Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Felix Fietkau | 4001 | 76.71% | 44 | 44.44% |
Lorenzo Bianconi | 1034 | 19.82% | 44 | 44.44% |
Sujuan Chen | 92 | 1.76% | 2 | 2.02% |
Bo Jiao | 37 | 0.71% | 1 | 1.01% |
Ryder Lee | 27 | 0.52% | 5 | 5.05% |
Shayne Chen | 15 | 0.29% | 1 | 1.01% |
Sean Wang | 9 | 0.17% | 1 | 1.01% |
Stanislaw Gruszka | 1 | 0.02% | 1 | 1.01% |
Total | 5216 | 99 |
// SPDX-License-Identifier: ISC /* * Copyright (C) 2016 Felix Fietkau <nbd@nbd.name> */ #include <linux/dma-mapping.h> #include "mt76.h" #include "dma.h" #if IS_ENABLED(CONFIG_NET_MEDIATEK_SOC_WED) #define Q_READ(_dev, _q, _field) ({ \ u32 _offset = offsetof(struct mt76_queue_regs, _field); \ u32 _val; \ if ((_q)->flags & MT_QFLAG_WED) \ _val = mtk_wed_device_reg_read(&(_dev)->mmio.wed, \ ((_q)->wed_regs + \ _offset)); \ else \ _val = readl(&(_q)->regs->_field); \ _val; \ }) #define Q_WRITE(_dev, _q, _field, _val) do { \ u32 _offset = offsetof(struct mt76_queue_regs, _field); \ if ((_q)->flags & MT_QFLAG_WED) \ mtk_wed_device_reg_write(&(_dev)->mmio.wed, \ ((_q)->wed_regs + _offset), \ _val); \ else \ writel(_val, &(_q)->regs->_field); \ } while (0) #else #define Q_READ(_dev, _q, _field) readl(&(_q)->regs->_field) #define Q_WRITE(_dev, _q, _field, _val) writel(_val, &(_q)->regs->_field) #endif static struct mt76_txwi_cache * mt76_alloc_txwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t; dma_addr_t addr; u8 *txwi; int size; size = L1_CACHE_ALIGN(dev->drv->txwi_size + sizeof(*t)); txwi = kzalloc(size, GFP_ATOMIC); if (!txwi) return NULL; addr = dma_map_single(dev->dma_dev, txwi, dev->drv->txwi_size, DMA_TO_DEVICE); t = (struct mt76_txwi_cache *)(txwi + dev->drv->txwi_size); t->dma_addr = addr; return t; } static struct mt76_txwi_cache * mt76_alloc_rxwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t; t = kzalloc(L1_CACHE_ALIGN(sizeof(*t)), GFP_ATOMIC); if (!t) return NULL; t->ptr = NULL; return t; } static struct mt76_txwi_cache * __mt76_get_txwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t = NULL; spin_lock(&dev->lock); if (!list_empty(&dev->txwi_cache)) { t = list_first_entry(&dev->txwi_cache, struct mt76_txwi_cache, list); list_del(&t->list); } spin_unlock(&dev->lock); return t; } static struct mt76_txwi_cache * __mt76_get_rxwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t = NULL; spin_lock(&dev->wed_lock); if (!list_empty(&dev->rxwi_cache)) { t = list_first_entry(&dev->rxwi_cache, struct mt76_txwi_cache, list); list_del(&t->list); } spin_unlock(&dev->wed_lock); return t; } static struct mt76_txwi_cache * mt76_get_txwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t = __mt76_get_txwi(dev); if (t) return t; return mt76_alloc_txwi(dev); } struct mt76_txwi_cache * mt76_get_rxwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t = __mt76_get_rxwi(dev); if (t) return t; return mt76_alloc_rxwi(dev); } EXPORT_SYMBOL_GPL(mt76_get_rxwi); void mt76_put_txwi(struct mt76_dev *dev, struct mt76_txwi_cache *t) { if (!t) return; spin_lock(&dev->lock); list_add(&t->list, &dev->txwi_cache); spin_unlock(&dev->lock); } EXPORT_SYMBOL_GPL(mt76_put_txwi); void mt76_put_rxwi(struct mt76_dev *dev, struct mt76_txwi_cache *t) { if (!t) return; spin_lock(&dev->wed_lock); list_add(&t->list, &dev->rxwi_cache); spin_unlock(&dev->wed_lock); } EXPORT_SYMBOL_GPL(mt76_put_rxwi); static void mt76_free_pending_txwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t; local_bh_disable(); while ((t = __mt76_get_txwi(dev)) != NULL) { dma_unmap_single(dev->dma_dev, t->dma_addr, dev->drv->txwi_size, DMA_TO_DEVICE); kfree(mt76_get_txwi_ptr(dev, t)); } local_bh_enable(); } static void mt76_free_pending_rxwi(struct mt76_dev *dev) { struct mt76_txwi_cache *t; local_bh_disable(); while ((t = __mt76_get_rxwi(dev)) != NULL) { if (t->ptr) skb_free_frag(t->ptr); kfree(t); } local_bh_enable(); } static void mt76_dma_sync_idx(struct mt76_dev *dev, struct mt76_queue *q) { Q_WRITE(dev, q, desc_base, q->desc_dma); Q_WRITE(dev, q, ring_size, q->ndesc); q->head = Q_READ(dev, q, dma_idx); q->tail = q->head; } static void mt76_dma_queue_reset(struct mt76_dev *dev, struct mt76_queue *q) { int i; if (!q || !q->ndesc) return; /* clear descriptors */ for (i = 0; i < q->ndesc; i++) q->desc[i].ctrl = cpu_to_le32(MT_DMA_CTL_DMA_DONE); Q_WRITE(dev, q, cpu_idx, 0); Q_WRITE(dev, q, dma_idx, 0); mt76_dma_sync_idx(dev, q); } static int mt76_dma_add_rx_buf(struct mt76_dev *dev, struct mt76_queue *q, struct mt76_queue_buf *buf, void *data) { struct mt76_desc *desc = &q->desc[q->head]; struct mt76_queue_entry *entry = &q->entry[q->head]; struct mt76_txwi_cache *txwi = NULL; u32 buf1 = 0, ctrl; int idx = q->head; int rx_token; ctrl = FIELD_PREP(MT_DMA_CTL_SD_LEN0, buf[0].len); if ((q->flags & MT_QFLAG_WED) && FIELD_GET(MT_QFLAG_WED_TYPE, q->flags) == MT76_WED_Q_RX) { txwi = mt76_get_rxwi(dev); if (!txwi) return -ENOMEM; rx_token = mt76_rx_token_consume(dev, data, txwi, buf->addr); if (rx_token < 0) { mt76_put_rxwi(dev, txwi); return -ENOMEM; } buf1 |= FIELD_PREP(MT_DMA_CTL_TOKEN, rx_token); ctrl |= MT_DMA_CTL_TO_HOST; } WRITE_ONCE(desc->buf0, cpu_to_le32(buf->addr)); WRITE_ONCE(desc->buf1, cpu_to_le32(buf1)); WRITE_ONCE(desc->ctrl, cpu_to_le32(ctrl)); WRITE_ONCE(desc->info, 0); entry->dma_addr[0] = buf->addr; entry->dma_len[0] = buf->len; entry->txwi = txwi; entry->buf = data; entry->wcid = 0xffff; entry->skip_buf1 = true; q->head = (q->head + 1) % q->ndesc; q->queued++; return idx; } static int mt76_dma_add_buf(struct mt76_dev *dev, struct mt76_queue *q, struct mt76_queue_buf *buf, int nbufs, u32 info, struct sk_buff *skb, void *txwi) { struct mt76_queue_entry *entry; struct mt76_desc *desc; int i, idx = -1; u32 ctrl, next; if (txwi) { q->entry[q->head].txwi = DMA_DUMMY_DATA; q->entry[q->head].skip_buf0 = true; } for (i = 0; i < nbufs; i += 2, buf += 2) { u32 buf0 = buf[0].addr, buf1 = 0; idx = q->head; next = (q->head + 1) % q->ndesc; desc = &q->desc[idx]; entry = &q->entry[idx]; if (buf[0].skip_unmap) entry->skip_buf0 = true; entry->skip_buf1 = i == nbufs - 1; entry->dma_addr[0] = buf[0].addr; entry->dma_len[0] = buf[0].len; ctrl = FIELD_PREP(MT_DMA_CTL_SD_LEN0, buf[0].len); if (i < nbufs - 1) { entry->dma_addr[1] = buf[1].addr; entry->dma_len[1] = buf[1].len; buf1 = buf[1].addr; ctrl |= FIELD_PREP(MT_DMA_CTL_SD_LEN1, buf[1].len); if (buf[1].skip_unmap) entry->skip_buf1 = true; } if (i == nbufs - 1) ctrl |= MT_DMA_CTL_LAST_SEC0; else if (i == nbufs - 2) ctrl |= MT_DMA_CTL_LAST_SEC1; WRITE_ONCE(desc->buf0, cpu_to_le32(buf0)); WRITE_ONCE(desc->buf1, cpu_to_le32(buf1)); WRITE_ONCE(desc->info, cpu_to_le32(info)); WRITE_ONCE(desc->ctrl, cpu_to_le32(ctrl)); q->head = next; q->queued++; } q->entry[idx].txwi = txwi; q->entry[idx].skb = skb; q->entry[idx].wcid = 0xffff; return idx; } static void mt76_dma_tx_cleanup_idx(struct mt76_dev *dev, struct mt76_queue *q, int idx, struct mt76_queue_entry *prev_e) { struct mt76_queue_entry *e = &q->entry[idx]; if (!e->skip_buf0) dma_unmap_single(dev->dma_dev, e->dma_addr[0], e->dma_len[0], DMA_TO_DEVICE); if (!e->skip_buf1) dma_unmap_single(dev->dma_dev, e->dma_addr[1], e->dma_len[1], DMA_TO_DEVICE); if (e->txwi == DMA_DUMMY_DATA) e->txwi = NULL; if (e->skb == DMA_DUMMY_DATA) e->skb = NULL; *prev_e = *e; memset(e, 0, sizeof(*e)); } static void mt76_dma_kick_queue(struct mt76_dev *dev, struct mt76_queue *q) { wmb(); Q_WRITE(dev, q, cpu_idx, q->head); } static void mt76_dma_tx_cleanup(struct mt76_dev *dev, struct mt76_queue *q, bool flush) { struct mt76_queue_entry entry; int last; if (!q || !q->ndesc) return; spin_lock_bh(&q->cleanup_lock); if (flush) last = -1; else last = Q_READ(dev, q, dma_idx); while (q->queued > 0 && q->tail != last) { mt76_dma_tx_cleanup_idx(dev, q, q->tail, &entry); mt76_queue_tx_complete(dev, q, &entry); if (entry.txwi) { if (!(dev->drv->drv_flags & MT_DRV_TXWI_NO_FREE)) mt76_put_txwi(dev, entry.txwi); } if (!flush && q->tail == last) last = Q_READ(dev, q, dma_idx); } spin_unlock_bh(&q->cleanup_lock); if (flush) { spin_lock_bh(&q->lock); mt76_dma_sync_idx(dev, q); mt76_dma_kick_queue(dev, q); spin_unlock_bh(&q->lock); } if (!q->queued) wake_up(&dev->tx_wait); } static void * mt76_dma_get_buf(struct mt76_dev *dev, struct mt76_queue *q, int idx, int *len, u32 *info, bool *more, bool *drop) { struct mt76_queue_entry *e = &q->entry[idx]; struct mt76_desc *desc = &q->desc[idx]; void *buf; if (len) { u32 ctrl = le32_to_cpu(READ_ONCE(desc->ctrl)); *len = FIELD_GET(MT_DMA_CTL_SD_LEN0, ctrl); *more = !(ctrl & MT_DMA_CTL_LAST_SEC0); } if (info) *info = le32_to_cpu(desc->info); if ((q->flags & MT_QFLAG_WED) && FIELD_GET(MT_QFLAG_WED_TYPE, q->flags) == MT76_WED_Q_RX) { u32 token = FIELD_GET(MT_DMA_CTL_TOKEN, le32_to_cpu(desc->buf1)); struct mt76_txwi_cache *t = mt76_rx_token_release(dev, token); if (!t) return NULL; dma_unmap_single(dev->dma_dev, t->dma_addr, SKB_WITH_OVERHEAD(q->buf_size), DMA_FROM_DEVICE); buf = t->ptr; t->dma_addr = 0; t->ptr = NULL; mt76_put_rxwi(dev, t); if (drop) { u32 ctrl = le32_to_cpu(READ_ONCE(desc->ctrl)); *drop = !!(ctrl & (MT_DMA_CTL_TO_HOST_A | MT_DMA_CTL_DROP)); } } else { buf = e->buf; e->buf = NULL; dma_unmap_single(dev->dma_dev, e->dma_addr[0], SKB_WITH_OVERHEAD(q->buf_size), DMA_FROM_DEVICE); } return buf; } static void * mt76_dma_dequeue(struct mt76_dev *dev, struct mt76_queue *q, bool flush, int *len, u32 *info, bool *more, bool *drop) { int idx = q->tail; *more = false; if (!q->queued) return NULL; if (flush) q->desc[idx].ctrl |= cpu_to_le32(MT_DMA_CTL_DMA_DONE); else if (!(q->desc[idx].ctrl & cpu_to_le32(MT_DMA_CTL_DMA_DONE))) return NULL; q->tail = (q->tail + 1) % q->ndesc; q->queued--; return mt76_dma_get_buf(dev, q, idx, len, info, more, drop); } static int mt76_dma_tx_queue_skb_raw(struct mt76_dev *dev, struct mt76_queue *q, struct sk_buff *skb, u32 tx_info) { struct mt76_queue_buf buf = {}; dma_addr_t addr; if (q->queued + 1 >= q->ndesc - 1) goto error; addr = dma_map_single(dev->dma_dev, skb->data, skb->len, DMA_TO_DEVICE); if (unlikely(dma_mapping_error(dev->dma_dev, addr))) goto error; buf.addr = addr; buf.len = skb->len; spin_lock_bh(&q->lock); mt76_dma_add_buf(dev, q, &buf, 1, tx_info, skb, NULL); mt76_dma_kick_queue(dev, q); spin_unlock_bh(&q->lock); return 0; error: dev_kfree_skb(skb); return -ENOMEM; } static int mt76_dma_tx_queue_skb(struct mt76_dev *dev, struct mt76_queue *q, enum mt76_txq_id qid, struct sk_buff *skb, struct mt76_wcid *wcid, struct ieee80211_sta *sta) { struct ieee80211_tx_status status = { .sta = sta, }; struct mt76_tx_info tx_info = { .skb = skb, }; struct ieee80211_hw *hw; int len, n = 0, ret = -ENOMEM; struct mt76_txwi_cache *t; struct sk_buff *iter; dma_addr_t addr; u8 *txwi; t = mt76_get_txwi(dev); if (!t) goto free_skb; txwi = mt76_get_txwi_ptr(dev, t); skb->prev = skb->next = NULL; if (dev->drv->drv_flags & MT_DRV_TX_ALIGNED4_SKBS) mt76_insert_hdr_pad(skb); len = skb_headlen(skb); addr = dma_map_single(dev->dma_dev, skb->data, len, DMA_TO_DEVICE); if (unlikely(dma_mapping_error(dev->dma_dev, addr))) goto free; tx_info.buf[n].addr = t->dma_addr; tx_info.buf[n++].len = dev->drv->txwi_size; tx_info.buf[n].addr = addr; tx_info.buf[n++].len = len; skb_walk_frags(skb, iter) { if (n == ARRAY_SIZE(tx_info.buf)) goto unmap; addr = dma_map_single(dev->dma_dev, iter->data, iter->len, DMA_TO_DEVICE); if (unlikely(dma_mapping_error(dev->dma_dev, addr))) goto unmap; tx_info.buf[n].addr = addr; tx_info.buf[n++].len = iter->len; } tx_info.nbuf = n; if (q->queued + (tx_info.nbuf + 1) / 2 >= q->ndesc - 1) { ret = -ENOMEM; goto unmap; } dma_sync_single_for_cpu(dev->dma_dev, t->dma_addr, dev->drv->txwi_size, DMA_TO_DEVICE); ret = dev->drv->tx_prepare_skb(dev, txwi, qid, wcid, sta, &tx_info); dma_sync_single_for_device(dev->dma_dev, t->dma_addr, dev->drv->txwi_size, DMA_TO_DEVICE); if (ret < 0) goto unmap; return mt76_dma_add_buf(dev, q, tx_info.buf, tx_info.nbuf, tx_info.info, tx_info.skb, t); unmap: for (n--; n > 0; n--) dma_unmap_single(dev->dma_dev, tx_info.buf[n].addr, tx_info.buf[n].len, DMA_TO_DEVICE); free: #ifdef CONFIG_NL80211_TESTMODE /* fix tx_done accounting on queue overflow */ if (mt76_is_testmode_skb(dev, skb, &hw)) { struct mt76_phy *phy = hw->priv; if (tx_info.skb == phy->test.tx_skb) phy->test.tx_done--; } #endif mt76_put_txwi(dev, t); free_skb: status.skb = tx_info.skb; hw = mt76_tx_status_get_hw(dev, tx_info.skb); ieee80211_tx_status_ext(hw, &status); return ret; } static struct page_frag_cache * mt76_dma_rx_get_frag_cache(struct mt76_dev *dev, struct mt76_queue *q) { struct page_frag_cache *rx_page = &q->rx_page; #ifdef CONFIG_NET_MEDIATEK_SOC_WED if ((q->flags & MT_QFLAG_WED) && FIELD_GET(MT_QFLAG_WED_TYPE, q->flags) == MT76_WED_Q_RX) rx_page = &dev->mmio.wed.rx_buf_ring.rx_page; #endif return rx_page; } static int mt76_dma_rx_fill(struct mt76_dev *dev, struct mt76_queue *q) { struct page_frag_cache *rx_page = mt76_dma_rx_get_frag_cache(dev, q); int len = SKB_WITH_OVERHEAD(q->buf_size); int frames = 0, offset = q->buf_offset; dma_addr_t addr; if (!q->ndesc) return 0; spin_lock_bh(&q->lock); while (q->queued < q->ndesc - 1) { struct mt76_queue_buf qbuf; void *buf = NULL; buf = page_frag_alloc(rx_page, q->buf_size, GFP_ATOMIC); if (!buf) break; addr = dma_map_single(dev->dma_dev, buf, len, DMA_FROM_DEVICE); if (unlikely(dma_mapping_error(dev->dma_dev, addr))) { skb_free_frag(buf); break; } qbuf.addr = addr + offset; qbuf.len = len - offset; qbuf.skip_unmap = false; if (mt76_dma_add_rx_buf(dev, q, &qbuf, buf) < 0) { dma_unmap_single(dev->dma_dev, addr, len, DMA_FROM_DEVICE); skb_free_frag(buf); break; } frames++; } if (frames) mt76_dma_kick_queue(dev, q); spin_unlock_bh(&q->lock); return frames; } static int mt76_dma_wed_setup(struct mt76_dev *dev, struct mt76_queue *q) { #ifdef CONFIG_NET_MEDIATEK_SOC_WED struct mtk_wed_device *wed = &dev->mmio.wed; int ret, type, ring; u8 flags = q->flags; if (!mtk_wed_device_active(wed)) q->flags &= ~MT_QFLAG_WED; if (!(q->flags & MT_QFLAG_WED)) return 0; type = FIELD_GET(MT_QFLAG_WED_TYPE, q->flags); ring = FIELD_GET(MT_QFLAG_WED_RING, q->flags); switch (type) { case MT76_WED_Q_TX: ret = mtk_wed_device_tx_ring_setup(wed, ring, q->regs, false); if (!ret) q->wed_regs = wed->tx_ring[ring].reg_base; break; case MT76_WED_Q_TXFREE: /* WED txfree queue needs ring to be initialized before setup */ q->flags = 0; mt76_dma_queue_reset(dev, q); mt76_dma_rx_fill(dev, q); q->flags = flags; ret = mtk_wed_device_txfree_ring_setup(wed, q->regs); if (!ret) q->wed_regs = wed->txfree_ring.reg_base; break; case MT76_WED_Q_RX: ret = mtk_wed_device_rx_ring_setup(wed, ring, q->regs, false); if (!ret) q->wed_regs = wed->rx_ring[ring].reg_base; break; default: ret = -EINVAL; } return ret; #else return 0; #endif } static int mt76_dma_alloc_queue(struct mt76_dev *dev, struct mt76_queue *q, int idx, int n_desc, int bufsize, u32 ring_base) { int ret, size; spin_lock_init(&q->lock); spin_lock_init(&q->cleanup_lock); q->regs = dev->mmio.regs + ring_base + idx * MT_RING_SIZE; q->ndesc = n_desc; q->buf_size = bufsize; q->hw_idx = idx; size = q->ndesc * sizeof(struct mt76_desc); q->desc = dmam_alloc_coherent(dev->dma_dev, size, &q->desc_dma, GFP_KERNEL); if (!q->desc) return -ENOMEM; size = q->ndesc * sizeof(*q->entry); q->entry = devm_kzalloc(dev->dev, size, GFP_KERNEL); if (!q->entry) return -ENOMEM; ret = mt76_dma_wed_setup(dev, q); if (ret) return ret; if (q->flags != MT_WED_Q_TXFREE) mt76_dma_queue_reset(dev, q); return 0; } static void mt76_dma_rx_cleanup(struct mt76_dev *dev, struct mt76_queue *q) { struct page *page; void *buf; bool more; if (!q->ndesc) return; spin_lock_bh(&q->lock); do { buf = mt76_dma_dequeue(dev, q, true, NULL, NULL, &more, NULL); if (!buf) break; skb_free_frag(buf); } while (1); spin_unlock_bh(&q->lock); if (!q->rx_page.va) return; page = virt_to_page(q->rx_page.va); __page_frag_cache_drain(page, q->rx_page.pagecnt_bias); memset(&q->rx_page, 0, sizeof(q->rx_page)); } static void mt76_dma_rx_reset(struct mt76_dev *dev, enum mt76_rxq_id qid) { struct mt76_queue *q = &dev->q_rx[qid]; int i; if (!q->ndesc) return; for (i = 0; i < q->ndesc; i++) q->desc[i].ctrl = cpu_to_le32(MT_DMA_CTL_DMA_DONE); mt76_dma_rx_cleanup(dev, q); mt76_dma_sync_idx(dev, q); mt76_dma_rx_fill(dev, q); if (!q->rx_head) return; dev_kfree_skb(q->rx_head); q->rx_head = NULL; } static void mt76_add_fragment(struct mt76_dev *dev, struct mt76_queue *q, void *data, int len, bool more, u32 info) { struct sk_buff *skb = q->rx_head; struct skb_shared_info *shinfo = skb_shinfo(skb); int nr_frags = shinfo->nr_frags; if (nr_frags < ARRAY_SIZE(shinfo->frags)) { struct page *page = virt_to_head_page(data); int offset = data - page_address(page) + q->buf_offset; skb_add_rx_frag(skb, nr_frags, page, offset, len, q->buf_size); } else { skb_free_frag(data); } if (more) return; q->rx_head = NULL; if (nr_frags < ARRAY_SIZE(shinfo->frags)) dev->drv->rx_skb(dev, q - dev->q_rx, skb, &info); else dev_kfree_skb(skb); } static int mt76_dma_rx_process(struct mt76_dev *dev, struct mt76_queue *q, int budget) { int len, data_len, done = 0, dma_idx; struct sk_buff *skb; unsigned char *data; bool check_ddone = false; bool more; if (IS_ENABLED(CONFIG_NET_MEDIATEK_SOC_WED) && q->flags == MT_WED_Q_TXFREE) { dma_idx = Q_READ(dev, q, dma_idx); check_ddone = true; } while (done < budget) { bool drop = false; u32 info; if (check_ddone) { if (q->tail == dma_idx) dma_idx = Q_READ(dev, q, dma_idx); if (q->tail == dma_idx) break; } data = mt76_dma_dequeue(dev, q, false, &len, &info, &more, &drop); if (!data) break; if (drop) goto free_frag; if (q->rx_head) data_len = q->buf_size; else data_len = SKB_WITH_OVERHEAD(q->buf_size); if (data_len < len + q->buf_offset) { dev_kfree_skb(q->rx_head); q->rx_head = NULL; goto free_frag; } if (q->rx_head) { mt76_add_fragment(dev, q, data, len, more, info); continue; } if (!more && dev->drv->rx_check && !(dev->drv->rx_check(dev, data, len))) goto free_frag; skb = build_skb(data, q->buf_size); if (!skb) goto free_frag; skb_reserve(skb, q->buf_offset); *(u32 *)skb->cb = info; __skb_put(skb, len); done++; if (more) { q->rx_head = skb; continue; } dev->drv->rx_skb(dev, q - dev->q_rx, skb, &info); continue; free_frag: skb_free_frag(data); } mt76_dma_rx_fill(dev, q); return done; } int mt76_dma_rx_poll(struct napi_struct *napi, int budget) { struct mt76_dev *dev; int qid, done = 0, cur; dev = container_of(napi->dev, struct mt76_dev, napi_dev); qid = napi - dev->napi; rcu_read_lock(); do { cur = mt76_dma_rx_process(dev, &dev->q_rx[qid], budget - done); mt76_rx_poll_complete(dev, qid, napi); done += cur; } while (cur && done < budget); rcu_read_unlock(); if (done < budget && napi_complete(napi)) dev->drv->rx_poll_complete(dev, qid); return done; } EXPORT_SYMBOL_GPL(mt76_dma_rx_poll); static int mt76_dma_init(struct mt76_dev *dev, int (*poll)(struct napi_struct *napi, int budget)) { int i; init_dummy_netdev(&dev->napi_dev); init_dummy_netdev(&dev->tx_napi_dev); snprintf(dev->napi_dev.name, sizeof(dev->napi_dev.name), "%s", wiphy_name(dev->hw->wiphy)); dev->napi_dev.threaded = 1; mt76_for_each_q_rx(dev, i) { netif_napi_add(&dev->napi_dev, &dev->napi[i], poll); mt76_dma_rx_fill(dev, &dev->q_rx[i]); napi_enable(&dev->napi[i]); } return 0; } static const struct mt76_queue_ops mt76_dma_ops = { .init = mt76_dma_init, .alloc = mt76_dma_alloc_queue, .reset_q = mt76_dma_queue_reset, .tx_queue_skb_raw = mt76_dma_tx_queue_skb_raw, .tx_queue_skb = mt76_dma_tx_queue_skb, .tx_cleanup = mt76_dma_tx_cleanup, .rx_cleanup = mt76_dma_rx_cleanup, .rx_reset = mt76_dma_rx_reset, .kick = mt76_dma_kick_queue, }; void mt76_dma_attach(struct mt76_dev *dev) { dev->queue_ops = &mt76_dma_ops; } EXPORT_SYMBOL_GPL(mt76_dma_attach); void mt76_dma_cleanup(struct mt76_dev *dev) { int i; mt76_worker_disable(&dev->tx_worker); netif_napi_del(&dev->tx_napi); for (i = 0; i < ARRAY_SIZE(dev->phys); i++) { struct mt76_phy *phy = dev->phys[i]; int j; if (!phy) continue; for (j = 0; j < ARRAY_SIZE(phy->q_tx); j++) mt76_dma_tx_cleanup(dev, phy->q_tx[j], true); } for (i = 0; i < ARRAY_SIZE(dev->q_mcu); i++) mt76_dma_tx_cleanup(dev, dev->q_mcu[i], true); mt76_for_each_q_rx(dev, i) { struct mt76_queue *q = &dev->q_rx[i]; netif_napi_del(&dev->napi[i]); if (FIELD_GET(MT_QFLAG_WED_TYPE, q->flags)) mt76_dma_rx_cleanup(dev, q); } mt76_free_pending_txwi(dev); mt76_free_pending_rxwi(dev); if (mtk_wed_device_active(&dev->mmio.wed)) mtk_wed_device_detach(&dev->mmio.wed); } EXPORT_SYMBOL_GPL(mt76_dma_cleanup);
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