EINVAL;
                }
        }
        return 0;
}

static int
hns3_rx_queue_conf_check(struct hns3_hw *hw, const struct rte_eth_rxconf *conf,
                         struct rte_mempool *mp, uint16_t nb_desc,
                         uint16_t *buf_size)
{
        int ret;

        if (nb_desc > HNS3_MAX_RING_DESC || nb_desc < HNS3_MIN_RING_DESC ||
            nb_desc % HNS3_ALIGN_RING_DESC) {
                hns3_err(hw, "Number (%u) of rx descriptors is invalid",
                         nb_desc);
                return -EINVAL;
        }

        if (conf->rx_drop_en == 0)
                hns3_warn(hw, "if no descriptors available, packets are always "
                          "dropped and rx_drop_en (1) is fixed on");

        if (hns3_rx_buf_len_calc(mp, buf_size)) {
                hns3_err(hw, "rxq mbufs' data room size (%u) is not enough! "
                                "minimal data room size (%u).",
                                rte_pktmbuf_data_room_size(mp),
                                HNS3_MIN_BD_BUF_SIZE + RTE_PKTMBUF_HEADROOM);
                return -EINVAL;
        }

        if (hw->data->dev_started) {
                ret = hns3_rxq_conf_runtime_check(hw, *buf_size, nb_desc);
                if (ret) {
                        hns3_err(hw, "Rx queue runtime setup fail.");
                        return ret;
                }
        }

        return 0;
}

uint32_t
hns3_get_tqp_reg_offset(uint16_t queue_id)
{
        uint32_t reg_offset;

        /* Need an extend offset to config queue > 1024 */
        if (queue_id < HNS3_MIN_EXTEND_QUEUE_ID)
                reg_offset = HNS3_TQP_REG_OFFSET + queue_id * HNS3_TQP_REG_SIZE;
        else
                reg_offset = HNS3_TQP_REG_OFFSET + HNS3_TQP_EXT_REG_OFFSET +
                             (queue_id - HNS3_MIN_EXTEND_QUEUE_ID) *
                             HNS3_TQP_REG_SIZE;

        return reg_offset;
}

int
hns3_rx_queue_setup(struct rte_eth_dev *dev, uint16_t idx, uint16_t nb_desc,
                    unsigned int socket_id, const struct rte_eth_rxconf *conf,
                    struct rte_mempool *mp)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_hw *hw = &hns->hw;
        struct hns3_queue_info q_info;
        struct hns3_rx_queue *rxq;
        uint16_t rx_buf_size;
        int rx_entry_len;
        int ret;

        ret = hns3_rx_queue_conf_check(hw, conf, mp, nb_desc, &rx_buf_size);
        if (ret)
                return ret;

        if (dev->data->rx_queues[idx]) {
                hns3_rx_queue_release(dev->data->rx_queues[idx]);
                dev->data->rx_queues[idx] = NULL;
        }

        q_info.idx = idx;
        q_info.socket_id = socket_id;
        q_info.nb_desc = nb_desc;
        q_info.type = "hns3 RX queue";
        q_info.ring_name = "rx_ring";

        rxq = hns3_alloc_rxq_and_dma_zone(dev, &q_info);
        if (rxq == NULL) {
                hns3_err(hw,
                         "Failed to alloc mem and reserve DMA mem for rx ring!");
                return -ENOMEM;
        }

        rxq->hns = hns;
        rxq->ptype_tbl = &hns->ptype_tbl;
        rxq->mb_pool = mp;
        rxq->rx_free_thresh = (conf->rx_free_thresh > 0) ?
                conf->rx_free_thresh : HNS3_DEFAULT_RX_FREE_THRESH;

        rxq->rx_deferred_start = conf->rx_deferred_start;
        if (rxq->rx_deferred_start && !hns3_dev_indep_txrx_supported(hw)) {
                hns3_warn(hw, "deferred start is not supported.");
                rxq->rx_deferred_start = false;
        }

        rx_entry_len = (rxq->nb_rx_desc + HNS3_DEFAULT_RX_BURST) *
                        sizeof(struct hns3_entry);
        rxq->sw_ring = rte_zmalloc_socket("hns3 RX sw ring", rx_entry_len,
                                          RTE_CACHE_LINE_SIZE, socket_id);
        if (rxq->sw_ring == NULL) {
                hns3_err(hw, "Failed to allocate memory for rx sw ring!");
                hns3_rx_queue_release(rxq);
                return -ENOMEM;
        }

        rxq->next_to_use = 0;
        rxq->rx_free_hold = 0;
        rxq->rx_rearm_start = 0;
        rxq->rx_rearm_nb = 0;
        rxq->pkt_first_seg = NULL;
        rxq->pkt_last_seg = NULL;
        rxq->port_id = dev->data->port_id;
        /*
         * For hns3 PF device, if the VLAN mode is HW_SHIFT_AND_DISCARD_MODE,
         * the pvid_sw_discard_en in the queue struct should not be changed,
         * because PVID-related operations do not need to be processed by PMD
         * driver. For hns3 VF device, whether it needs to process PVID depends
         * on the configuration of PF kernel mode netdevice driver. And the
         * related PF configuration is delivered through the mailbox and finally
         * reflectd in port_base_vlan_cfg.
         */
        if (hns->is_vf || hw->vlan_mode == HNS3_SW_SHIFT_AND_DISCARD_MODE)
                rxq->pvid_sw_discard_en = hw->port_base_vlan_cfg.state ==
                                       HNS3_PORT_BASE_VLAN_ENABLE;
        else
                rxq->pvid_sw_discard_en = false;
        rxq->ptype_en = hns3_dev_rxd_adv_layout_supported(hw) ? true : false;
        rxq->configured = true;
        rxq->io_base = (void *)((char *)hw->io_base + HNS3_TQP_REG_OFFSET +
                                idx * HNS3_TQP_REG_SIZE);
        rxq->io_base = (void *)((char *)hw->io_base +
                                        hns3_get_tqp_reg_offset(idx));
        rxq->io_head_reg = (volatile void *)((char *)rxq->io_base +
                           HNS3_RING_RX_HEAD_REG);
        rxq->rx_buf_len = rx_buf_size;
        memset(&rxq->basic_stats, 0, sizeof(struct hns3_rx_basic_stats));
        memset(&rxq->err_stats, 0, sizeof(struct hns3_rx_bd_errors_stats));
        memset(&rxq->dfx_stats, 0, sizeof(struct hns3_rx_dfx_stats));

        /* CRC len set here is used for amending packet length */
        if (dev->data->dev_conf.rxmode.offloads & DEV_RX_OFFLOAD_KEEP_CRC)
                rxq->crc_len = RTE_ETHER_CRC_LEN;
        else
                rxq->crc_len = 0;

        rxq->bulk_mbuf_num = 0;

        rte_spinlock_lock(&hw->lock);
        dev->data->rx_queues[idx] = rxq;
        rte_spinlock_unlock(&hw->lock);

        return 0;
}

void
hns3_rx_scattered_reset(struct rte_eth_dev *dev)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_hw *hw = &hns->hw;

        hw->rx_buf_len = 0;
        dev->data->scattered_rx = false;
}

void
hns3_rx_scattered_calc(struct rte_eth_dev *dev)
{
        struct rte_eth_conf *dev_conf = &dev->data->dev_conf;
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_hw *hw = &hns->hw;
        struct hns3_rx_queue *rxq;
        uint32_t queue_id;

        if (dev->data->rx_queues == NULL)
                return;

        for (queue_id = 0; queue_id < dev->data->nb_rx_queues; queue_id++) {
                rxq = dev->data->rx_queues[queue_id];
                if (hw->rx_buf_len == 0)
                        hw->rx_buf_len = rxq->rx_buf_len;
                else
                        hw->rx_buf_len = RTE_MIN(hw->rx_buf_len,
                                                 rxq->rx_buf_len);
        }

        if (dev_conf->rxmode.offloads & DEV_RX_OFFLOAD_SCATTER ||
            dev_conf->rxmode.max_rx_pkt_len > hw->rx_buf_len)
                dev->data->scattered_rx = true;
}

const uint32_t *
hns3_dev_supported_ptypes_get(struct rte_eth_dev *dev)
{
        static const uint32_t ptypes[] = {
                RTE_PTYPE_L2_ETHER,
                RTE_PTYPE_L2_ETHER_VLAN,
                RTE_PTYPE_L2_ETHER_QINQ,
                RTE_PTYPE_L2_ETHER_LLDP,
                RTE_PTYPE_L2_ETHER_ARP,
                RTE_PTYPE_L3_IPV4,
                RTE_PTYPE_L3_IPV4_EXT,
                RTE_PTYPE_L3_IPV6,
                RTE_PTYPE_L3_IPV6_EXT,
                RTE_PTYPE_L4_IGMP,
                RTE_PTYPE_L4_ICMP,
                RTE_PTYPE_L4_SCTP,
                RTE_PTYPE_L4_TCP,
                RTE_PTYPE_L4_UDP,
                RTE_PTYPE_TUNNEL_GRE,
                RTE_PTYPE_INNER_L2_ETHER,
                RTE_PTYPE_INNER_L2_ETHER_VLAN,
                RTE_PTYPE_INNER_L2_ETHER_QINQ,
                RTE_PTYPE_INNER_L3_IPV4,
                RTE_PTYPE_INNER_L3_IPV6,
                RTE_PTYPE_INNER_L3_IPV4_EXT,
                RTE_PTYPE_INNER_L3_IPV6_EXT,
                RTE_PTYPE_INNER_L4_UDP,
                RTE_PTYPE_INNER_L4_TCP,
                RTE_PTYPE_INNER_L4_SCTP,
                RTE_PTYPE_INNER_L4_ICMP,
                RTE_PTYPE_TUNNEL_VXLAN,
                RTE_PTYPE_TUNNEL_NVGRE,
                RTE_PTYPE_UNKNOWN
        };

        if (dev->rx_pkt_burst == hns3_recv_pkts ||
            dev->rx_pkt_burst == hns3_recv_scattered_pkts ||
            dev->rx_pkt_burst == hns3_recv_pkts_vec ||
            dev->rx_pkt_burst == hns3_recv_pkts_vec_sve)
                return ptypes;

        return NULL;
}

static void
hns3_init_non_tunnel_ptype_tbl(struct hns3_ptype_table *tbl)
{
        tbl->l3table[0] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4;
        tbl->l3table[1] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6;
        tbl->l3table[2] = RTE_PTYPE_L2_ETHER_ARP;
        tbl->l3table[4] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT;
        tbl->l3table[5] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT;
        tbl->l3table[6] = RTE_PTYPE_L2_ETHER_LLDP;

        tbl->l4table[0] = RTE_PTYPE_L4_UDP;
        tbl->l4table[1] = RTE_PTYPE_L4_TCP;
        tbl->l4table[2] = RTE_PTYPE_TUNNEL_GRE;
        tbl->l4table[3] = RTE_PTYPE_L4_SCTP;
        tbl->l4table[4] = RTE_PTYPE_L4_IGMP;
        tbl->l4table[5] = RTE_PTYPE_L4_ICMP;
}

static void
hns3_init_tunnel_ptype_tbl(struct hns3_ptype_table *tbl)
{
        tbl->inner_l3table[0] = RTE_PTYPE_INNER_L2_ETHER |
                                RTE_PTYPE_INNER_L3_IPV4;
        tbl->inner_l3table[1] = RTE_PTYPE_INNER_L2_ETHER |
                                RTE_PTYPE_INNER_L3_IPV6;
        /* There is not a ptype for inner ARP/RARP */
        tbl->inner_l3table[2] = RTE_PTYPE_UNKNOWN;
        tbl->inner_l3table[3] = RTE_PTYPE_UNKNOWN;
        tbl->inner_l3table[4] = RTE_PTYPE_INNER_L2_ETHER |
                                RTE_PTYPE_INNER_L3_IPV4_EXT;
        tbl->inner_l3table[5] = RTE_PTYPE_INNER_L2_ETHER |
                                RTE_PTYPE_INNER_L3_IPV6_EXT;

        tbl->inner_l4table[0] = RTE_PTYPE_INNER_L4_UDP;
        tbl->inner_l4table[1] = RTE_PTYPE_INNER_L4_TCP;
        /* There is not a ptype for inner GRE */
        tbl->inner_l4table[2] = RTE_PTYPE_UNKNOWN;
        tbl->inner_l4table[3] = RTE_PTYPE_INNER_L4_SCTP;
        /* There is not a ptype for inner IGMP */
        tbl->inner_l4table[4] = RTE_PTYPE_UNKNOWN;
        tbl->inner_l4table[5] = RTE_PTYPE_INNER_L4_ICMP;

        tbl->ol3table[0] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4;
        tbl->ol3table[1] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6;
        tbl->ol3table[2] = RTE_PTYPE_UNKNOWN;
        tbl->ol3table[3] = RTE_PTYPE_UNKNOWN;
        tbl->ol3table[4] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT;
        tbl->ol3table[5] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT;

        tbl->ol4table[0] = RTE_PTYPE_UNKNOWN;
        tbl->ol4table[1] = RTE_PTYPE_TUNNEL_VXLAN;
        tbl->ol4table[2] = RTE_PTYPE_TUNNEL_NVGRE;
}

static void
hns3_init_adv_layout_ptype(struct hns3_ptype_table *tbl)
{
        uint32_t *ptype = tbl->ptype;

        /* Non-tunnel L2 */
        ptype[1] = RTE_PTYPE_L2_ETHER_ARP;
        ptype[3] = RTE_PTYPE_L2_ETHER_LLDP;
        ptype[8] = RTE_PTYPE_L2_ETHER_TIMESYNC;

        /* Non-tunnel IPv4 */
        ptype[17] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_FRAG;
        ptype[18] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_NONFRAG;
        ptype[19] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_UDP;
        ptype[20] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_TCP;
        /* The next ptype is GRE over IPv4 */
        ptype[21] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN;
        ptype[22] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_SCTP;
        ptype[23] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_IGMP;
        ptype[24] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_ICMP;
        /* The next ptype is PTP over IPv4 + UDP */
        ptype[25] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_L4_UDP;

        /* IPv4 --> GRE/Teredo/VXLAN */
        ptype[29] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT;
        /* IPv4 --> GRE/Teredo/VXLAN --> MAC */
        ptype[30] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER;

        /* IPv4 --> GRE/Teredo/VXLAN --> MAC --> IPv4 */
        ptype[31] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_FRAG;
        ptype[32] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_NONFRAG;
        ptype[33] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_UDP;
        ptype[34] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_TCP;
        ptype[35] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_SCTP;
        /* The next ptype's inner L4 is IGMP */
        ptype[36] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN;
        ptype[37] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_ICMP;

        /* IPv4 --> GRE/Teredo/VXLAN --> MAC --> IPv6 */
        ptype[39] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_FRAG;
        ptype[40] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_NONFRAG;
        ptype[41] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_UDP;
        ptype[42] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_TCP;
        ptype[43] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_SCTP;
        /* The next ptype's inner L4 is IGMP */
        ptype[44] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN;
        ptype[45] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
                    RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                    RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                    RTE_PTYPE_INNER_L4_ICMP;

        /* Non-tunnel IPv6 */
        ptype[111] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_FRAG;
        ptype[112] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_NONFRAG;
        ptype[113] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_UDP;
        ptype[114] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_TCP;
        /* The next ptype is GRE over IPv6 */
        ptype[115] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN;
        ptype[116] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_SCTP;
        ptype[117] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_IGMP;
        ptype[118] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_ICMP;
        /* Special for PTP over IPv6 + UDP */
        ptype[119] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_L4_UDP;

        /* IPv6 --> GRE/Teredo/VXLAN */
        ptype[123] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT;
        /* IPv6 --> GRE/Teredo/VXLAN --> MAC */
        ptype[124] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER;

        /* IPv6 --> GRE/Teredo/VXLAN --> MAC --> IPv4 */
        ptype[125] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_FRAG;
        ptype[126] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_NONFRAG;
        ptype[127] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_UDP;
        ptype[128] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_TCP;
        ptype[129] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_SCTP;
        /* The next ptype's inner L4 is IGMP */
        ptype[130] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN;
        ptype[131] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_ICMP;

        /* IPv6 --> GRE/Teredo/VXLAN --> MAC --> IPv6 */
        ptype[133] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_FRAG;
        ptype[134] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_NONFRAG;
        ptype[135] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_UDP;
        ptype[136] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_TCP;
        ptype[137] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_SCTP;
        /* The next ptype's inner L4 is IGMP */
        ptype[138] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN;
        ptype[139] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_TUNNEL_GRENAT | RTE_PTYPE_INNER_L2_ETHER |
                     RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
                     RTE_PTYPE_INNER_L4_ICMP;
}

void
hns3_init_rx_ptype_tble(struct rte_eth_dev *dev)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        struct hns3_ptype_table *tbl = &hns->ptype_tbl;

        memset(tbl, 0, sizeof(*tbl));

        hns3_init_non_tunnel_ptype_tbl(tbl);
        hns3_init_tunnel_ptype_tbl(tbl);
        hns3_init_adv_layout_ptype(tbl);
}

static inline void
hns3_rxd_to_vlan_tci(struct hns3_rx_queue *rxq, struct rte_mbuf *mb,
                     uint32_t l234_info, const struct hns3_desc *rxd)
{
#define HNS3_STRP_STATUS_NUM            0x4

#define HNS3_NO_STRP_VLAN_VLD           0x0
#define HNS3_INNER_STRP_VLAN_VLD        0x1
#define HNS3_OUTER_STRP_VLAN_VLD        0x2
        uint32_t strip_status;
        uint32_t report_mode;

        /*
         * Since HW limitation, the vlan tag will always be inserted into RX
         * descriptor when strip the tag from packet, driver needs to determine
         * reporting which tag to mbuf according to the PVID configuration
         * and vlan striped status.
         */
        static const uint32_t report_type[][HNS3_STRP_STATUS_NUM] = {
                {
                        HNS3_NO_STRP_VLAN_VLD,
                        HNS3_OUTER_STRP_VLAN_VLD,
                        HNS3_INNER_STRP_VLAN_VLD,
                        HNS3_OUTER_STRP_VLAN_VLD
                },
                {
                        HNS3_NO_STRP_VLAN_VLD,
                        HNS3_NO_STRP_VLAN_VLD,
                        HNS3_NO_STRP_VLAN_VLD,
                        HNS3_INNER_STRP_VLAN_VLD
                }
        };
        strip_status = hns3_get_field(l234_info, HNS3_RXD_STRP_TAGP_M,
                                      HNS3_RXD_STRP_TAGP_S);
        report_mode = report_type[rxq->pvid_sw_discard_en][strip_status];
        switch (report_mode) {
        case HNS3_NO_STRP_VLAN_VLD:
                mb->vlan_tci = 0;
                return;
        case HNS3_INNER_STRP_VLAN_VLD:
                mb->ol_flags |= PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED;
                mb->vlan_tci = rte_le_to_cpu_16(rxd->rx.vlan_tag);
                return;
        case HNS3_OUTER_STRP_VLAN_VLD:
                mb->ol_flags |= PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED;
                mb->vlan_tci = rte_le_to_cpu_16(rxd->rx.ot_vlan_tag);
                return;
        default:
                mb->vlan_tci = 0;
                return;
        }
}

static inline void
recalculate_data_len(struct rte_mbuf *first_seg, struct rte_mbuf *last_seg,
                    struct rte_mbuf *rxm, struct hns3_rx_queue *rxq,
                    uint16_t data_len)
{
        uint8_t crc_len = rxq->crc_len;

        if (data_len <= crc_len) {
                rte_pktmbuf_free_seg(rxm);
                first_seg->nb_segs--;
                last_seg->data_len = (uint16_t)(last_seg->data_len -
                        (crc_len - data_len));
                last_seg->next = NULL;
        } else
                rxm->data_len = (uint16_t)(data_len - crc_len);
}

static inline struct rte_mbuf *
hns3_rx_alloc_buffer(struct hns3_rx_queue *rxq)
{
        int ret;

        if (likely(rxq->bulk_mbuf_num > 0))
                return rxq->bulk_mbuf[--rxq->bulk_mbuf_num];

        ret = rte_mempool_get_bulk(rxq->mb_pool, (void **)rxq->bulk_mbuf,
                                   HNS3_BULK_ALLOC_MBUF_NUM);
        if (likely(ret == 0)) {
                rxq->bulk_mbuf_num = HNS3_BULK_ALLOC_MBUF_NUM;
                return rxq->bulk_mbuf[--rxq->bulk_mbuf_num];
        } else
                return rte_mbuf_raw_alloc(rxq->mb_pool);
}

static inline void
hns3_rx_ptp_timestamp_handle(struct hns3_rx_queue *rxq, struct rte_mbuf *mbuf,
                  volatile struct hns3_desc *rxd)
{
        struct hns3_pf *pf = HNS3_DEV_PRIVATE_TO_PF(rxq->hns);
        uint64_t timestamp = rte_le_to_cpu_64(rxd->timestamp);

        mbuf->ol_flags |= PKT_RX_IEEE1588_PTP | PKT_RX_IEEE1588_TMST;
        if (hns3_timestamp_rx_dynflag > 0) {
                *RTE_MBUF_DYNFIELD(mbuf, hns3_timestamp_dynfield_offset,
                        rte_mbuf_timestamp_t *) = timestamp;
                mbuf->ol_flags |= hns3_timestamp_rx_dynflag;
        }

        pf->rx_timestamp = timestamp;
}

uint16_t
hns3_recv_pkts(void *rx_queue, struct rte_mbuf **rx_pkts, uint16_t nb_pkts)
{
        volatile struct hns3_desc *rx_ring;  /* RX ring (desc) */
        volatile struct hns3_desc *rxdp;     /* pointer of the current desc */
        struct hns3_rx_queue *rxq;      /* RX queue */
        struct hns3_entry *sw_ring;
        struct hns3_entry *rxe;
        struct hns3_desc rxd;
        struct rte_mbuf *nmb;           /* pointer of the new mbuf */
        struct rte_mbuf *rxm;
        uint32_t bd_base_info;
        uint32_t cksum_err;
        uint32_t l234_info;
        uint32_t ol_info;
        uint64_t dma_addr;
        uint16_t nb_rx_bd;
        uint16_t nb_rx;
        uint16_t rx_id;
        int ret;

        nb_rx = 0;
        nb_rx_bd = 0;
        rxq = rx_queue;
        rx_ring = rxq->rx_ring;
        sw_ring = rxq->sw_ring;
        rx_id = rxq->next_to_use;

        while (nb_rx < nb_pkts) {
                rxdp = &rx_ring[rx_id];
                bd_base_info = rte_le_to_cpu_32(rxdp->rx.bd_base_info);
                if (unlikely(!(bd_base_info & BIT(HNS3_RXD_VLD_B))))
                        break;

                rxd = rxdp[(bd_base_info & (1u << HNS3_RXD_VLD_B)) -
                           (1u << HNS3_RXD_VLD_B)];

                nmb = hns3_rx_alloc_buffer(rxq);
                if (unlikely(nmb == NULL)) {
                        uint16_t port_id;

                        port_id = rxq->port_id;
                        rte_eth_devices[port_id].data->rx_mbuf_alloc_failed++;
                        break;
                }

                nb_rx_bd++;
                rxe = &sw_ring[rx_id];
                rx_id++;
                if (unlikely(rx_id == rxq->nb_rx_desc))
                        rx_id = 0;

                rte_prefetch0(sw_ring[rx_id].mbuf);
                if ((rx_id & HNS3_RX_RING_PREFETCTH_MASK) == 0) {
                        rte_prefetch0(&rx_ring[rx_id]);
                        rte_prefetch0(&sw_ring[rx_id]);
                }

                rxm = rxe->mbuf;
                rxm->ol_flags = 0;
                rxe->mbuf = nmb;

                if (unlikely(bd_base_info & BIT(HNS3_RXD_TS_VLD_B)))
                        hns3_rx_ptp_timestamp_handle(rxq, rxm, rxdp);

                dma_addr = rte_mbuf_data_iova_default(nmb);
                rxdp->addr = rte_cpu_to_le_64(dma_addr);
                rxdp->rx.bd_base_info = 0;

                rxm->data_off = RTE_PKTMBUF_HEADROOM;
                rxm->pkt_len = (uint16_t)(rte_le_to_cpu_16(rxd.rx.pkt_len)) -
                                rxq->crc_len;
                rxm->data_len = rxm->pkt_len;
                rxm->port = rxq->port_id;
                rxm->hash.rss = rte_le_to_cpu_32(rxd.rx.rss_hash);
                rxm->ol_flags |= PKT_RX_RSS_HASH;
                if (unlikely(bd_base_info & BIT(HNS3_RXD_LUM_B))) {
                        rxm->hash.fdir.hi =
                                rte_le_to_cpu_16(rxd.rx.fd_id);
                        rxm->ol_flags |= PKT_RX_FDIR | PKT_RX_FDIR_ID;
                }
                rxm->nb_segs = 1;
                rxm->next = NULL;

                /* Load remained descriptor data and extract necessary fields */
                l234_info = rte_le_to_cpu_32(rxd.rx.l234_info);
                ol_info = rte_le_to_cpu_32(rxd.rx.ol_info);
                ret = hns3_handle_bdinfo(rxq, rxm, bd_base_info,
                                         l234_info, &cksum_err);
                if (unlikely(ret))
                        goto pkt_err;

                rxm->packet_type = hns3_rx_calc_ptype(rxq, l234_info, ol_info);

                if (rxm->packet_type == RTE_PTYPE_L2_ETHER_TIMESYNC)
                        rxm->ol_flags |= PKT_RX_IEEE1588_PTP;

                if (likely(bd_base_info & BIT(HNS3_RXD_L3L4P_B)))
                        hns3_rx_set_cksum_flag(rxm, rxm->packet_type,
                                               cksum_err);
                hns3_rxd_to_vlan_tci(rxq, rxm, l234_info, &rxd);

                /* Increment bytes counter  */
                rxq->basic_stats.bytes += rxm->pkt_len;

                rx_pkts[nb_rx++] = rxm;
                continue;
pkt_err:
                rte_pktmbuf_free(rxm);
        }

        rxq->next_to_use = rx_id;
        rxq->rx_free_hold += nb_rx_bd;
        if (rxq->rx_free_hold > rxq->rx_free_thresh) {
                hns3_write_reg_opt(rxq->io_head_reg, rxq->rx_free_hold);
                rxq->rx_free_hold = 0;
        }

        return nb_rx;
}

uint16_t
hns3_recv_scattered_pkts(void *rx_queue,
                         struct rte_mbuf **rx_pkts,
                         uint16_t nb_pkts)
{
        volatile struct hns3_desc *rx_ring;  /* RX ring (desc) */
        volatile struct hns3_desc *rxdp;     /* pointer of the current desc */
        struct hns3_rx_queue *rxq;      /* RX queue */
        struct hns3_entry *sw_ring;
        struct hns3_entry *rxe;
        struct rte_mbuf *first_seg;
        struct rte_mbuf *last_seg;
        struct hns3_desc rxd;
        struct rte_mbuf *nmb;           /* pointer of the new mbuf */
        struct rte_mbuf *rxm;
        struct rte_eth_dev *dev;
        uint32_t bd_base_info;
        uint32_t cksum_err;
        uint32_t l234_info;
        uint32_t gro_size;
        uint32_t ol_info;
        uint64_t dma_addr;
        uint16_t nb_rx_bd;
        uint16_t nb_rx;
        uint16_t rx_id;
        int ret;

        nb_rx = 0;
        nb_rx_bd = 0;
        rxq = rx_queue;

        rx_id = rxq->next_to_use;
        rx_ring = rxq->rx_ring;
        sw_ring = rxq->sw_ring;
        first_seg = rxq->pkt_first_seg;
        last_seg = rxq->pkt_last_seg;

        while (nb_rx < nb_pkts) {
                rxdp = &rx_ring[rx_id];
                bd_base_info = rte_le_to_cpu_32(rxdp->rx.bd_base_info);
                if (unlikely(!(bd_base_info & BIT(HNS3_RXD_VLD_B))))
                        break;

                /*
                 * The interactive process between software and hardware of
                 * receiving a new packet in hns3 network engine:
                 * 1. Hardware network engine firstly writes the packet content
                 *    to the memory pointed by the 'addr' field of the Rx Buffer
                 *    Descriptor, secondly fills the result of parsing the
                 *    packet include the valid field into the Rx Buffer
                 *    Descriptor in one write operation.
                 * 2. Driver reads the Rx BD's valid field in the loop to check
                 *    whether it's valid, if valid then assign a new address to
                 *    the addr field, clear the valid field, get the other
                 *    information of the packet by parsing Rx BD's other fields,
                 *    finally write back the number of Rx BDs processed by the
                 *    driver to the HNS3_RING_RX_HEAD_REG register to inform
                 *    hardware.
                 * In the above process, the ordering is very important. We must
                 * make sure that CPU read Rx BD's other fields only after the
                 * Rx BD is valid.
                 *
                 * There are two type of re-ordering: compiler re-ordering and
                 * CPU re-ordering under the ARMv8 architecture.
                 * 1. we use volatile to deal with compiler re-ordering, so you
                 *    can see that rx_ring/rxdp defined with volatile.
                 * 2. we commonly use memory barrier to deal with CPU
                 *    re-ordering, but the cost is high.
                 *
                 * In order to solve the high cost of using memory barrier, we
                 * use the data dependency order under the ARMv8 architecture,
                 * for example:
                 *      instr01: load A
                 *      instr02: load B <- A
                 * the instr02 will always execute after instr01.
                 *
                 * To construct the data dependency ordering, we use the
                 * following assignment:
                 *      rxd = rxdp[(bd_base_info & (1u << HNS3_RXD_VLD_B)) -
                 *                 (1u<<HNS3_RXD_VLD_B)]
                 * Using gcc compiler under the ARMv8 architecture, the related
                 * assembly code example as follows:
                 * note: (1u << HNS3_RXD_VLD_B) equal 0x10
                 *      instr01: ldr w26, [x22, #28]  --read bd_base_info
                 *      instr02: and w0, w26, #0x10   --calc bd_base_info & 0x10
                 *      instr03: sub w0, w0, #0x10    --calc (bd_base_info &
                 *                                            0x10) - 0x10
                 *      instr04: add x0, x22, x0, lsl #5 --calc copy source addr
                 *      instr05: ldp x2, x3, [x0]
                 *      instr06: stp x2, x3, [x29, #256] --copy BD's [0 ~ 15]B
                 *      instr07: ldp x4, x5, [x0, #16]
                 *      instr08: stp x4, x5, [x29, #272] --copy BD's [16 ~ 31]B
                 * the instr05~08 depend on x0's value, x0 depent on w26's
                 * value, the w26 is the bd_base_info, this form the data
                 * dependency ordering.
                 * note: if BD is valid, (bd_base_info & (1u<<HNS3_RXD_VLD_B)) -
                 *       (1u<<HNS3_RXD_VLD_B) will always zero, so the
                 *       assignment is correct.
                 *
                 * So we use the data dependency ordering instead of memory
                 * barrier to improve receive performance.
                 */
                rxd = rxdp[(bd_base_info & (1u << HNS3_RXD_VLD_B)) -
                           (1u << HNS3_RXD_VLD_B)];

                nmb = hns3_rx_alloc_buffer(rxq);
                if (unlikely(nmb == NULL)) {
                        dev = &rte_eth_devices[rxq->port_id];
                        dev->data->rx_mbuf_alloc_failed++;
                        break;
                }

                nb_rx_bd++;
                rxe = &sw_ring[rx_id];
                rx_id++;
                if (unlikely(rx_id == rxq->nb_rx_desc))
                        rx_id = 0;

                rte_prefetch0(sw_ring[rx_id].mbuf);
                if ((rx_id & HNS3_RX_RING_PREFETCTH_MASK) == 0) {
                        rte_prefetch0(&rx_ring[rx_id]);
                        rte_prefetch0(&sw_ring[rx_id]);
                }

                rxm = rxe->mbuf;
                rxe->mbuf = nmb;

                dma_addr = rte_cpu_to_le_64(rte_mbuf_data_iova_default(nmb));
                rxdp->rx.bd_base_info = 0;
                rxdp->addr = dma_addr;

                if (first_seg == NULL) {
                        first_seg = rxm;
                        first_seg->nb_segs = 1;
                } else {
                        first_seg->nb_segs++;
                        last_seg->next = rxm;
                }

                rxm->data_off = RTE_PKTMBUF_HEADROOM;
                rxm->data_len = rte_le_to_cpu_16(rxd.rx.size);

                if (!(bd_base_info & BIT(HNS3_RXD_FE_B))) {
                        last_seg = rxm;
                        rxm->next = NULL;
                        continue;
                }

                /*
                 * The last buffer of the received packet. packet len from
                 * buffer description may contains CRC len, packet len should
                 * subtract it, same as data len.
                 */
                first_seg->pkt_len = rte_le_to_cpu_16(rxd.rx.pkt_len);

                /*
                 * This is the last buffer of the received packet. If the CRC
                 * is not stripped by the hardware:
                 *  - Subtract the CRC length from the total packet length.
                 *  - If the last buffer only contains the whole CRC or a part
                 *  of it, free the mbuf associated to the last buffer. If part
                 *  of the CRC is also contained in the previous mbuf, subtract
                 *  the length of that CRC part from the data length of the
                 *  previous mbuf.
                 */
                rxm->next = NULL;
                if (unlikely(rxq->crc_len > 0)) {
                        first_seg->pkt_len -= rxq->crc_len;
                        recalculate_data_len(first_seg, last_seg, rxm, rxq,
                                rxm->data_len);
                }

                first_seg->port = rxq->port_id;
                first_seg->hash.rss = rte_le_to_cpu_32(rxd.rx.rss_hash);
                first_seg->ol_flags = PKT_RX_RSS_HASH;
                if (unlikely(bd_base_info & BIT(HNS3_RXD_LUM_B))) {
                        first_seg->hash.fdir.hi =
                                rte_le_to_cpu_16(rxd.rx.fd_id);
                        first_seg->ol_flags |= PKT_RX_FDIR | PKT_RX_FDIR_ID;
                }

                gro_size = hns3_get_field(bd_base_info, HNS3_RXD_GRO_SIZE_M,
                                          HNS3_RXD_GRO_SIZE_S);
                if (gro_size != 0) {
                        first_seg->ol_flags |= PKT_RX_LRO;
                        first_seg->tso_segsz = gro_size;
                }

                l234_info = rte_le_to_cpu_32(rxd.rx.l234_info);
                ol_info = rte_le_to_cpu_32(rxd.rx.ol_info);
                ret = hns3_handle_bdinfo(rxq, first_seg, bd_base_info,
                                         l234_info, &cksum_err);
                if (unlikely(ret))
                        goto pkt_err;

                first_seg->packet_type = hns3_rx_calc_ptype(rxq,
                                                l234_info, ol_info);

                if (bd_base_info & BIT(HNS3_RXD_L3L4P_B))
                        hns3_rx_set_cksum_flag(first_seg,
                                               first_seg->packet_type,
                                               cksum_err);
                hns3_rxd_to_vlan_tci(rxq, first_seg, l234_info, &rxd);

                /* Increment bytes counter */
                rxq->basic_stats.bytes += first_seg->pkt_len;

                rx_pkts[nb_rx++] = first_seg;
                first_seg = NULL;
                continue;
pkt_err:
                rte_pktmbuf_free(first_seg);
                first_seg = NULL;
        }

        rxq->next_to_use = rx_id;
        rxq->pkt_first_seg = first_seg;
        rxq->pkt_last_seg = last_seg;

        rxq->rx_free_hold += nb_rx_bd;
        if (rxq->rx_free_hold > rxq->rx_free_thresh) {
                hns3_write_reg_opt(rxq->io_head_reg, rxq->rx_free_hold);
                rxq->rx_free_hold = 0;
        }

        return nb_rx;
}

void __rte_weak
hns3_rxq_vec_setup(__rte_unused struct hns3_rx_queue *rxq)
{
}

int __rte_weak
hns3_rx_check_vec_support(__rte_unused struct rte_eth_dev *dev)
{
        return -ENOTSUP;
}

uint16_t __rte_weak
hns3_recv_pkts_vec(__rte_unused void *tx_queue,
                   __rte_unused struct rte_mbuf **rx_pkts,
                   __rte_unused uint16_t nb_pkts)
{
        return 0;
}

uint16_t __rte_weak
hns3_recv_pkts_vec_sve(__rte_unused void *tx_queue,
                       __rte_unused struct rte_mbuf **rx_pkts,
                       __rte_unused uint16_t nb_pkts)
{
        return 0;
}

int
hns3_rx_burst_mode_get(struct rte_eth_dev *dev, __rte_unused uint16_t queue_id,
                       struct rte_eth_burst_mode *mode)
{
        static const struct {
                eth_rx_burst_t pkt_burst;
                const char *info;
        } burst_infos[] = {
                { hns3_recv_pkts,               "Scalar" },
                { hns3_recv_scattered_pkts,     "Scalar Scattered" },
                { hns3_recv_pkts_vec,           "Vector Neon" },
                { hns3_recv_pkts_vec_sve,       "Vector Sve" },
        };

        eth_rx_burst_t pkt_burst = dev->rx_pkt_burst;
        int ret = -EINVAL;
        unsigned int i;

        for (i = 0; i < RTE_DIM(burst_infos); i++) {
                if (pkt_burst == burst_infos[i].pkt_burst) {
                        snprintf(mode->info, sizeof(mode->info), "%s",
                                 burst_infos[i].info);
                        ret = 0;
                        break;
                }
        }

        return ret;
}

static bool
hns3_check_sve_support(void)
{
#if defined(RTE_ARCH_ARM64) && defined(__ARM_FEATURE_SVE)
        if (rte_cpu_get_flag_enabled(RTE_CPUFLAG_SVE))
                return true;
#endif
        return false;
}

static eth_rx_burst_t
hns3_get_rx_function(struct rte_eth_dev *dev)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        uint64_t offloads = dev->data->dev_conf.rxmode.offloads;
        bool vec_allowed, sve_allowed, simple_allowed;

        vec_allowed = hns3_rx_check_vec_support(dev) == 0;
        sve_allowed = vec_allowed && hns3_check_sve_support();
        simple_allowed = !dev->data->scattered_rx &&
                         (offloads & DEV_RX_OFFLOAD_TCP_LRO) == 0;

        if (hns->rx_func_hint == HNS3_IO_FUNC_HINT_VEC && vec_allowed)
                return hns3_recv_pkts_vec;
        if (hns->rx_func_hint == HNS3_IO_FUNC_HINT_SVE && sve_allowed)
                return hns3_recv_pkts_vec_sve;
        if (hns->rx_func_hint == HNS3_IO_FUNC_HINT_SIMPLE && simple_allowed)
                return hns3_recv_pkts;
        if (hns->rx_func_hint == HNS3_IO_FUNC_HINT_COMMON)
                return hns3_recv_scattered_pkts;

        if (vec_allowed)
                return hns3_recv_pkts_vec;
        if (simple_allowed)
                return hns3_recv_pkts;

        return hns3_recv_scattered_pkts;
}

static int
hns3_tx_queue_conf_check(struct hns3_hw *hw, const struct rte_eth_txconf *conf,
                         uint16_t nb_desc, uint16_t *tx_rs_thresh,
                         uint16_t *tx_free_thresh, uint16_t idx)
{
#define HNS3_TX_RS_FREE_THRESH_GAP      8
        uint16_t rs_thresh, free_thresh, fast_free_thresh;

        if (nb_desc > HNS3_MAX_RING_DESC || nb_desc < HNS3_MIN_RING_DESC ||
            nb_desc % HNS3_ALIGN_RING_DESC) {
                hns3_err(hw, "number (%u) of tx descriptors is invalid",
                         nb_desc);
                return -EINVAL;
        }

        rs_thresh = (conf->tx_rs_thresh > 0) ?
                        conf->tx_rs_thresh : HNS3_DEFAULT_TX_RS_THRESH;
        free_thresh = (conf->tx_free_thresh > 0) ?
                        conf->tx_free_thresh : HNS3_DEFAULT_TX_FREE_THRESH;
        if (rs_thresh + free_thresh > nb_desc || nb_desc % rs_thresh ||
            rs_thresh >= nb_desc - HNS3_TX_RS_FREE_THRESH_GAP ||
            free_thresh >= nb_desc - HNS3_TX_RS_FREE_THRESH_GAP) {
                hns3_err(hw, "tx_rs_thresh (%u) tx_free_thresh (%u) nb_desc "
                         "(%u) of tx descriptors for port=%u queue=%u check "
                         "fail!",
                         rs_thresh, free_thresh, nb_desc, hw->data->port_id,
                         idx);
                return -EINVAL;
        }

        if (conf->tx_free_thresh == 0) {
                /* Fast free Tx memory buffer to improve cache hit rate */
                fast_free_thresh = nb_desc - rs_thresh;
                if (fast_free_thresh >=
                    HNS3_TX_FAST_FREE_AHEAD + HNS3_DEFAULT_TX_FREE_THRESH)
                        free_thresh = fast_free_thresh -
                                        HNS3_TX_FAST_FREE_AHEAD;
        }

        *tx_rs_thresh = rs_thresh;
        *tx_free_thresh = free_thresh;
        return 0;
}

int
hns3_tx_queue_setup(struct rte_eth_dev *dev, uint16_t idx, uint16_t nb_desc,
                    unsigned int socket_id, const struct rte_eth_txconf *conf)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        uint16_t tx_rs_thresh, tx_free_thresh;
        struct hns3_hw *hw = &hns->hw;
        struct hns3_queue_info q_info;
        struct hns3_tx_queue *txq;
        int tx_entry_len;
        int ret;

        ret = hns3_tx_queue_conf_check(hw, conf, nb_desc,
                                       &tx_rs_thresh, &tx_free_thresh, idx);
        if (ret)
                return ret;

        if (dev->data->tx_queues[idx] != NULL) {
                hns3_tx_queue_release(dev->data->tx_queues[idx]);
                dev->data->tx_queues[idx] = NULL;
        }

        q_info.idx = idx;
        q_info.socket_id = socket_id;
        q_info.nb_desc = nb_desc;
        q_info.type = "hns3 TX queue";
        q_info.ring_name = "tx_ring";
        txq = hns3_alloc_txq_and_dma_zone(dev, &q_info);
        if (txq == NULL) {
                hns3_err(hw,
                         "Failed to alloc mem and reserve DMA mem for tx ring!");
                return -ENOMEM;
        }

        txq->tx_deferred_start = conf->tx_deferred_start;
        if (txq->tx_deferred_start && !hns3_dev_indep_txrx_supported(hw)) {
                hns3_warn(hw, "deferred start is not supported.");
                txq->tx_deferred_start = false;
        }

        tx_entry_len = sizeof(struct hns3_entry) * txq->nb_tx_desc;
        txq->sw_ring = rte_zmalloc_socket("hns3 TX sw ring", tx_entry_len,
                                          RTE_CACHE_LINE_SIZE, socket_id);
        if (txq->sw_ring == NULL) {
                hns3_err(hw, "Failed to allocate memory for tx sw ring!");
                hns3_tx_queue_release(txq);
                return -ENOMEM;
        }

        txq->hns = hns;
        txq->next_to_use = 0;
        txq->next_to_clean = 0;
        txq->tx_bd_ready = txq->nb_tx_desc - 1;
        txq->tx_free_thresh = tx_free_thresh;
        txq->tx_rs_thresh = tx_rs_thresh;
        txq->free = rte_zmalloc_socket("hns3 TX mbuf free array",
                                sizeof(struct rte_mbuf *) * txq->tx_rs_thresh,
                                RTE_CACHE_LINE_SIZE, socket_id);
        if (!txq->free) {
                hns3_err(hw, "failed to allocate tx mbuf free array!");
                hns3_tx_queue_release(txq);
                return -ENOMEM;
        }

        txq->port_id = dev->data->port_id;
        /*
         * For hns3 PF device, if the VLAN mode is HW_SHIFT_AND_DISCARD_MODE,
         * the pvid_sw_shift_en in the queue struct should not be changed,
         * because PVID-related operations do not need to be processed by PMD
         * driver. For hns3 VF device, whether it needs to process PVID depends
         * on the configuration of PF kernel mode netdev driver. And the
         * related PF configuration is delivered through the mailbox and finally
         * reflectd in port_base_vlan_cfg.
         */
        if (hns->is_vf || hw->vlan_mode == HNS3_SW_SHIFT_AND_DISCARD_MODE)
                txq->pvid_sw_shift_en = hw->port_base_vlan_cfg.state ==
                                        HNS3_PORT_BASE_VLAN_ENABLE;
        else
                txq->pvid_sw_shift_en = false;
        txq->max_non_tso_bd_num = hw->max_non_tso_bd_num;
        txq->configured = true;
        txq->io_base = (void *)((char *)hw->io_base +
                                                hns3_get_tqp_reg_offset(idx));
        txq->io_tail_reg = (volatile void *)((char *)txq->io_base +
                                             HNS3_RING_TX_TAIL_REG);
        txq->min_tx_pkt_len = hw->min_tx_pkt_len;
        txq->tso_mode = hw->tso_mode;
        txq->udp_cksum_mode = hw->udp_cksum_mode;
        memset(&txq->basic_stats, 0, sizeof(struct hns3_tx_basic_stats));
        memset(&txq->dfx_stats, 0, sizeof(struct hns3_tx_dfx_stats));

        rte_spinlock_lock(&hw->lock);
        dev->data->tx_queues[idx] = txq;
        rte_spinlock_unlock(&hw->lock);

        return 0;
}

static void
hns3_tx_free_useless_buffer(struct hns3_tx_queue *txq)
{
        uint16_t tx_next_clean = txq->next_to_clean;
        uint16_t tx_next_use   = txq->next_to_use;
        uint16_t tx_bd_ready   = txq->tx_bd_ready;
        uint16_t tx_bd_max     = txq->nb_tx_desc;
        struct hns3_entry *tx_bak_pkt = &txq->sw_ring[tx_next_clean];
        struct hns3_desc *desc = &txq->tx_ring[tx_next_clean];
        struct rte_mbuf *mbuf;

        while ((!(desc->tx.tp_fe_sc_vld_ra_ri &
                rte_cpu_to_le_16(BIT(HNS3_TXD_VLD_B)))) &&
                tx_next_use != tx_next_clean) {
                mbuf = tx_bak_pkt->mbuf;
                if (mbuf) {
                        rte_pktmbuf_free_seg(mbuf);
                        tx_bak_pkt->mbuf = NULL;
                }

                desc++;
                tx_bak_pkt++;
                tx_next_clean++;
                tx_bd_ready++;

                if (tx_next_clean >= tx_bd_max) {
                        tx_next_clean = 0;
                        desc = txq->tx_ring;
                        tx_bak_pkt = txq->sw_ring;
                }
        }

        txq->next_to_clean = tx_next_clean;
        txq->tx_bd_ready   = tx_bd_ready;
}

int
hns3_config_gro(struct hns3_hw *hw, bool en)
{
        struct hns3_cfg_gro_status_cmd *req;
        struct hns3_cmd_desc desc;
        int ret;

        hns3_cmd_setup_basic_desc(&desc, HNS3_OPC_GRO_GENERIC_CONFIG, false);
        req = (struct hns3_cfg_gro_status_cmd *)desc.data;

        req->gro_en = rte_cpu_to_le_16(en ? 1 : 0);

        ret = hns3_cmd_send(hw, &desc, 1);
        if (ret)
                hns3_err(hw, "%s hardware GRO failed, ret = %d",
                         en ? "enable" : "disable", ret);

        return ret;
}

int
hns3_restore_gro_conf(struct hns3_hw *hw)
{
        uint64_t offloads;
        bool gro_en;
        int ret;

        offloads = hw->data->dev_conf.rxmode.offloads;
        gro_en = offloads & DEV_RX_OFFLOAD_TCP_LRO ? true : false;
        ret = hns3_config_gro(hw, gro_en);
        if (ret)
                hns3_err(hw, "restore hardware GRO to %s failed, ret = %d",
                         gro_en ? "enabled" : "disabled", ret);

        return ret;
}

static inline bool
hns3_pkt_is_tso(struct rte_mbuf *m)
{
        return (m->tso_segsz != 0 && m->ol_flags & PKT_TX_TCP_SEG);
}

static void
hns3_set_tso(struct hns3_desc *desc, uint32_t paylen, struct rte_mbuf *rxm)
{
        if (!hns3_pkt_is_tso(rxm))
                return;

        if (paylen <= rxm->tso_segsz)
                return;

        desc->tx.type_cs_vlan_tso_len |= rte_cpu_to_le_32(BIT(HNS3_TXD_TSO_B));
        desc->tx.mss = rte_cpu_to_le_16(rxm->tso_segsz);
}

static inline void
hns3_fill_per_desc(struct hns3_desc *desc, struct rte_mbuf *rxm)
{
        desc->addr = rte_mbuf_data_iova(rxm);
        desc->tx.send_size = rte_cpu_to_le_16(rte_pktmbuf_data_len(rxm));
        desc->tx.tp_fe_sc_vld_ra_ri |= rte_cpu_to_le_16(BIT(HNS3_TXD_VLD_B));
}

static void
hns3_fill_first_desc(struct hns3_tx_queue *txq, struct hns3_desc *desc,
                     struct rte_mbuf *rxm)
{
        uint64_t ol_flags = rxm->ol_flags;
        uint32_t hdr_len;
        uint32_t paylen;

        hdr_len = rxm->l2_len + rxm->l3_len + rxm->l4_len;
        hdr_len += (ol_flags & PKT_TX_TUNNEL_MASK) ?
                           rxm->outer_l2_len + rxm->outer_l3_len : 0;
        paylen = rxm->pkt_len - hdr_len;
        desc->tx.paylen_fd_dop_ol4cs |= rte_cpu_to_le_32(paylen);
        hns3_set_tso(desc, paylen, rxm);

        /*
         * Currently, hardware doesn't support more than two layers VLAN offload
         * in Tx direction based on hns3 network engine. So when the number of
         * VLANs in the packets represented by rxm plus the number of VLAN
         * offload by hardware such as PVID etc, exceeds two, the packets will
         * be discarded or the original VLAN of the packets will be overwitted
         * by hardware. When the PF PVID is enabled by calling the API function
         * named rte_eth_dev_set_vlan_pvid or the VF PVID is enabled by the hns3
         * PF kernel ether driver, the outer VLAN tag will always be the PVID.
         * To avoid the VLAN of Tx descriptor is overwritten by PVID, it should
         * be added to the position close to the IP header when PVID is enabled.
         */
        if (!txq->pvid_sw_shift_en && ol_flags & (PKT_TX_VLAN_PKT |
                                PKT_TX_QINQ_PKT)) {
                desc->tx.ol_type_vlan_len_msec |=
                                rte_cpu_to_le_32(BIT(HNS3_TXD_OVLAN_B));
                if (ol_flags & PKT_TX_QINQ_PKT)
                        desc->tx.outer_vlan_tag =
                                        rte_cpu_to_le_16(rxm->vlan_tci_outer);
                else
                        desc->tx.outer_vlan_tag =
                                        rte_cpu_to_le_16(rxm->vlan_tci);
        }

        if (ol_flags & PKT_TX_QINQ_PKT ||
            ((ol_flags & PKT_TX_VLAN_PKT) && txq->pvid_sw_shift_en)) {
                desc->tx.type_cs_vlan_tso_len |=
                                        rte_cpu_to_le_32(BIT(HNS3_TXD_VLAN_B));
                desc->tx.vlan_tag = rte_cpu_to_le_16(rxm->vlan_tci);
        }

        if (ol_flags & PKT_TX_IEEE1588_TMST)
                desc->tx.tp_fe_sc_vld_ra_ri |=
                                rte_cpu_to_le_16(BIT(HNS3_TXD_TSYN_B));
}

static inline int
hns3_tx_alloc_mbufs(struct rte_mempool *mb_pool, uint16_t nb_new_buf,
                        struct rte_mbuf **alloc_mbuf)
{
#define MAX_NON_TSO_BD_PER_PKT 18
        struct rte_mbuf *pkt_segs[MAX_NON_TSO_BD_PER_PKT];
        uint16_t i;

        /* Allocate enough mbufs */
        if (rte_mempool_get_bulk(mb_pool, (void **)pkt_segs, nb_new_buf))
                return -ENOMEM;

        for (i = 0; i < nb_new_buf - 1; i++)
                pkt_segs[i]->next = pkt_segs[i + 1];

        pkt_segs[nb_new_buf - 1]->next = NULL;
        pkt_segs[0]->nb_segs = nb_new_buf;
        *alloc_mbuf = pkt_segs[0];

        return 0;
}

static inline void
hns3_pktmbuf_copy_hdr(struct rte_mbuf *new_pkt, struct rte_mbuf *old_pkt)
{
        new_pkt->ol_flags = old_pkt->ol_flags;
        new_pkt->pkt_len = rte_pktmbuf_pkt_len(old_pkt);
        new_pkt->outer_l2_len = old_pkt->outer_l2_len;
        new_pkt->outer_l3_len = old_pkt->outer_l3_len;
        new_pkt->l2_len = old_pkt->l2_len;
        new_pkt->l3_len = old_pkt->l3_len;
        new_pkt->l4_len = old_pkt->l4_len;
        new_pkt->vlan_tci_outer = old_pkt->vlan_tci_outer;
        new_pkt->vlan_tci = old_pkt->vlan_tci;
}

static int
hns3_reassemble_tx_pkts(struct rte_mbuf *tx_pkt, struct rte_mbuf **new_pkt,
                                  uint8_t max_non_tso_bd_num)
{
        struct rte_mempool *mb_pool;
        struct rte_mbuf *new_mbuf;
        struct rte_mbuf *temp_new;
        struct rte_mbuf *temp;
        uint16_t last_buf_len;
        uint16_t nb_new_buf;
        uint16_t buf_size;
        uint16_t buf_len;
        uint16_t len_s;
        uint16_t len_d;
        uint16_t len;
        int ret;
        char *s;
        char *d;

        mb_pool = tx_pkt->pool;
        buf_size = tx_pkt->buf_len - RTE_PKTMBUF_HEADROOM;
        nb_new_buf = (rte_pktmbuf_pkt_len(tx_pkt) - 1) / buf_size + 1;
        if (nb_new_buf > max_non_tso_bd_num)
                return -EINVAL;

        last_buf_len = rte_pktmbuf_pkt_len(tx_pkt) % buf_size;
        if (last_buf_len == 0)
                last_buf_len = buf_size;

        /* Allocate enough mbufs */
        ret = hns3_tx_alloc_mbufs(mb_pool, nb_new_buf, &new_mbuf);
        if (ret)
                return ret;

        /* Copy the original packet content to the new mbufs */
        temp = tx_pkt;
        s = rte_pktmbuf_mtod(temp, char *);
        len_s = rte_pktmbuf_data_len(temp);
        temp_new = new_mbuf;
        while (temp != NULL && temp_new != NULL) {
                d = rte_pktmbuf_mtod(temp_new, char *);
                buf_len = temp_new->next == NULL ? last_buf_len : buf_size;
                len_d = buf_len;

                while (len_d) {
                        len = RTE_MIN(len_s, len_d);
                        memcpy(d, s, len);
                        s = s + len;
                        d = d + len;
                        len_d = len_d - len;
                        len_s = len_s - len;

                        if (len_s == 0) {
                                temp = temp->next;
                                if (temp == NULL)
                                        break;
                                s = rte_pktmbuf_mtod(temp, char *);
                                len_s = rte_pktmbuf_data_len(temp);
                        }
                }

                temp_new->data_len = buf_len;
                temp_new = temp_new->next;
        }
        hns3_pktmbuf_copy_hdr(new_mbuf, tx_pkt);

        /* free original mbufs */
        rte_pktmbuf_free(tx_pkt);

        *new_pkt = new_mbuf;

        return 0;
}

static void
hns3_parse_outer_params(struct rte_mbuf *m, uint32_t *ol_type_vlan_len_msec)
{
        uint32_t tmp = *ol_type_vlan_len_msec;
        uint64_t ol_flags = m->ol_flags;

        /* (outer) IP header type */
        if (ol_flags & PKT_TX_OUTER_IPV4) {
                if (ol_flags & PKT_TX_OUTER_IP_CKSUM)
                        tmp |= hns3_gen_field_val(HNS3_TXD_OL3T_M,
                                        HNS3_TXD_OL3T_S, HNS3_OL3T_IPV4_CSUM);
                else
                        tmp |= hns3_gen_field_val(HNS3_TXD_OL3T_M,
                                HNS3_TXD_OL3T_S, HNS3_OL3T_IPV4_NO_CSUM);
        } else if (ol_flags & PKT_TX_OUTER_IPV6) {
                tmp |= hns3_gen_field_val(HNS3_TXD_OL3T_M, HNS3_TXD_OL3T_S,
                                        HNS3_OL3T_IPV6);
        }
        /* OL3 header size, defined in 4 bytes */
        tmp |= hns3_gen_field_val(HNS3_TXD_L3LEN_M, HNS3_TXD_L3LEN_S,
                                m->outer_l3_len >> HNS3_L3_LEN_UNIT);
        *ol_type_vlan_len_msec = tmp;
}

static int
hns3_parse_inner_params(struct rte_mbuf *m, uint32_t *ol_type_vlan_len_msec,
                        uint32_t *type_cs_vlan_tso_len)
{
#define HNS3_NVGRE_HLEN 8
        uint32_t tmp_outer = *ol_type_vlan_len_msec;
        uint32_t tmp_inner = *type_cs_vlan_tso_len;
        uint64_t ol_flags = m->ol_flags;
        uint16_t inner_l2_len;

        switch (ol_flags & PKT_TX_TUNNEL_MASK) {
        case PKT_TX_TUNNEL_VXLAN_GPE:
        case PKT_TX_TUNNEL_GENEVE:
        case PKT_TX_TUNNEL_VXLAN:
                /* MAC in UDP tunnelling packet, include VxLAN and GENEVE */
                tmp_outer |= hns3_gen_field_val(HNS3_TXD_TUNTYPE_M,
                                HNS3_TXD_TUNTYPE_S, HNS3_TUN_MAC_IN_UDP);
                /*
                 * The inner l2 length of mbuf is the sum of outer l4 length,
                 * tunneling header length and inner l2 length for a tunnel
                 * packect. But in hns3 tx descriptor, the tunneling header
                 * length is contained in the field of outer L4 length.
                 * Therefore, driver need to calculate the outer L4 length and
                 * inner L2 length.
                 */
                tmp_outer |= hns3_gen_field_val(HNS3_TXD_L4LEN_M,
                                                HNS3_TXD_L4LEN_S,
                                                (uint8_t)RTE_ETHER_VXLAN_HLEN >>
                                                HNS3_L4_LEN_UNIT);

                inner_l2_len = m->l2_len - RTE_ETHER_VXLAN_HLEN;
                break;
        case PKT_TX_TUNNEL_GRE:
                tmp_outer |= hns3_gen_field_val(HNS3_TXD_TUNTYPE_M,
                                        HNS3_TXD_TUNTYPE_S, HNS3_TUN_NVGRE);
                /*
                 * For NVGRE tunnel packect, the outer L4 is empty. So only
                 * fill the NVGRE header length to the outer L4 field.
                 */
                tmp_outer |= hns3_gen_field_val(HNS3_TXD_L4LEN_M,
                                HNS3_TXD_L4LEN_S,
                                (uint8_t)HNS3_NVGRE_HLEN >> HNS3_L4_LEN_UNIT);

                inner_l2_len = m->l2_len - HNS3_NVGRE_HLEN;
                break;
        default:
                /* For non UDP / GRE tunneling, drop the tunnel packet */
                return -EINVAL;
        }

        tmp_inner |= hns3_gen_field_val(HNS3_TXD_L2LEN_M, HNS3_TXD_L2LEN_S,
                                        inner_l2_len >> HNS3_L2_LEN_UNIT);
        /* OL2 header size, defined in 2 bytes */
        tmp_outer |= hns3_gen_field_val(HNS3_TXD_L2LEN_M, HNS3_TXD_L2LEN_S,
                                        m->outer_l2_len >> HNS3_L2_LEN_UNIT);

        *type_cs_vlan_tso_len = tmp_inner;
        *ol_type_vlan_len_msec = tmp_outer;

        return 0;
}

static int
hns3_parse_tunneling_params(struct hns3_tx_queue *txq, struct rte_mbuf *m,
                            uint16_t tx_desc_id)
{
        struct hns3_desc *tx_ring = txq->tx_ring;
        struct hns3_desc *desc = &tx_ring[tx_desc_id];
        uint64_t ol_flags = m->ol_flags;
        uint32_t tmp_outer = 0;
        uint32_t tmp_inner = 0;
        uint32_t tmp_ol4cs;
        int ret;

        /*
         * The tunnel header is contained in the inner L2 header field of the
         * mbuf, but for hns3 descriptor, it is contained in the outer L4. So,
         * there is a need that switching between them. To avoid multiple
         * calculations, the length of the L2 header include the outer and
         * inner, will be filled during the parsing of tunnel packects.
         */
        if (!(ol_flags & PKT_TX_TUNNEL_MASK)) {
                /*
                 * For non tunnel type the tunnel type id is 0, so no need to
                 * assign a value to it. Only the inner(normal) L2 header length
                 * is assigned.
                 */
                tmp_inner |= hns3_gen_field_val(HNS3_TXD_L2LEN_M,
                               HNS3_TXD_L2LEN_S, m->l2_len >> HNS3_L2_LEN_UNIT);
        } else {
                /*
                 * If outer csum is not offload, the outer length may be filled
                 * with 0. And the length of the outer header is added to the
                 * inner l2_len. It would lead a cksum error. So driver has to
                 * calculate the header length.
                 */
                if (unlikely(!(ol_flags &
                        (PKT_TX_OUTER_IP_CKSUM | PKT_TX_OUTER_UDP_CKSUM)) &&
                                        m->outer_l2_len == 0)) {
                        struct rte_net_hdr_lens hdr_len;
                        (void)rte_net_get_ptype(m, &hdr_len,
                                        RTE_PTYPE_L2_MASK | RTE_PTYPE_L3_MASK);
                        m->outer_l3_len = hdr_len.l3_len;
                        m->outer_l2_len = hdr_len.l2_len;
                        m->l2_len = m->l2_len - hdr_len.l2_len - hdr_len.l3_len;
                }
                hns3_parse_outer_params(m, &tmp_outer);
                ret = hns3_parse_inner_params(m, &tmp_outer, &tmp_inner);
                if (ret)
                        return -EINVAL;
        }

        desc->tx.ol_type_vlan_len_msec = rte_cpu_to_le_32(tmp_outer);
        desc->tx.type_cs_vlan_tso_len = rte_cpu_to_le_32(tmp_inner);
        tmp_ol4cs = ol_flags & PKT_TX_OUTER_UDP_CKSUM ?
                        BIT(HNS3_TXD_OL4CS_B) : 0;
        desc->tx.paylen_fd_dop_ol4cs = rte_cpu_to_le_32(tmp_ol4cs);

        return 0;
}

static void
hns3_parse_l3_cksum_params(struct rte_mbuf *m, uint32_t *type_cs_vlan_tso_len)
{
        uint64_t ol_flags = m->ol_flags;
        uint32_t l3_type;
        uint32_t tmp;

        tmp = *type_cs_vlan_tso_len;
        if (ol_flags & PKT_TX_IPV4)
                l3_type = HNS3_L3T_IPV4;
        else if (ol_flags & PKT_TX_IPV6)
                l3_type = HNS3_L3T_IPV6;
        else
                l3_type = HNS3_L3T_NONE;

        /* inner(/normal) L3 header size, defined in 4 bytes */
        tmp |= hns3_gen_field_val(HNS3_TXD_L3LEN_M, HNS3_TXD_L3LEN_S,
                                        m->l3_len >> HNS3_L3_LEN_UNIT);

        tmp |= hns3_gen_field_val(HNS3_TXD_L3T_M, HNS3_TXD_L3T_S, l3_type);

        /* Enable L3 checksum offloads */
        if (ol_flags & PKT_TX_IP_CKSUM)
                tmp |= BIT(HNS3_TXD_L3CS_B);
        *type_cs_vlan_tso_len = tmp;
}

static void
hns3_parse_l4_cksum_params(struct rte_mbuf *m, uint32_t *type_cs_vlan_tso_len)
{
        uint64_t ol_flags = m->ol_flags;
        uint32_t tmp;
        /* Enable L4 checksum offloads */
        switch (ol_flags & (PKT_TX_L4_MASK | PKT_TX_TCP_SEG)) {
        case PKT_TX_TCP_CKSUM | PKT_TX_TCP_SEG:
        case PKT_TX_TCP_CKSUM:
        case PKT_TX_TCP_SEG:
                tmp = *type_cs_vlan_tso_len;
                tmp |= hns3_gen_field_val(HNS3_TXD_L4T_M, HNS3_TXD_L4T_S,
                                        HNS3_L4T_TCP);
                break;
        case PKT_TX_UDP_CKSUM:
                tmp = *type_cs_vlan_tso_len;
                tmp |= hns3_gen_field_val(HNS3_TXD_L4T_M, HNS3_TXD_L4T_S,
                                        HNS3_L4T_UDP);
                break;
        case PKT_TX_SCTP_CKSUM:
                tmp = *type_cs_vlan_tso_len;
                tmp |= hns3_gen_field_val(HNS3_TXD_L4T_M, HNS3_TXD_L4T_S,
                                        HNS3_L4T_SCTP);
                break;
        default:
                return;
        }
        tmp |= BIT(HNS3_TXD_L4CS_B);
        tmp |= hns3_gen_field_val(HNS3_TXD_L4LEN_M, HNS3_TXD_L4LEN_S,
                                        m->l4_len >> HNS3_L4_LEN_UNIT);
        *type_cs_vlan_tso_len = tmp;
}

static void
hns3_txd_enable_checksum(struct hns3_tx_queue *txq, struct rte_mbuf *m,
                         uint16_t tx_desc_id)
{
        struct hns3_desc *tx_ring = txq->tx_ring;
        struct hns3_desc *desc = &tx_ring[tx_desc_id];
        uint32_t value = 0;

        hns3_parse_l3_cksum_params(m, &value);
        hns3_parse_l4_cksum_params(m, &value);

        desc->tx.type_cs_vlan_tso_len |= rte_cpu_to_le_32(value);
}

static bool
hns3_pkt_need_linearized(struct rte_mbuf *tx_pkts, uint32_t bd_num,
                                 uint32_t max_non_tso_bd_num)
{
        struct rte_mbuf *m_first = tx_pkts;
        struct rte_mbuf *m_last = tx_pkts;
        uint32_t tot_len = 0;
        uint32_t hdr_len;
        uint32_t i;

        /*
         * Hardware requires that the sum of the data length of every 8
         * consecutive buffers is greater than MSS in hns3 network engine.
         * We simplify it by ensuring pkt_headlen + the first 8 consecutive
         * frags greater than gso header len + mss, and the remaining 7
         * consecutive frags greater than MSS except the last 7 frags.
         */
        if (bd_num <= max_non_tso_bd_num)
                return false;

        for (i = 0; m_last && i < max_non_tso_bd_num - 1;
             i++, m_last = m_last->next)
                tot_len += m_last->data_len;

        if (!m_last)
                return true;

        /* ensure the first 8 frags is greater than mss + header */
        hdr_len = tx_pkts->l2_len + tx_pkts->l3_len + tx_pkts->l4_len;
        hdr_len += (tx_pkts->ol_flags & PKT_TX_TUNNEL_MASK) ?
                   tx_pkts->outer_l2_len + tx_pkts->outer_l3_len : 0;
        if (tot_len + m_last->data_len < tx_pkts->tso_segsz + hdr_len)
                return true;

        /*
         * ensure the sum of the data length of every 7 consecutive buffer
         * is greater than mss except the last one.
         */
        for (i = 0; m_last && i < bd_num - max_non_tso_bd_num; i++) {
                tot_len -= m_first->data_len;
                tot_len += m_last->data_len;

                if (tot_len < tx_pkts->tso_segsz)
                        return true;

                m_first = m_first->next;
                m_last = m_last->next;
        }

        return false;
}

static bool
hns3_outer_ipv4_cksum_prepared(struct rte_mbuf *m, uint64_t ol_flags,
                                uint32_t *l4_proto)
{
        struct rte_ipv4_hdr *ipv4_hdr;
        ipv4_hdr = rte_pktmbuf_mtod_offset(m, struct rte_ipv4_hdr *,
                                           m->outer_l2_len);
        if (ol_flags & PKT_TX_OUTER_IP_CKSUM)
                ipv4_hdr->hdr_checksum = 0;
        if (ol_flags & PKT_TX_OUTER_UDP_CKSUM) {
                struct rte_udp_hdr *udp_hdr;
                /*
                 * If OUTER_UDP_CKSUM is support, HW can caclulate the pseudo
                 * header for TSO packets
                 */
                if (ol_flags & PKT_TX_TCP_SEG)
                        return true;
                udp_hdr = rte_pktmbuf_mtod_offset(m, struct rte_udp_hdr *,
                                m->outer_l2_len + m->outer_l3_len);
                udp_hdr->dgram_cksum = rte_ipv4_phdr_cksum(ipv4_hdr, ol_flags);

                return true;
        }
        *l4_proto = ipv4_hdr->next_proto_id;
        return false;
}

static bool
hns3_outer_ipv6_cksum_prepared(struct rte_mbuf *m, uint64_t ol_flags,
                                uint32_t *l4_proto)
{
        struct rte_ipv6_hdr *ipv6_hdr;
        ipv6_hdr = rte_pktmbuf_mtod_offset(m, struct rte_ipv6_hdr *,
                                           m->outer_l2_len);
        if (ol_flags & PKT_TX_OUTER_UDP_CKSUM) {
                struct rte_udp_hdr *udp_hdr;
                /*
                 * If OUTER_UDP_CKSUM is support, HW can caclulate the pseudo
                 * header for TSO packets
                 */
                if (ol_flags & PKT_TX_TCP_SEG)
                        return true;
                udp_hdr = rte_pktmbuf_mtod_offset(m, struct rte_udp_hdr *,
                                m->outer_l2_len + m->outer_l3_len);
                udp_hdr->dgram_cksum = rte_ipv6_phdr_cksum(ipv6_hdr, ol_flags);

                return true;
        }
        *l4_proto = ipv6_hdr->proto;
        return false;
}

static void
hns3_outer_header_cksum_prepare(struct rte_mbuf *m)
{
        uint64_t ol_flags = m->ol_flags;
        uint32_t paylen, hdr_len, l4_proto;
        struct rte_udp_hdr *udp_hdr;

        if (!(ol_flags & (PKT_TX_OUTER_IPV4 | PKT_TX_OUTER_IPV6)))
                return;

        if (ol_flags & PKT_TX_OUTER_IPV4) {
                if (hns3_outer_ipv4_cksum_prepared(m, ol_flags, &l4_proto))
                        return;
        } else {
                if (hns3_outer_ipv6_cksum_prepared(m, ol_flags, &l4_proto))
                        return;
        }

        /* driver should ensure the outer udp cksum is 0 for TUNNEL TSO */
        if (l4_proto == IPPROTO_UDP && (ol_flags & PKT_TX_TCP_SEG)) {
                hdr_len = m->l2_len + m->l3_len + m->l4_len;
                hdr_len += m->outer_l2_len + m->outer_l3_len;
                paylen = m->pkt_len - hdr_len;
                if (paylen <= m->tso_segsz)
                        return;
                udp_hdr = rte_pktmbuf_mtod_offset(m, struct rte_udp_hdr *,
                                                  m->outer_l2_len +
                                                  m->outer_l3_len);
                udp_hdr->dgram_cksum = 0;
        }
}

static int
hns3_check_tso_pkt_valid(struct rte_mbuf *m)
{
        uint32_t tmp_data_len_sum = 0;
        uint16_t nb_buf = m->nb_segs;
        uint32_t paylen, hdr_len;
        struct rte_mbuf *m_seg;
        int i;

        if (nb_buf > HNS3_MAX_TSO_BD_PER_PKT)
                return -EINVAL;

        hdr_len = m->l2_len + m->l3_len + m->l4_len;
        hdr_len += (m->ol_flags & PKT_TX_TUNNEL_MASK) ?
                        m->outer_l2_len + m->outer_l3_len : 0;
        if (hdr_len > HNS3_MAX_TSO_HDR_SIZE)
                return -EINVAL;

        paylen = m->pkt_len - hdr_len;
        if (paylen > HNS3_MAX_BD_PAYLEN)
                return -EINVAL;

        /*
         * The TSO header (include outer and inner L2, L3 and L4 header)
         * should be provided by three descriptors in maximum in hns3 network
         * engine.
         */
        m_seg = m;
        for (i = 0; m_seg != NULL && i < HNS3_MAX_TSO_HDR_BD_NUM && i < nb_buf;
             i++, m_seg = m_seg->next) {
                tmp_data_len_sum += m_seg->data_len;
        }

        if (hdr_len > tmp_data_len_sum)
                return -EINVAL;

        return 0;
}

#ifdef RTE_LIBRTE_ETHDEV_DEBUG
static inline int
hns3_vld_vlan_chk(struct hns3_tx_queue *txq, struct rte_mbuf *m)
{
        struct rte_ether_hdr *eh;
        struct rte_vlan_hdr *vh;

        if (!txq->pvid_sw_shift_en)
                return 0;

        /*
         * Due to hardware limitations, we only support two-layer VLAN hardware
         * offload in Tx direction based on hns3 network engine, so when PVID is
         * enabled, QinQ insert is no longer supported.
         * And when PVID is enabled, in the following two cases:
         *  i) packets with more than two VLAN tags.
         *  ii) packets with one VLAN tag while the hardware VLAN insert is
         *      enabled.
         * The packets will be regarded as abnormal packets and discarded by
         * hardware in Tx direction. For debugging purposes, a validation check
         * for these types of packets is added to the '.tx_pkt_prepare' ops
         * implementation function named hns3_prep_pkts to inform users that
         * these packets will be discarded.
         */
        if (m->ol_flags & PKT_TX_QINQ_PKT)
                return -EINVAL;

        eh = rte_pktmbuf_mtod(m, struct rte_ether_hdr *);
        if (eh->ether_type == rte_cpu_to_be_16(RTE_ETHER_TYPE_VLAN)) {
                if (m->ol_flags & PKT_TX_VLAN_PKT)
                        return -EINVAL;

                /* Ensure the incoming packet is not a QinQ packet */
                vh = (struct rte_vlan_hdr *)(eh + 1);
                if (vh->eth_proto == rte_cpu_to_be_16(RTE_ETHER_TYPE_VLAN))
                        return -EINVAL;
        }

        return 0;
}
#endif

static uint16_t
hns3_udp_cksum_help(struct rte_mbuf *m)
{
        uint64_t ol_flags = m->ol_flags;
        uint16_t cksum = 0;
        uint32_t l4_len;

        if (ol_flags & PKT_TX_IPV4) {
                struct rte_ipv4_hdr *ipv4_hdr = rte_pktmbuf_mtod_offset(m,
                                struct rte_ipv4_hdr *, m->l2_len);
                l4_len = rte_be_to_cpu_16(ipv4_hdr->total_length) - m->l3_len;
        } else {
                struct rte_ipv6_hdr *ipv6_hdr = rte_pktmbuf_mtod_offset(m,
                                struct rte_ipv6_hdr *, m->l2_len);
                l4_len = rte_be_to_cpu_16(ipv6_hdr->payload_len);
        }

        rte_raw_cksum_mbuf(m, m->l2_len + m->l3_len, l4_len, &cksum);

        cksum = ~cksum;
        /*
         * RFC 768:If the computed checksum is zero for UDP, it is transmitted
         * as all ones
         */
        if (cksum == 0)
                cksum = 0xffff;

        return (uint16_t)cksum;
}

static bool
hns3_validate_tunnel_cksum(struct hns3_tx_queue *tx_queue, struct rte_mbuf *m)
{
        uint64_t ol_flags = m->ol_flags;
        struct rte_udp_hdr *udp_hdr;
        uint16_t dst_port;

        if (tx_queue->udp_cksum_mode == HNS3_SPECIAL_PORT_HW_CKSUM_MODE ||
            ol_flags & PKT_TX_TUNNEL_MASK ||
            (ol_flags & PKT_TX_L4_MASK) != PKT_TX_UDP_CKSUM)
                return true;
        /*
         * A UDP packet with the same dst_port as VXLAN\VXLAN_GPE\GENEVE will
         * be recognized as a tunnel packet in HW. In this case, if UDP CKSUM
         * offload is set and the tunnel mask has not been set, the CKSUM will
         * be wrong since the header length is wrong and driver should complete
         * the CKSUM to avoid CKSUM error.
         */
        udp_hdr = rte_pktmbuf_mtod_offset(m, struct rte_udp_hdr *,
                                                m->l2_len + m->l3_len);
        dst_port = rte_be_to_cpu_16(udp_hdr->dst_port);
        switch (dst_port) {
        case RTE_VXLAN_DEFAULT_PORT:
        case RTE_VXLAN_GPE_DEFAULT_PORT:
        case RTE_GENEVE_DEFAULT_PORT:
                udp_hdr->dgram_cksum = hns3_udp_cksum_help(m);
                m->ol_flags = ol_flags & ~PKT_TX_L4_MASK;
                return false;
        default:
                return true;
        }
}

static int
hns3_prep_pkt_proc(struct hns3_tx_queue *tx_queue, struct rte_mbuf *m)
{
        int ret;

#ifdef RTE_LIBRTE_ETHDEV_DEBUG
        ret = rte_validate_tx_offload(m);
        if (ret != 0) {
                rte_errno = -ret;
                return ret;
        }

        ret = hns3_vld_vlan_chk(tx_queue, m);
        if (ret != 0) {
                rte_errno = EINVAL;
                return ret;
        }
#endif
        if (hns3_pkt_is_tso(m)) {
                if (hns3_pkt_need_linearized(m, m->nb_segs,
                                             tx_queue->max_non_tso_bd_num) ||
                    hns3_check_tso_pkt_valid(m)) {
                        rte_errno = EINVAL;
                        return -EINVAL;
                }

                if (tx_queue->tso_mode != HNS3_TSO_SW_CAL_PSEUDO_H_CSUM) {
                        /*
                         * (tso mode != HNS3_TSO_SW_CAL_PSEUDO_H_CSUM) means
                         * hardware support recalculate the TCP pseudo header
                         * checksum of packets that need TSO, so network driver
                         * software not need to recalculate it.
                         */
                        hns3_outer_header_cksum_prepare(m);
                        return 0;
                }
        }

        ret = rte_net_intel_cksum_prepare(m);
        if (ret != 0) {
                rte_errno = -ret;
                return ret;
        }

        if (!hns3_validate_tunnel_cksum(tx_queue, m))
                return 0;

        hns3_outer_header_cksum_prepare(m);

        return 0;
}

uint16_t
hns3_prep_pkts(__rte_unused void *tx_queue, struct rte_mbuf **tx_pkts,
               uint16_t nb_pkts)
{
        struct rte_mbuf *m;
        uint16_t i;

        for (i = 0; i < nb_pkts; i++) {
                m = tx_pkts[i];
                if (hns3_prep_pkt_proc(tx_queue, m))
                        return i;
        }

        return i;
}

static int
hns3_parse_cksum(struct hns3_tx_queue *txq, uint16_t tx_desc_id,
                 struct rte_mbuf *m)
{
        struct hns3_desc *tx_ring = txq->tx_ring;
        struct hns3_desc *desc = &tx_ring[tx_desc_id];

        /* Enable checksum offloading */
        if (m->ol_flags & HNS3_TX_CKSUM_OFFLOAD_MASK) {
                /* Fill in tunneling parameters if necessary */
                if (hns3_parse_tunneling_params(txq, m, tx_desc_id)) {
                        txq->dfx_stats.unsupported_tunnel_pkt_cnt++;
                                return -EINVAL;
                }

                hns3_txd_enable_checksum(txq, m, tx_desc_id);
        } else {
                /* clear the control bit */
                desc->tx.type_cs_vlan_tso_len  = 0;
                desc->tx.ol_type_vlan_len_msec = 0;
        }

        return 0;
}

static int
hns3_check_non_tso_pkt(uint16_t nb_buf, struct rte_mbuf **m_seg,
                      struct rte_mbuf *tx_pkt, struct hns3_tx_queue *txq)
{
        uint8_t max_non_tso_bd_num;
        struct rte_mbuf *new_pkt;
        int ret;

        if (hns3_pkt_is_tso(*m_seg))
                return 0;

        /*
         * If packet length is greater than HNS3_MAX_FRAME_LEN
         * driver support, the packet will be ignored.
         */
        if (unlikely(rte_pktmbuf_pkt_len(tx_pkt) > HNS3_MAX_FRAME_LEN)) {
                txq->dfx_stats.over_length_pkt_cnt++;
                return -EINVAL;
        }

        max_non_tso_bd_num = txq->max_non_tso_bd_num;
        if (unlikely(nb_buf > max_non_tso_bd_num)) {
                txq->dfx_stats.exceed_limit_bd_pkt_cnt++;
                ret = hns3_reassemble_tx_pkts(tx_pkt, &new_pkt,
                                              max_non_tso_bd_num);
                if (ret) {
                        txq->dfx_stats.exceed_limit_bd_reassem_fail++;
                        return ret;
                }
                *m_seg = new_pkt;
        }

        return 0;
}

static inline void
hns3_tx_free_buffer_simple(struct hns3_tx_queue *txq)
{
        struct hns3_entry *tx_entry;
        struct hns3_desc *desc;
        uint16_t tx_next_clean;
        int i;

        while (1) {
                if (HNS3_GET_TX_QUEUE_PEND_BD_NUM(txq) < txq->tx_rs_thresh)
                        break;

                /*
                 * All mbufs can be released only when the VLD bits of all
                 * descriptors in a batch are cleared.
                 */
                tx_next_clean = (txq->next_to_clean + txq->tx_rs_thresh - 1) %
                                txq->nb_tx_desc;
                desc = &txq->tx_ring[tx_next_clean];
                for (i = 0; i < txq->tx_rs_thresh; i++) {
                        if (rte_le_to_cpu_16(desc->tx.tp_fe_sc_vld_ra_ri) &
                                        BIT(HNS3_TXD_VLD_B))
                                return;
                        desc--;
                }

                tx_entry = &txq->sw_ring[txq->next_to_clean];

                for (i = 0; i < txq->tx_rs_thresh; i++)
                        rte_prefetch0((tx_entry + i)->mbuf);
                for (i = 0; i < txq->tx_rs_thresh; i++, tx_entry++) {
                        rte_mempool_put(tx_entry->mbuf->pool, tx_entry->mbuf);
                        tx_entry->mbuf = NULL;
                }

                txq->next_to_clean = (tx_next_clean + 1) % txq->nb_tx_desc;
                txq->tx_bd_ready += txq->tx_rs_thresh;
        }
}

static inline void
hns3_tx_backup_1mbuf(struct hns3_entry *tx_entry, struct rte_mbuf **pkts)
{
        tx_entry->mbuf = pkts[0];
}

static inline void
hns3_tx_backup_4mbuf(struct hns3_entry *tx_entry, struct rte_mbuf **pkts)
{
        hns3_tx_backup_1mbuf(&tx_entry[0], &pkts[0]);
        hns3_tx_backup_1mbuf(&tx_entry[1], &pkts[1]);
        hns3_tx_backup_1mbuf(&tx_entry[2], &pkts[2]);
        hns3_tx_backup_1mbuf(&tx_entry[3], &pkts[3]);
}

static inline void
hns3_tx_setup_4bd(struct hns3_desc *txdp, struct rte_mbuf **pkts)
{
#define PER_LOOP_NUM    4
        const uint16_t bd_flag = BIT(HNS3_TXD_VLD_B) | BIT(HNS3_TXD_FE_B);
        uint64_t dma_addr;
        uint32_t i;

        for (i = 0; i < PER_LOOP_NUM; i++, txdp++, pkts++) {
                dma_addr = rte_mbuf_data_iova(*pkts);
                txdp->addr = rte_cpu_to_le_64(dma_addr);
                txdp->tx.send_size = rte_cpu_to_le_16((*pkts)->data_len);
                txdp->tx.paylen_fd_dop_ol4cs = 0;
                txdp->tx.type_cs_vlan_tso_len = 0;
                txdp->tx.ol_type_vlan_len_msec = 0;
                txdp->tx.tp_fe_sc_vld_ra_ri = rte_cpu_to_le_16(bd_flag);
        }
}

static inline void
hns3_tx_setup_1bd(struct hns3_desc *txdp, struct rte_mbuf **pkts)
{
        const uint16_t bd_flag = BIT(HNS3_TXD_VLD_B) | BIT(HNS3_TXD_FE_B);
        uint64_t dma_addr;

        dma_addr = rte_mbuf_data_iova(*pkts);
        txdp->addr = rte_cpu_to_le_64(dma_addr);
        txdp->tx.send_size = rte_cpu_to_le_16((*pkts)->data_len);
        txdp->tx.paylen_fd_dop_ol4cs = 0;
        txdp->tx.type_cs_vlan_tso_len = 0;
        txdp->tx.ol_type_vlan_len_msec = 0;
        txdp->tx.tp_fe_sc_vld_ra_ri = rte_cpu_to_le_16(bd_flag);
}

static inline void
hns3_tx_fill_hw_ring(struct hns3_tx_queue *txq,
                     struct rte_mbuf **pkts,
                     uint16_t nb_pkts)
{
#define PER_LOOP_NUM    4
#define PER_LOOP_MASK   (PER_LOOP_NUM - 1)
        struct hns3_desc *txdp = &txq->tx_ring[txq->next_to_use];
        struct hns3_entry *tx_entry = &txq->sw_ring[txq->next_to_use];
        const uint32_t mainpart = (nb_pkts & ((uint32_t)~PER_LOOP_MASK));
        const uint32_t leftover = (nb_pkts & ((uint32_t)PER_LOOP_MASK));
        uint32_t i;

        for (i = 0; i < mainpart; i += PER_LOOP_NUM) {
                hns3_tx_backup_4mbuf(tx_entry + i, pkts + i);
                hns3_tx_setup_4bd(txdp + i, pkts + i);

                /* Increment bytes counter */
                uint32_t j;
                for (j = 0; j < PER_LOOP_NUM; j++)
                        txq->basic_stats.bytes += pkts[i + j]->pkt_len;
        }
        if (unlikely(leftover > 0)) {
                for (i = 0; i < leftover; i++) {
                        hns3_tx_backup_1mbuf(tx_entry + mainpart + i,
                                             pkts + mainpart + i);
                        hns3_tx_setup_1bd(txdp + mainpart + i,
                                          pkts + mainpart + i);

                        /* Increment bytes counter */
                        txq->basic_stats.bytes += pkts[mainpart + i]->pkt_len;
                }
        }
}

uint16_t
hns3_xmit_pkts_simple(void *tx_queue,
                      struct rte_mbuf **tx_pkts,
                      uint16_t nb_pkts)
{
        struct hns3_tx_queue *txq = tx_queue;
        uint16_t nb_tx = 0;

        hns3_tx_free_buffer_simple(txq);

        nb_pkts = RTE_MIN(txq->tx_bd_ready, nb_pkts);
        if (unlikely(nb_pkts == 0)) {
                if (txq->tx_bd_ready == 0)
                        txq->dfx_stats.queue_full_cnt++;
                return 0;
        }

        txq->tx_bd_ready -= nb_pkts;
        if (txq->next_to_use + nb_pkts > txq->nb_tx_desc) {
                nb_tx = txq->nb_tx_desc - txq->next_to_use;
                hns3_tx_fill_hw_ring(txq, tx_pkts, nb_tx);
                txq->next_to_use = 0;
        }

        hns3_tx_fill_hw_ring(txq, tx_pkts + nb_tx, nb_pkts - nb_tx);
        txq->next_to_use += nb_pkts - nb_tx;

        hns3_write_reg_opt(txq->io_tail_reg, nb_pkts);

        return nb_pkts;
}

uint16_t
hns3_xmit_pkts(void *tx_queue, struct rte_mbuf **tx_pkts, uint16_t nb_pkts)
{
        struct hns3_tx_queue *txq = tx_queue;
        struct hns3_entry *tx_bak_pkt;
        struct hns3_desc *tx_ring;
        struct rte_mbuf *tx_pkt;
        struct rte_mbuf *m_seg;
        struct hns3_desc *desc;
        uint32_t nb_hold = 0;
        uint16_t tx_next_use;
        uint16_t tx_pkt_num;
        uint16_t tx_bd_max;
        uint16_t nb_buf;
        uint16_t nb_tx;
        uint16_t i;

        /* free useless buffer */
        hns3_tx_free_useless_buffer(txq);

        tx_next_use   = txq->next_to_use;
        tx_bd_max     = txq->nb_tx_desc;
        tx_pkt_num = nb_pkts;
        tx_ring = txq->tx_ring;

        /* send packets */
        tx_bak_pkt = &txq->sw_ring[tx_next_use];
        for (nb_tx = 0; nb_tx < tx_pkt_num; nb_tx++) {
                tx_pkt = *tx_pkts++;

                nb_buf = tx_pkt->nb_segs;

                if (nb_buf > txq->tx_bd_ready) {
                        txq->dfx_stats.queue_full_cnt++;
                        if (nb_tx == 0)
                                return 0;

                        goto end_of_tx;
                }

                /*
                 * If packet length is less than minimum packet length supported
                 * by hardware in Tx direction, driver need to pad it to avoid
                 * error.
                 */
                if (unlikely(rte_pktmbuf_pkt_len(tx_pkt) <
                                                txq->min_tx_pkt_len)) {
                        uint16_t add_len;
                        char *appended;

                        add_len = txq->min_tx_pkt_len -
                                         rte_pktmbuf_pkt_len(tx_pkt);
                        appended = rte_pktmbuf_append(tx_pkt, add_len);
                        if (appended == NULL) {
                                txq->dfx_stats.pkt_padding_fail_cnt++;
                                break;
                        }

                        memset(appended, 0, add_len);
                }

                m_seg = tx_pkt;

                if (hns3_check_non_tso_pkt(nb_buf, &m_seg, tx_pkt, txq))
                        goto end_of_tx;

                if (hns3_parse_cksum(txq, tx_next_use, m_seg))
                        goto end_of_tx;

                i = 0;
                desc = &tx_ring[tx_next_use];

                /*
                 * If the packet is divided into multiple Tx Buffer Descriptors,
                 * only need to fill vlan, paylen and tso into the first Tx
                 * Buffer Descriptor.
                 */
                hns3_fill_first_desc(txq, desc, m_seg);

                do {
                        desc = &tx_ring[tx_next_use];
                        /*
                         * Fill valid bits, DMA address and data length for each
                         * Tx Buffer Descriptor.
                         */
                        hns3_fill_per_desc(desc, m_seg);
                        tx_bak_pkt->mbuf = m_seg;
                        m_seg = m_seg->next;
                        tx_next_use++;
                        tx_bak_pkt++;
                        if (tx_next_use >= tx_bd_max) {
                                tx_next_use = 0;
                                tx_bak_pkt = txq->sw_ring;
                        }

                        i++;
                } while (m_seg != NULL);

                /* Add end flag for the last Tx Buffer Descriptor */
                desc->tx.tp_fe_sc_vld_ra_ri |=
                                 rte_cpu_to_le_16(BIT(HNS3_TXD_FE_B));

                /* Increment bytes counter */
                txq->basic_stats.bytes += tx_pkt->pkt_len;
                nb_hold += i;
                txq->next_to_use = tx_next_use;
                txq->tx_bd_ready -= i;
        }

end_of_tx:

        if (likely(nb_tx))
                hns3_write_reg_opt(txq->io_tail_reg, nb_hold);

        return nb_tx;
}

int __rte_weak
hns3_tx_check_vec_support(__rte_unused struct rte_eth_dev *dev)
{
        return -ENOTSUP;
}

uint16_t __rte_weak
hns3_xmit_pkts_vec(__rte_unused void *tx_queue,
                   __rte_unused struct rte_mbuf **tx_pkts,
                   __rte_unused uint16_t nb_pkts)
{
        return 0;
}

uint16_t __rte_weak
hns3_xmit_pkts_vec_sve(void __rte_unused * tx_queue,
                       struct rte_mbuf __rte_unused **tx_pkts,
                       uint16_t __rte_unused nb_pkts)
{
        return 0;
}

int
hns3_tx_burst_mode_get(struct rte_eth_dev *dev, __rte_unused uint16_t queue_id,
                       struct rte_eth_burst_mode *mode)
{
        eth_tx_burst_t pkt_burst = dev->tx_pkt_burst;
        const char *info = NULL;

        if (pkt_burst == hns3_xmit_pkts_simple)
                info = "Scalar Simple";
        else if (pkt_burst == hns3_xmit_pkts)
                info = "Scalar";
        else if (pkt_burst == hns3_xmit_pkts_vec)
                info = "Vector Neon";
        else if (pkt_burst == hns3_xmit_pkts_vec_sve)
                info = "Vector Sve";

        if (info == NULL)
                return -EINVAL;

        snprintf(mode->info, sizeof(mode->info), "%s", info);

        return 0;
}

static bool
hns3_tx_check_simple_support(struct rte_eth_dev *dev)
{
        uint64_t offloads = dev->data->dev_conf.txmode.offloads;

        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        if (hns3_dev_ptp_supported(hw))
                return false;

        return (offloads == (offloads & DEV_TX_OFFLOAD_MBUF_FAST_FREE));
}

static eth_tx_burst_t
hns3_get_tx_function(struct rte_eth_dev *dev, eth_tx_prep_t *prep)
{
        struct hns3_adapter *hns = dev->data->dev_private;
        bool vec_allowed, sve_allowed, simple_allowed;

        vec_allowed = hns3_tx_check_vec_support(dev) == 0;
        sve_allowed = vec_allowed && hns3_check_sve_support();
        simple_allowed = hns3_tx_check_simple_support(dev);

        *prep = NULL;

        if (hns->tx_func_hint == HNS3_IO_FUNC_HINT_VEC && vec_allowed)
                return hns3_xmit_pkts_vec;
        if (hns->tx_func_hint == HNS3_IO_FUNC_HINT_SVE && sve_allowed)
                return hns3_xmit_pkts_vec_sve;
        if (hns->tx_func_hint == HNS3_IO_FUNC_HINT_SIMPLE && simple_allowed)
                return hns3_xmit_pkts_simple;
        if (hns->tx_func_hint == HNS3_IO_FUNC_HINT_COMMON) {
                *prep = hns3_prep_pkts;
                return hns3_xmit_pkts;
        }

        if (vec_allowed)
                return hns3_xmit_pkts_vec;
        if (simple_allowed)
                return hns3_xmit_pkts_simple;

        *prep = hns3_prep_pkts;
        return hns3_xmit_pkts;
}

static uint16_t
hns3_dummy_rxtx_burst(void *dpdk_txq __rte_unused,
                      struct rte_mbuf **pkts __rte_unused,
                      uint16_t pkts_n __rte_unused)
{
        return 0;
}

static void
hns3_trace_rxtx_function(struct rte_eth_dev *dev)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct rte_eth_burst_mode rx_mode;
        struct rte_eth_burst_mode tx_mode;

        memset(&rx_mode, 0, sizeof(rx_mode));
        memset(&tx_mode, 0, sizeof(tx_mode));
        (void)hns3_rx_burst_mode_get(dev, 0, &rx_mode);
        (void)hns3_tx_burst_mode_get(dev, 0, &tx_mode);

        hns3_dbg(hw, "using rx_pkt_burst: %s, tx_pkt_burst: %s.",
                 rx_mode.info, tx_mode.info);
}

void hns3_set_rxtx_function(struct rte_eth_dev *eth_dev)
{
        struct hns3_adapter *hns = eth_dev->data->dev_private;
        eth_tx_prep_t prep = NULL;

        if (hns->hw.adapter_state == HNS3_NIC_STARTED &&
            __atomic_load_n(&hns->hw.reset.resetting, __ATOMIC_RELAXED) == 0) {
                eth_dev->rx_pkt_burst = hns3_get_rx_function(eth_dev);
                eth_dev->rx_descriptor_status = hns3_dev_rx_descriptor_status;
                eth_dev->tx_pkt_burst = hns3_get_tx_function(eth_dev, &prep);
                eth_dev->tx_pkt_prepare = prep;
                eth_dev->tx_descriptor_status = hns3_dev_tx_descriptor_status;
                hns3_trace_rxtx_function(eth_dev);
        } else {
                eth_dev->rx_pkt_burst = hns3_dummy_rxtx_burst;
                eth_dev->tx_pkt_burst = hns3_dummy_rxtx_burst;
                eth_dev->tx_pkt_prepare = hns3_dummy_rxtx_burst;
        }
}

void
hns3_rxq_info_get(struct rte_eth_dev *dev, uint16_t queue_id,
                  struct rte_eth_rxq_info *qinfo)
{
        struct hns3_rx_queue *rxq = dev->data->rx_queues[queue_id];

        qinfo->mp = rxq->mb_pool;
        qinfo->nb_desc = rxq->nb_rx_desc;
        qinfo->scattered_rx = dev->data->scattered_rx;
        /* Report the HW Rx buffer length to user */
        qinfo->rx_buf_size = rxq->rx_buf_len;

        /*
         * If there are no available Rx buffer descriptors, incoming packets
         * are always dropped by hardware based on hns3 network engine.
         */
        qinfo->conf.rx_drop_en = 1;
        qinfo->conf.offloads = dev->data->dev_conf.rxmode.offloads;
        qinfo->conf.rx_free_thresh = rxq->rx_free_thresh;
        qinfo->conf.rx_deferred_start = rxq->rx_deferred_start;
}

void
hns3_txq_info_get(struct rte_eth_dev *dev, uint16_t queue_id,
                  struct rte_eth_txq_info *qinfo)
{
        struct hns3_tx_queue *txq = dev->data->tx_queues[queue_id];

        qinfo->nb_desc = txq->nb_tx_desc;
        qinfo->conf.offloads = dev->data->dev_conf.txmode.offloads;
        qinfo->conf.tx_rs_thresh = txq->tx_rs_thresh;
        qinfo->conf.tx_free_thresh = txq->tx_free_thresh;
        qinfo->conf.tx_deferred_start = txq->tx_deferred_start;
}

int
hns3_dev_rx_queue_start(struct rte_eth_dev *dev, uint16_t rx_queue_id)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_rx_queue *rxq = dev->data->rx_queues[rx_queue_id];
        struct hns3_adapter *hns = HNS3_DEV_HW_TO_ADAPTER(hw);
        int ret;

        if (!hns3_dev_indep_txrx_supported(hw))
                return -ENOTSUP;

        ret = hns3_reset_queue(hw, rx_queue_id, HNS3_RING_TYPE_RX);
        if (ret) {
                hns3_err(hw, "fail to reset Rx queue %u, ret = %d.",
                         rx_queue_id, ret);
                return ret;
        }

        ret = hns3_init_rxq(hns, rx_queue_id);
        if (ret) {
                hns3_err(hw, "fail to init Rx queue %u, ret = %d.",
                         rx_queue_id, ret);
                return ret;
        }

        hns3_enable_rxq(rxq, true);
        dev->data->rx_queue_state[rx_queue_id] = RTE_ETH_QUEUE_STATE_STARTED;

        return ret;
}

static void
hns3_reset_sw_rxq(struct hns3_rx_queue *rxq)
{
        rxq->next_to_use = 0;
        rxq->rx_rearm_start = 0;
        rxq->rx_free_hold = 0;
        rxq->rx_rearm_nb = 0;
        rxq->pkt_first_seg = NULL;
        rxq->pkt_last_seg = NULL;
        memset(&rxq->rx_ring[0], 0, rxq->nb_rx_desc * sizeof(struct hns3_desc));
        hns3_rxq_vec_setup(rxq);
}

int
hns3_dev_rx_queue_stop(struct rte_eth_dev *dev, uint16_t rx_queue_id)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_rx_queue *rxq = dev->data->rx_queues[rx_queue_id];

        if (!hns3_dev_indep_txrx_supported(hw))
                return -ENOTSUP;

        hns3_enable_rxq(rxq, false);

        hns3_rx_queue_release_mbufs(rxq);

        hns3_reset_sw_rxq(rxq);
        dev->data->rx_queue_state[rx_queue_id] = RTE_ETH_QUEUE_STATE_STOPPED;

        return 0;
}

int
hns3_dev_tx_queue_start(struct rte_eth_dev *dev, uint16_t tx_queue_id)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_tx_queue *txq = dev->data->tx_queues[tx_queue_id];
        int ret;

        if (!hns3_dev_indep_txrx_supported(hw))
                return -ENOTSUP;

        ret = hns3_reset_queue(hw, tx_queue_id, HNS3_RING_TYPE_TX);
        if (ret) {
                hns3_err(hw, "fail to reset Tx queue %u, ret = %d.",
                         tx_queue_id, ret);
                return ret;
        }

        hns3_init_txq(txq);
        hns3_enable_txq(txq, true);
        dev->data->tx_queue_state[tx_queue_id] = RTE_ETH_QUEUE_STATE_STARTED;

        return ret;
}

int
hns3_dev_tx_queue_stop(struct rte_eth_dev *dev, uint16_t tx_queue_id)
{
        struct hns3_hw *hw = HNS3_DEV_PRIVATE_TO_HW(dev->data->dev_private);
        struct hns3_tx_queue *txq = dev->data->tx_queues[tx_queue_id];

        if (!hns3_dev_indep_txrx_supported(hw))
                return -ENOTSUP;

        hns3_enable_txq(txq, false);
        hns3_tx_queue_release_mbufs(txq);
        /*
         * All the mbufs in sw_ring are released and all the pointers in sw_ring
         * are set to NULL. If this queue is still called by upper layer,
         * residual SW status of this txq may cause these pointers in sw_ring
         * which have been set to NULL to be released again. To avoid it,
         * reinit the txq.
         */
        hns3_init_txq(txq);
        dev->data->tx_queue_state[tx_queue_id] = RTE_ETH_QUEUE_STATE_STOPPED;

        return 0;
}

static int
hns3_tx_done_cleanup_full(struct hns3_tx_queue *txq, uint32_t free_cnt)
{
        uint16_t next_to_clean = txq->next_to_clean;
        uint16_t next_to_use   = txq->next_to_use;
        uint16_t tx_bd_ready   = txq->tx_bd_ready;
        struct hns3_entry *tx_pkt = &txq->sw_ring[next_to_clean];
        struct hns3_desc *desc = &txq->tx_ring[next_to_clean];
        uint32_t idx;

        if (free_cnt == 0 || free_cnt > txq->nb_tx_desc)
                free_cnt = txq->nb_tx_desc;

        for (idx = 0; idx < free_cnt; idx++) {
                if (next_to_clean == next_to_use)
                        break;

                if (desc->tx.tp_fe_sc_vld_ra_ri &
                    rte_cpu_to_le_16(BIT(HNS3_TXD_VLD_B)))
                        break;

                if (tx_pkt->mbuf != NULL) {
                        rte_pktmbuf_free_seg(tx_pkt->mbuf);
                        tx_pkt->mbuf = NULL;
                }

                next_to_clean++;
                tx_bd_ready++;
                tx_pkt++;
                desc++;
                if (next_to_clean == txq->nb_tx_desc) {
                        tx_pkt = txq->sw_ring;
                        desc = txq->tx_ring;
                        next_to_clean = 0;
                }
        }

        if (idx > 0) {
                txq->next_to_clean = next_to_clean;
                txq->tx_bd_ready = tx_bd_ready;
        }

        return (int)idx;
}

int
hns3_tx_done_cleanup(void *txq, uint32_t free_cnt)
{
        struct hns3_tx_queue *q = (struct hns3_tx_queue *)txq;
        struct rte_eth_dev *dev = &rte_eth_devices[q->port_id];

        if (dev->tx_pkt_burst == hns3_xmit_pkts)
                return hns3_tx_done_cleanup_full(q, free_cnt);
        else if (dev->tx_pkt_burst == hns3_dummy_rxtx_burst)
                return 0;
        else
                return -ENOTSUP;
}

int
hns3_dev_rx_descriptor_status(void *rx_queue, uint16_t offset)
{
        volatile struct hns3_desc *rxdp;
        struct hns3_rx_queue *rxq;
        struct rte_eth_dev *dev;
        uint32_t bd_base_info;
        uint16_t desc_id;

        rxq = (struct hns3_rx_queue *)rx_queue;
        if (offset >= rxq->nb_rx_desc)
                return -EINVAL;

        desc_id = (rxq->next_to_use + offset) % rxq->nb_rx_desc;
        rxdp = &rxq->rx_ring[desc_id];
        bd_base_info = rte_le_to_cpu_32(rxdp->rx.bd_base_info);
        dev = &rte_eth_devices[rxq->port_id];
        if (dev->rx_pkt_burst == hns3_recv_pkts ||
            dev->rx_pkt_burst == hns3_recv_scattered_pkts) {
                if (offset >= rxq->nb_rx_desc - rxq->rx_free_hold)
                        return RTE_ETH_RX_DESC_UNAVAIL;
        } else if (dev->rx_pkt_burst == hns3_recv_pkts_vec ||
                   dev->rx_pkt_burst == hns3_recv_pkts_vec_sve) {
                if (offset >= rxq->nb_rx_desc - rxq->rx_rearm_nb)
                        return RTE_ETH_RX_DESC_UNAVAIL;
        } else {
                return RTE_ETH_RX_DESC_UNAVAIL;
        }

        if (!(bd_base_info & BIT(HNS3_RXD_VLD_B)))
                return RTE_ETH_RX_DESC_AVAIL;
        else
                return RTE_ETH_RX_DESC_DONE;
}

int
hns3_dev_tx_descriptor_status(void *tx_queue, uint16_t offset)
{
        volatile struct hns3_desc *txdp;
        struct hns3_tx_queue *txq;
        struct rte_eth_dev *dev;
        uint16_t desc_id;

        txq = (struct hns3_tx_queue *)tx_queue;
        if (offset >= txq->nb_tx_desc)
                return -EINVAL;

        dev = &rte_eth_devices[txq->port_id];
        if (dev->tx_pkt_burst != hns3_xmit_pkts_simple &&
            dev->tx_pkt_burst != hns3_xmit_pkts &&
            dev->tx_pkt_burst != hns3_xmit_pkts_vec_sve &&
            dev->tx_pkt_burst != hns3_xmit_pkts_vec)
                return RTE_ETH_TX_DESC_UNAVAIL;

        desc_id = (txq->next_to_use + offset) % txq->nb_tx_desc;
        txdp = &txq->tx_ring[desc_id];
        if (txdp->tx.tp_fe_sc_vld_ra_ri & rte_cpu_to_le_16(BIT(HNS3_TXD_VLD_B)))
                return RTE_ETH_TX_DESC_FULL;
        else
                return RTE_ETH_TX_DESC_DONE;
}

uint32_t
hns3_rx_queue_count(struct rte_eth_dev *dev, uint16_t rx_queue_id)
{
        /*
         * Number of BDs that have been processed by the driver
         * but have not been notified to the hardware.
         */
        uint32_t driver_hold_bd_num;
        struct hns3_rx_queue *rxq;
        uint32_t fbd_num;

        rxq = dev->data->rx_queues[rx_queue_id];
        fbd_num = hns3_read_dev(rxq, HNS3_RING_RX_FBDNUM_REG);
        if (dev->rx_pkt_burst == hns3_recv_pkts_vec ||
            dev->rx_pkt_burst == hns3_recv_pkts_vec_sve)
                driver_hold_bd_num = rxq->rx_rearm_nb;
        else
                driver_hold_bd_num = rxq->rx_free_hold;

        if (fbd_num <= driver_hold_bd_num)
                return 0;
        else
                return fbd_num - driver_hold_bd_num;
}

void
hns3_enable_rxd_adv_layout(struct hns3_hw *hw)
{
        /*
         * If the hardware support rxd advanced layout, then driver enable it
         * default.
         */
        if (hns3_dev_rxd_adv_layout_supported(hw))
                hns3_write_dev(hw, HNS3_RXD_ADV_LAYOUT_EN_REG, 1);
}