/* Copyright (c) 2014 Broadcom Corporation * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /******************************************************************************* * Communicates with the dongle by using dcmd codes. * For certain dcmd codes, the dongle interprets string data from the host. ******************************************************************************/ #include #include #include #include #include "core.h" #include "debug.h" #include "proto.h" #include "msgbuf.h" #include "commonring.h" #include "flowring.h" #include "bus.h" #include "tracepoint.h" #define MSGBUF_IOCTL_RESP_TIMEOUT 2000 #define MSGBUF_TYPE_GEN_STATUS 0x1 #define MSGBUF_TYPE_RING_STATUS 0x2 #define MSGBUF_TYPE_FLOW_RING_CREATE 0x3 #define MSGBUF_TYPE_FLOW_RING_CREATE_CMPLT 0x4 #define MSGBUF_TYPE_FLOW_RING_DELETE 0x5 #define MSGBUF_TYPE_FLOW_RING_DELETE_CMPLT 0x6 #define MSGBUF_TYPE_FLOW_RING_FLUSH 0x7 #define MSGBUF_TYPE_FLOW_RING_FLUSH_CMPLT 0x8 #define MSGBUF_TYPE_IOCTLPTR_REQ 0x9 #define MSGBUF_TYPE_IOCTLPTR_REQ_ACK 0xA #define MSGBUF_TYPE_IOCTLRESP_BUF_POST 0xB #define MSGBUF_TYPE_IOCTL_CMPLT 0xC #define MSGBUF_TYPE_EVENT_BUF_POST 0xD #define MSGBUF_TYPE_WL_EVENT 0xE #define MSGBUF_TYPE_TX_POST 0xF #define MSGBUF_TYPE_TX_STATUS 0x10 #define MSGBUF_TYPE_RXBUF_POST 0x11 #define MSGBUF_TYPE_RX_CMPLT 0x12 #define MSGBUF_TYPE_LPBK_DMAXFER 0x13 #define MSGBUF_TYPE_LPBK_DMAXFER_CMPLT 0x14 #define NR_TX_PKTIDS 2048 #define NR_RX_PKTIDS 1024 #define BRCMF_IOCTL_REQ_PKTID 0xFFFE #define BRCMF_MSGBUF_MAX_PKT_SIZE 2048 #define BRCMF_MSGBUF_RXBUFPOST_THRESHOLD 32 #define BRCMF_MSGBUF_MAX_IOCTLRESPBUF_POST 8 #define BRCMF_MSGBUF_MAX_EVENTBUF_POST 8 #define BRCMF_MSGBUF_PKT_FLAGS_FRAME_802_3 0x01 #define BRCMF_MSGBUF_PKT_FLAGS_PRIO_SHIFT 5 #define BRCMF_MSGBUF_TX_FLUSH_CNT1 32 #define BRCMF_MSGBUF_TX_FLUSH_CNT2 96 #define BRCMF_MSGBUF_DELAY_TXWORKER_THRS 64 #define BRCMF_MSGBUF_TRICKLE_TXWORKER_THRS 32 struct msgbuf_common_hdr { u8 msgtype; u8 ifidx; u8 flags; u8 rsvd0; __le32 request_id; }; struct msgbuf_buf_addr { __le32 low_addr; __le32 high_addr; }; struct msgbuf_ioctl_req_hdr { struct msgbuf_common_hdr msg; __le32 cmd; __le16 trans_id; __le16 input_buf_len; __le16 output_buf_len; __le16 rsvd0[3]; struct msgbuf_buf_addr req_buf_addr; __le32 rsvd1[2]; }; struct msgbuf_tx_msghdr { struct msgbuf_common_hdr msg; u8 txhdr[ETH_HLEN]; u8 flags; u8 seg_cnt; struct msgbuf_buf_addr metadata_buf_addr; struct msgbuf_buf_addr data_buf_addr; __le16 metadata_buf_len; __le16 data_len; __le32 rsvd0; }; struct msgbuf_rx_bufpost { struct msgbuf_common_hdr msg; __le16 metadata_buf_len; __le16 data_buf_len; __le32 rsvd0; struct msgbuf_buf_addr metadata_buf_addr; struct msgbuf_buf_addr data_buf_addr; }; struct msgbuf_rx_ioctl_resp_or_event { struct msgbuf_common_hdr msg; __le16 host_buf_len; __le16 rsvd0[3]; struct msgbuf_buf_addr host_buf_addr; __le32 rsvd1[4]; }; struct msgbuf_completion_hdr { __le16 status; __le16 flow_ring_id; }; struct msgbuf_rx_event { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le16 event_data_len; __le16 seqnum; __le16 rsvd0[4]; }; struct msgbuf_ioctl_resp_hdr { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le16 resp_len; __le16 trans_id; __le32 cmd; __le32 rsvd0; }; struct msgbuf_tx_status { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le16 metadata_len; __le16 tx_status; }; struct msgbuf_rx_complete { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le16 metadata_len; __le16 data_len; __le16 data_offset; __le16 flags; __le32 rx_status_0; __le32 rx_status_1; __le32 rsvd0; }; struct msgbuf_tx_flowring_create_req { struct msgbuf_common_hdr msg; u8 da[ETH_ALEN]; u8 sa[ETH_ALEN]; u8 tid; u8 if_flags; __le16 flow_ring_id; u8 tc; u8 priority; __le16 int_vector; __le16 max_items; __le16 len_item; struct msgbuf_buf_addr flow_ring_addr; }; struct msgbuf_tx_flowring_delete_req { struct msgbuf_common_hdr msg; __le16 flow_ring_id; __le16 reason; __le32 rsvd0[7]; }; struct msgbuf_flowring_create_resp { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le32 rsvd0[3]; }; struct msgbuf_flowring_delete_resp { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le32 rsvd0[3]; }; struct msgbuf_flowring_flush_resp { struct msgbuf_common_hdr msg; struct msgbuf_completion_hdr compl_hdr; __le32 rsvd0[3]; }; struct brcmf_msgbuf_work_item { struct list_head queue; u32 flowid; int ifidx; u8 sa[ETH_ALEN]; u8 da[ETH_ALEN]; }; struct brcmf_msgbuf { struct brcmf_pub *drvr; struct brcmf_commonring **commonrings; struct brcmf_commonring **flowrings; dma_addr_t *flowring_dma_handle; u16 nrof_flowrings; u16 rx_dataoffset; u32 max_rxbufpost; u16 rx_metadata_offset; u32 rxbufpost; u32 max_ioctlrespbuf; u32 cur_ioctlrespbuf; u32 max_eventbuf; u32 cur_eventbuf; void *ioctbuf; dma_addr_t ioctbuf_handle; u32 ioctbuf_phys_hi; u32 ioctbuf_phys_lo; int ioctl_resp_status; u32 ioctl_resp_ret_len; u32 ioctl_resp_pktid; u16 data_seq_no; u16 ioctl_seq_no; u32 reqid; wait_queue_head_t ioctl_resp_wait; bool ctl_completed; struct brcmf_msgbuf_pktids *tx_pktids; struct brcmf_msgbuf_pktids *rx_pktids; struct brcmf_flowring *flow; struct workqueue_struct *txflow_wq; struct work_struct txflow_work; unsigned long *flow_map; unsigned long *txstatus_done_map; struct work_struct flowring_work; spinlock_t flowring_work_lock; struct list_head work_queue; }; struct brcmf_msgbuf_pktid { atomic_t allocated; u16 data_offset; struct sk_buff *skb; dma_addr_t physaddr; }; struct brcmf_msgbuf_pktids { u32 array_size; u32 last_allocated_idx; enum dma_data_direction direction; struct brcmf_msgbuf_pktid *array; }; /* dma flushing needs implementation for mips and arm platforms. Should * be put in util. Note, this is not real flushing. It is virtual non * cached memory. Only write buffers should have to be drained. Though * this may be different depending on platform...... */ #define brcmf_dma_flush(addr, len) #define brcmf_dma_invalidate_cache(addr, len) static void brcmf_msgbuf_rxbuf_ioctlresp_post(struct brcmf_msgbuf *msgbuf); static struct brcmf_msgbuf_pktids * brcmf_msgbuf_init_pktids(u32 nr_array_entries, enum dma_data_direction direction) { struct brcmf_msgbuf_pktid *array; struct brcmf_msgbuf_pktids *pktids; array = kcalloc(nr_array_entries, sizeof(*array), GFP_KERNEL); if (!array) return NULL; pktids = kzalloc(sizeof(*pktids), GFP_KERNEL); if (!pktids) { kfree(array); return NULL; } pktids->array = array; pktids->array_size = nr_array_entries; return pktids; } static int brcmf_msgbuf_alloc_pktid(struct device *dev, struct brcmf_msgbuf_pktids *pktids, struct sk_buff *skb, u16 data_offset, dma_addr_t *physaddr, u32 *idx) { struct brcmf_msgbuf_pktid *array; u32 count; array = pktids->array; *physaddr = dma_map_single(dev, skb->data + data_offset, skb->len - data_offset, pktids->direction); if (dma_mapping_error(dev, *physaddr)) { brcmf_err("dma_map_single failed !!\n"); return -ENOMEM; } *idx = pktids->last_allocated_idx; count = 0; do { (*idx)++; if (*idx == pktids->array_size) *idx = 0; if (array[*idx].allocated.counter == 0) if (atomic_cmpxchg(&array[*idx].allocated, 0, 1) == 0) break; count++; } while (count < pktids->array_size); if (count == pktids->array_size) return -ENOMEM; array[*idx].data_offset = data_offset; array[*idx].physaddr = *physaddr; array[*idx].skb = skb; pktids->last_allocated_idx = *idx; return 0; } static struct sk_buff * brcmf_msgbuf_get_pktid(struct device *dev, struct brcmf_msgbuf_pktids *pktids, u32 idx) { struct brcmf_msgbuf_pktid *pktid; struct sk_buff *skb; if (idx >= pktids->array_size) { brcmf_err("Invalid packet id %d (max %d)\n", idx, pktids->array_size); return NULL; } if (pktids->array[idx].allocated.counter) { pktid = &pktids->array[idx]; dma_unmap_single(dev, pktid->physaddr, pktid->skb->len - pktid->data_offset, pktids->direction); skb = pktid->skb; pktid->allocated.counter = 0; return skb; } else { brcmf_err("Invalid packet id %d (not in use)\n", idx); } return NULL; } static void brcmf_msgbuf_release_array(struct device *dev, struct brcmf_msgbuf_pktids *pktids) { struct brcmf_msgbuf_pktid *array; struct brcmf_msgbuf_pktid *pktid; u32 count; array = pktids->array; count = 0; do { if (array[count].allocated.counter) { pktid = &array[count]; dma_unmap_single(dev, pktid->physaddr, pktid->skb->len - pktid->data_offset, pktids->direction); brcmu_pkt_buf_free_skb(pktid->skb); } count++; } while (count < pktids->array_size); kfree(array); kfree(pktids); } static void brcmf_msgbuf_release_pktids(struct brcmf_msgbuf *msgbuf) { if (msgbuf->rx_pktids) brcmf_msgbuf_release_array(msgbuf->drvr->bus_if->dev, msgbuf->rx_pktids); if (msgbuf->tx_pktids) brcmf_msgbuf_release_array(msgbuf->drvr->bus_if->dev, msgbuf->tx_pktids); } static int brcmf_msgbuf_tx_ioctl(struct brcmf_pub *drvr, int ifidx, uint cmd, void *buf, uint len) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; struct brcmf_commonring *commonring; struct msgbuf_ioctl_req_hdr *request; u16 buf_len; void *ret_ptr; int err; commonring = msgbuf->commonrings[BRCMF_H2D_MSGRING_CONTROL_SUBMIT]; brcmf_commonring_lock(commonring); ret_ptr = brcmf_commonring_reserve_for_write(commonring); if (!ret_ptr) { brcmf_err("Failed to reserve space in commonring\n"); brcmf_commonring_unlock(commonring); return -ENOMEM; } msgbuf->reqid++; request = (struct msgbuf_ioctl_req_hdr *)ret_ptr; request->msg.msgtype = MSGBUF_TYPE_IOCTLPTR_REQ; request->msg.ifidx = (u8)ifidx; request->msg.flags = 0; request->msg.request_id = cpu_to_le32(BRCMF_IOCTL_REQ_PKTID); request->cmd = cpu_to_le32(cmd); request->output_buf_len = cpu_to_le16(len); request->trans_id = cpu_to_le16(msgbuf->reqid); buf_len = min_t(u16, len, BRCMF_TX_IOCTL_MAX_MSG_SIZE); request->input_buf_len = cpu_to_le16(buf_len); request->req_buf_addr.high_addr = cpu_to_le32(msgbuf->ioctbuf_phys_hi); request->req_buf_addr.low_addr = cpu_to_le32(msgbuf->ioctbuf_phys_lo); if (buf) memcpy(msgbuf->ioctbuf, buf, buf_len); else memset(msgbuf->ioctbuf, 0, buf_len); brcmf_dma_flush(ioctl_buf, buf_len); err = brcmf_commonring_write_complete(commonring); brcmf_commonring_unlock(commonring); return err; } static int brcmf_msgbuf_ioctl_resp_wait(struct brcmf_msgbuf *msgbuf) { return wait_event_timeout(msgbuf->ioctl_resp_wait, msgbuf->ctl_completed, msecs_to_jiffies(MSGBUF_IOCTL_RESP_TIMEOUT)); } static void brcmf_msgbuf_ioctl_resp_wake(struct brcmf_msgbuf *msgbuf) { if (waitqueue_active(&msgbuf->ioctl_resp_wait)) { msgbuf->ctl_completed = true; wake_up(&msgbuf->ioctl_resp_wait); } } static int brcmf_msgbuf_query_dcmd(struct brcmf_pub *drvr, int ifidx, uint cmd, void *buf, uint len) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; struct sk_buff *skb = NULL; int timeout; int err; brcmf_dbg(MSGBUF, "ifidx=%d, cmd=%d, len=%d\n", ifidx, cmd, len); msgbuf->ctl_completed = false; err = brcmf_msgbuf_tx_ioctl(drvr, ifidx, cmd, buf, len); if (err) return err; timeout = brcmf_msgbuf_ioctl_resp_wait(msgbuf); if (!timeout) { brcmf_err("Timeout on response for query command\n"); return -EIO; } skb = brcmf_msgbuf_get_pktid(msgbuf->drvr->bus_if->dev, msgbuf->rx_pktids, msgbuf->ioctl_resp_pktid); if (msgbuf->ioctl_resp_ret_len != 0) { if (!skb) { brcmf_err("Invalid packet id idx recv'd %d\n", msgbuf->ioctl_resp_pktid); return -EBADF; } memcpy(buf, skb->data, (len < msgbuf->ioctl_resp_ret_len) ? len : msgbuf->ioctl_resp_ret_len); } brcmu_pkt_buf_free_skb(skb); return msgbuf->ioctl_resp_status; } static int brcmf_msgbuf_set_dcmd(struct brcmf_pub *drvr, int ifidx, uint cmd, void *buf, uint len) { return brcmf_msgbuf_query_dcmd(drvr, ifidx, cmd, buf, len); } static int brcmf_msgbuf_hdrpull(struct brcmf_pub *drvr, bool do_fws, u8 *ifidx, struct sk_buff *skb) { return -ENODEV; } static void brcmf_msgbuf_remove_flowring(struct brcmf_msgbuf *msgbuf, u16 flowid) { u32 dma_sz; void *dma_buf; brcmf_dbg(MSGBUF, "Removing flowring %d\n", flowid); dma_sz = BRCMF_H2D_TXFLOWRING_MAX_ITEM * BRCMF_H2D_TXFLOWRING_ITEMSIZE; dma_buf = msgbuf->flowrings[flowid]->buf_addr; dma_free_coherent(msgbuf->drvr->bus_if->dev, dma_sz, dma_buf, msgbuf->flowring_dma_handle[flowid]); brcmf_flowring_delete(msgbuf->flow, flowid); } static struct brcmf_msgbuf_work_item * brcmf_msgbuf_dequeue_work(struct brcmf_msgbuf *msgbuf) { struct brcmf_msgbuf_work_item *work = NULL; ulong flags; spin_lock_irqsave(&msgbuf->flowring_work_lock, flags); if (!list_empty(&msgbuf->work_queue)) { work = list_first_entry(&msgbuf->work_queue, struct brcmf_msgbuf_work_item, queue); list_del(&work->queue); } spin_unlock_irqrestore(&msgbuf->flowring_work_lock, flags); return work; } static u32 brcmf_msgbuf_flowring_create_worker(struct brcmf_msgbuf *msgbuf, struct brcmf_msgbuf_work_item *work) { struct msgbuf_tx_flowring_create_req *create; struct brcmf_commonring *commonring; void *ret_ptr; u32 flowid; void *dma_buf; u32 dma_sz; u64 address; int err; flowid = work->flowid; dma_sz = BRCMF_H2D_TXFLOWRING_MAX_ITEM * BRCMF_H2D_TXFLOWRING_ITEMSIZE; dma_buf = dma_alloc_coherent(msgbuf->drvr->bus_if->dev, dma_sz, &msgbuf->flowring_dma_handle[flowid], GFP_KERNEL); if (!dma_buf) { brcmf_err("dma_alloc_coherent failed\n"); brcmf_flowring_delete(msgbuf->flow, flowid); return BRCMF_FLOWRING_INVALID_ID; } brcmf_commonring_config(msgbuf->flowrings[flowid], BRCMF_H2D_TXFLOWRING_MAX_ITEM, BRCMF_H2D_TXFLOWRING_ITEMSIZE, dma_buf); commonring = msgbuf->commonrings[BRCMF_H2D_MSGRING_CONTROL_SUBMIT]; brcmf_commonring_lock(commonring); ret_ptr = brcmf_commonring_reserve_for_write(commonring); if (!ret_ptr) { brcmf_err("Failed to reserve space in commonring\n"); brcmf_commonring_unlock(commonring); brcmf_msgbuf_remove_flowring(msgbuf, flowid); return BRCMF_FLOWRING_INVALID_ID; } create = (struct msgbuf_tx_flowring_create_req *)ret_ptr; create->msg.msgtype = MSGBUF_TYPE_FLOW_RING_CREATE; create->msg.ifidx = work->ifidx; create->msg.request_id = 0; create->tid = brcmf_flowring_tid(msgbuf->flow, flowid); create->flow_ring_id = cpu_to_le16(flowid + BRCMF_NROF_H2D_COMMON_MSGRINGS); memcpy(create->sa, work->sa, ETH_ALEN); memcpy(create->da, work->da, ETH_ALEN); address = (u64)msgbuf->flowring_dma_handle[flowid]; create->flow_ring_addr.high_addr = cpu_to_le32(address >> 32); create->flow_ring_addr.low_addr = cpu_to_le32(address & 0xffffffff); create->max_items = cpu_to_le16(BRCMF_H2D_TXFLOWRING_MAX_ITEM); create->len_item = cpu_to_le16(BRCMF_H2D_TXFLOWRING_ITEMSIZE); brcmf_dbg(MSGBUF, "Send Flow Create Req flow ID %d for peer %pM prio %d ifindex %d\n", flowid, work->da, create->tid, work->ifidx); err = brcmf_commonring_write_complete(commonring); brcmf_commonring_unlock(commonring); if (err) { brcmf_err("Failed to write commonring\n"); brcmf_msgbuf_remove_flowring(msgbuf, flowid); return BRCMF_FLOWRING_INVALID_ID; } return flowid; } static void brcmf_msgbuf_flowring_worker(struct work_struct *work) { struct brcmf_msgbuf *msgbuf; struct brcmf_msgbuf_work_item *create; msgbuf = container_of(work, struct brcmf_msgbuf, flowring_work); while ((create = brcmf_msgbuf_dequeue_work(msgbuf))) { brcmf_msgbuf_flowring_create_worker(msgbuf, create); kfree(create); } } static u32 brcmf_msgbuf_flowring_create(struct brcmf_msgbuf *msgbuf, int ifidx, struct sk_buff *skb) { struct brcmf_msgbuf_work_item *create; struct ethhdr *eh = (struct ethhdr *)(skb->data); u32 flowid; ulong flags; create = kzalloc(sizeof(*create), GFP_ATOMIC); if (create == NULL) return BRCMF_FLOWRING_INVALID_ID; flowid = brcmf_flowring_create(msgbuf->flow, eh->h_dest, skb->priority, ifidx); if (flowid == BRCMF_FLOWRING_INVALID_ID) { kfree(create); return flowid; } create->flowid = flowid; create->ifidx = ifidx; memcpy(create->sa, eh->h_source, ETH_ALEN); memcpy(create->da, eh->h_dest, ETH_ALEN); spin_lock_irqsave(&msgbuf->flowring_work_lock, flags); list_add_tail(&create->queue, &msgbuf->work_queue); spin_unlock_irqrestore(&msgbuf->flowring_work_lock, flags); schedule_work(&msgbuf->flowring_work); return flowid; } static void brcmf_msgbuf_txflow(struct brcmf_msgbuf *msgbuf, u8 flowid) { struct brcmf_flowring *flow = msgbuf->flow; struct brcmf_commonring *commonring; void *ret_ptr; u32 count; struct sk_buff *skb; dma_addr_t physaddr; u32 pktid; struct msgbuf_tx_msghdr *tx_msghdr; u64 address; commonring = msgbuf->flowrings[flowid]; if (!brcmf_commonring_write_available(commonring)) return; brcmf_commonring_lock(commonring); count = BRCMF_MSGBUF_TX_FLUSH_CNT2 - BRCMF_MSGBUF_TX_FLUSH_CNT1; while (brcmf_flowring_qlen(flow, flowid)) { skb = brcmf_flowring_dequeue(flow, flowid); if (skb == NULL) { brcmf_err("No SKB, but qlen %d\n", brcmf_flowring_qlen(flow, flowid)); break; } skb_orphan(skb); if (brcmf_msgbuf_alloc_pktid(msgbuf->drvr->bus_if->dev, msgbuf->tx_pktids, skb, ETH_HLEN, &physaddr, &pktid)) { brcmf_flowring_reinsert(flow, flowid, skb); brcmf_err("No PKTID available !!\n"); break; } ret_ptr = brcmf_commonring_reserve_for_write(commonring); if (!ret_ptr) { brcmf_msgbuf_get_pktid(msgbuf->drvr->bus_if->dev, msgbuf->tx_pktids, pktid); brcmf_flowring_reinsert(flow, flowid, skb); break; } count++; tx_msghdr = (struct msgbuf_tx_msghdr *)ret_ptr; tx_msghdr->msg.msgtype = MSGBUF_TYPE_TX_POST; tx_msghdr->msg.request_id = cpu_to_le32(pktid); tx_msghdr->msg.ifidx = brcmf_flowring_ifidx_get(flow, flowid); tx_msghdr->flags = BRCMF_MSGBUF_PKT_FLAGS_FRAME_802_3; tx_msghdr->flags |= (skb->priority & 0x07) << BRCMF_MSGBUF_PKT_FLAGS_PRIO_SHIFT; tx_msghdr->seg_cnt = 1; memcpy(tx_msghdr->txhdr, skb->data, ETH_HLEN); tx_msghdr->data_len = cpu_to_le16(skb->len - ETH_HLEN); address = (u64)physaddr; tx_msghdr->data_buf_addr.high_addr = cpu_to_le32(address >> 32); tx_msghdr->data_buf_addr.low_addr = cpu_to_le32(address & 0xffffffff); tx_msghdr->metadata_buf_len = 0; tx_msghdr->metadata_buf_addr.high_addr = 0; tx_msghdr->metadata_buf_addr.low_addr = 0; atomic_inc(&commonring->outstanding_tx); if (count >= BRCMF_MSGBUF_TX_FLUSH_CNT2) { brcmf_commonring_write_complete(commonring); count = 0; } } if (count) brcmf_commonring_write_complete(commonring); brcmf_commonring_unlock(commonring); } static void brcmf_msgbuf_txflow_worker(struct work_struct *worker) { struct brcmf_msgbuf *msgbuf; u32 flowid; msgbuf = container_of(worker, struct brcmf_msgbuf, txflow_work); for_each_set_bit(flowid, msgbuf->flow_map, msgbuf->nrof_flowrings) { clear_bit(flowid, msgbuf->flow_map); brcmf_msgbuf_txflow(msgbuf, flowid); } } static int brcmf_msgbuf_schedule_txdata(struct brcmf_msgbuf *msgbuf, u32 flowid, bool force) { struct brcmf_commonring *commonring; set_bit(flowid, msgbuf->flow_map); commonring = msgbuf->flowrings[flowid]; if ((force) || (atomic_read(&commonring->outstanding_tx) < BRCMF_MSGBUF_DELAY_TXWORKER_THRS)) queue_work(msgbuf->txflow_wq, &msgbuf->txflow_work); return 0; } static int brcmf_msgbuf_txdata(struct brcmf_pub *drvr, int ifidx, u8 offset, struct sk_buff *skb) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; struct brcmf_flowring *flow = msgbuf->flow; struct ethhdr *eh = (struct ethhdr *)(skb->data); u32 flowid; flowid = brcmf_flowring_lookup(flow, eh->h_dest, skb->priority, ifidx); if (flowid == BRCMF_FLOWRING_INVALID_ID) { flowid = brcmf_msgbuf_flowring_create(msgbuf, ifidx, skb); if (flowid == BRCMF_FLOWRING_INVALID_ID) return -ENOMEM; } brcmf_flowring_enqueue(flow, flowid, skb); brcmf_msgbuf_schedule_txdata(msgbuf, flowid, false); return 0; } static void brcmf_msgbuf_configure_addr_mode(struct brcmf_pub *drvr, int ifidx, enum proto_addr_mode addr_mode) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; brcmf_flowring_configure_addr_mode(msgbuf->flow, ifidx, addr_mode); } static void brcmf_msgbuf_delete_peer(struct brcmf_pub *drvr, int ifidx, u8 peer[ETH_ALEN]) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; brcmf_flowring_delete_peer(msgbuf->flow, ifidx, peer); } static void brcmf_msgbuf_add_tdls_peer(struct brcmf_pub *drvr, int ifidx, u8 peer[ETH_ALEN]) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; brcmf_flowring_add_tdls_peer(msgbuf->flow, ifidx, peer); } static void brcmf_msgbuf_process_ioctl_complete(struct brcmf_msgbuf *msgbuf, void *buf) { struct msgbuf_ioctl_resp_hdr *ioctl_resp; ioctl_resp = (struct msgbuf_ioctl_resp_hdr *)buf; msgbuf->ioctl_resp_status = (s16)le16_to_cpu(ioctl_resp->compl_hdr.status); msgbuf->ioctl_resp_ret_len = le16_to_cpu(ioctl_resp->resp_len); msgbuf->ioctl_resp_pktid = le32_to_cpu(ioctl_resp->msg.request_id); brcmf_msgbuf_ioctl_resp_wake(msgbuf); if (msgbuf->cur_ioctlrespbuf) msgbuf->cur_ioctlrespbuf--; brcmf_msgbuf_rxbuf_ioctlresp_post(msgbuf); } static void brcmf_msgbuf_process_txstatus(struct brcmf_msgbuf *msgbuf, void *buf) { struct brcmf_commonring *commonring; struct msgbuf_tx_status *tx_status; u32 idx; struct sk_buff *skb; u16 flowid; tx_status = (struct msgbuf_tx_status *)buf; idx = le32_to_cpu(tx_status->msg.request_id); flowid = le16_to_cpu(tx_status->compl_hdr.flow_ring_id); flowid -= BRCMF_NROF_H2D_COMMON_MSGRINGS; skb = brcmf_msgbuf_get_pktid(msgbuf->drvr->bus_if->dev, msgbuf->tx_pktids, idx); if (!skb) { brcmf_err("Invalid packet id idx recv'd %d\n", idx); return; } set_bit(flowid, msgbuf->txstatus_done_map); commonring = msgbuf->flowrings[flowid]; atomic_dec(&commonring->outstanding_tx); brcmf_txfinalize(msgbuf->drvr, skb, tx_status->msg.ifidx, true); } static u32 brcmf_msgbuf_rxbuf_data_post(struct brcmf_msgbuf *msgbuf, u32 count) { struct brcmf_commonring *commonring; void *ret_ptr; struct sk_buff *skb; u16 alloced; u32 pktlen; dma_addr_t physaddr; struct msgbuf_rx_bufpost *rx_bufpost; u64 address; u32 pktid; u32 i; commonring = msgbuf->commonrings[BRCMF_H2D_MSGRING_RXPOST_SUBMIT]; ret_ptr = brcmf_commonring_reserve_for_write_multiple(commonring, count, &alloced); if (!ret_ptr) { brcmf_dbg(MSGBUF, "Failed to reserve space in commonring\n"); return 0; } for (i = 0; i < alloced; i++) { rx_bufpost = (struct msgbuf_rx_bufpost *)ret_ptr; memset(rx_bufpost, 0, sizeof(*rx_bufpost)); skb = brcmu_pkt_buf_get_skb(BRCMF_MSGBUF_MAX_PKT_SIZE); if (skb == NULL) { brcmf_err("Failed to alloc SKB\n"); brcmf_commonring_write_cancel(commonring, alloced - i); break; } pktlen = skb->len; if (brcmf_msgbuf_alloc_pktid(msgbuf->drvr->bus_if->dev, msgbuf->rx_pktids, skb, 0, &physaddr, &pktid)) { dev_kfree_skb_any(skb); brcmf_err("No PKTID available !!\n"); brcmf_commonring_write_cancel(commonring, alloced - i); break; } if (msgbuf->rx_metadata_offset) { address = (u64)physaddr; rx_bufpost->metadata_buf_len = cpu_to_le16(msgbuf->rx_metadata_offset); rx_bufpost->metadata_buf_addr.high_addr = cpu_to_le32(address >> 32); rx_bufpost->metadata_buf_addr.low_addr = cpu_to_le32(address & 0xffffffff); skb_pull(skb, msgbuf->rx_metadata_offset); pktlen = skb->len; physaddr += msgbuf->rx_metadata_offset; } rx_bufpost->msg.msgtype = MSGBUF_TYPE_RXBUF_POST; rx_bufpost->msg.request_id = cpu_to_le32(pktid); address = (u64)physaddr; rx_bufpost->data_buf_len = cpu_to_le16((u16)pktlen); rx_bufpost->data_buf_addr.high_addr = cpu_to_le32(address >> 32); rx_bufpost->data_buf_addr.low_addr = cpu_to_le32(address & 0xffffffff); ret_ptr += brcmf_commonring_len_item(commonring); } if (i) brcmf_commonring_write_complete(commonring); return i; } static void brcmf_msgbuf_rxbuf_data_fill(struct brcmf_msgbuf *msgbuf) { u32 fillbufs; u32 retcount; fillbufs = msgbuf->max_rxbufpost - msgbuf->rxbufpost; while (fillbufs) { retcount = brcmf_msgbuf_rxbuf_data_post(msgbuf, fillbufs); if (!retcount) break; msgbuf->rxbufpost += retcount; fillbufs -= retcount; } } static void brcmf_msgbuf_update_rxbufpost_count(struct brcmf_msgbuf *msgbuf, u16 rxcnt) { msgbuf->rxbufpost -= rxcnt; if (msgbuf->rxbufpost <= (msgbuf->max_rxbufpost - BRCMF_MSGBUF_RXBUFPOST_THRESHOLD)) brcmf_msgbuf_rxbuf_data_fill(msgbuf); } static u32 brcmf_msgbuf_rxbuf_ctrl_post(struct brcmf_msgbuf *msgbuf, bool event_buf, u32 count) { struct brcmf_commonring *commonring; void *ret_ptr; struct sk_buff *skb; u16 alloced; u32 pktlen; dma_addr_t physaddr; struct msgbuf_rx_ioctl_resp_or_event *rx_bufpost; u64 address; u32 pktid; u32 i; commonring = msgbuf->commonrings[BRCMF_H2D_MSGRING_CONTROL_SUBMIT]; brcmf_commonring_lock(commonring); ret_ptr = brcmf_commonring_reserve_for_write_multiple(commonring, count, &alloced); if (!ret_ptr) { brcmf_err("Failed to reserve space in commonring\n"); brcmf_commonring_unlock(commonring); return 0; } for (i = 0; i < alloced; i++) { rx_bufpost = (struct msgbuf_rx_ioctl_resp_or_event *)ret_ptr; memset(rx_bufpost, 0, sizeof(*rx_bufpost)); skb = brcmu_pkt_buf_get_skb(BRCMF_MSGBUF_MAX_PKT_SIZE); if (skb == NULL) { brcmf_err("Failed to alloc SKB\n"); brcmf_commonring_write_cancel(commonring, alloced - i); break; } pktlen = skb->len; if (brcmf_msgbuf_alloc_pktid(msgbuf->drvr->bus_if->dev, msgbuf->rx_pktids, skb, 0, &physaddr, &pktid)) { dev_kfree_skb_any(skb); brcmf_err("No PKTID available !!\n"); brcmf_commonring_write_cancel(commonring, alloced - i); break; } if (event_buf) rx_bufpost->msg.msgtype = MSGBUF_TYPE_EVENT_BUF_POST; else rx_bufpost->msg.msgtype = MSGBUF_TYPE_IOCTLRESP_BUF_POST; rx_bufpost->msg.request_id = cpu_to_le32(pktid); address = (u64)physaddr; rx_bufpost->host_buf_len = cpu_to_le16((u16)pktlen); rx_bufpost->host_buf_addr.high_addr = cpu_to_le32(address >> 32); rx_bufpost->host_buf_addr.low_addr = cpu_to_le32(address & 0xffffffff); ret_ptr += brcmf_commonring_len_item(commonring); } if (i) brcmf_commonring_write_complete(commonring); brcmf_commonring_unlock(commonring); return i; } static void brcmf_msgbuf_rxbuf_ioctlresp_post(struct brcmf_msgbuf *msgbuf) { u32 count; count = msgbuf->max_ioctlrespbuf - msgbuf->cur_ioctlrespbuf; count = brcmf_msgbuf_rxbuf_ctrl_post(msgbuf, false, count); msgbuf->cur_ioctlrespbuf += count; } static void brcmf_msgbuf_rxbuf_event_post(struct brcmf_msgbuf *msgbuf) { u32 count; count = msgbuf->max_eventbuf - msgbuf->cur_eventbuf; count = brcmf_msgbuf_rxbuf_ctrl_post(msgbuf, true, count); msgbuf->cur_eventbuf += count; } static void brcmf_msgbuf_rx_skb(struct brcmf_msgbuf *msgbuf, struct sk_buff *skb, u8 ifidx) { struct brcmf_if *ifp; /* The ifidx is the idx to map to matching netdev/ifp. When receiving * events this is easy because it contains the bssidx which maps * 1-on-1 to the netdev/ifp. But for data frames the ifidx is rcvd. * bssidx 1 is used for p2p0 and no data can be received or * transmitted on it. Therefor bssidx is ifidx + 1 if ifidx > 0 */ if (ifidx) (ifidx)++; ifp = msgbuf->drvr->iflist[ifidx]; if (!ifp || !ifp->ndev) { brcmf_err("Received pkt for invalid ifidx %d\n", ifidx); brcmu_pkt_buf_free_skb(skb); return; } brcmf_netif_rx(ifp, skb); } static void brcmf_msgbuf_process_event(struct brcmf_msgbuf *msgbuf, void *buf) { struct msgbuf_rx_event *event; u32 idx; u16 buflen; struct sk_buff *skb; event = (struct msgbuf_rx_event *)buf; idx = le32_to_cpu(event->msg.request_id); buflen = le16_to_cpu(event->event_data_len); if (msgbuf->cur_eventbuf) msgbuf->cur_eventbuf--; brcmf_msgbuf_rxbuf_event_post(msgbuf); skb = brcmf_msgbuf_get_pktid(msgbuf->drvr->bus_if->dev, msgbuf->rx_pktids, idx); if (!skb) return; if (msgbuf->rx_dataoffset) skb_pull(skb, msgbuf->rx_dataoffset); skb_trim(skb, buflen); brcmf_msgbuf_rx_skb(msgbuf, skb, event->msg.ifidx); } static void brcmf_msgbuf_process_rx_complete(struct brcmf_msgbuf *msgbuf, void *buf) { struct msgbuf_rx_complete *rx_complete; struct sk_buff *skb; u16 data_offset; u16 buflen; u32 idx; brcmf_msgbuf_update_rxbufpost_count(msgbuf, 1); rx_complete = (struct msgbuf_rx_complete *)buf; data_offset = le16_to_cpu(rx_complete->data_offset); buflen = le16_to_cpu(rx_complete->data_len); idx = le32_to_cpu(rx_complete->msg.request_id); skb = brcmf_msgbuf_get_pktid(msgbuf->drvr->bus_if->dev, msgbuf->rx_pktids, idx); if (data_offset) skb_pull(skb, data_offset); else if (msgbuf->rx_dataoffset) skb_pull(skb, msgbuf->rx_dataoffset); skb_trim(skb, buflen); brcmf_msgbuf_rx_skb(msgbuf, skb, rx_complete->msg.ifidx); } static void brcmf_msgbuf_process_flow_ring_create_response(struct brcmf_msgbuf *msgbuf, void *buf) { struct msgbuf_flowring_create_resp *flowring_create_resp; u16 status; u16 flowid; flowring_create_resp = (struct msgbuf_flowring_create_resp *)buf; flowid = le16_to_cpu(flowring_create_resp->compl_hdr.flow_ring_id); flowid -= BRCMF_NROF_H2D_COMMON_MSGRINGS; status = le16_to_cpu(flowring_create_resp->compl_hdr.status); if (status) { brcmf_err("Flowring creation failed, code %d\n", status); brcmf_msgbuf_remove_flowring(msgbuf, flowid); return; } brcmf_dbg(MSGBUF, "Flowring %d Create response status %d\n", flowid, status); brcmf_flowring_open(msgbuf->flow, flowid); brcmf_msgbuf_schedule_txdata(msgbuf, flowid, true); } static void brcmf_msgbuf_process_flow_ring_delete_response(struct brcmf_msgbuf *msgbuf, void *buf) { struct msgbuf_flowring_delete_resp *flowring_delete_resp; u16 status; u16 flowid; flowring_delete_resp = (struct msgbuf_flowring_delete_resp *)buf; flowid = le16_to_cpu(flowring_delete_resp->compl_hdr.flow_ring_id); flowid -= BRCMF_NROF_H2D_COMMON_MSGRINGS; status = le16_to_cpu(flowring_delete_resp->compl_hdr.status); if (status) { brcmf_err("Flowring deletion failed, code %d\n", status); brcmf_flowring_delete(msgbuf->flow, flowid); return; } brcmf_dbg(MSGBUF, "Flowring %d Delete response status %d\n", flowid, status); brcmf_msgbuf_remove_flowring(msgbuf, flowid); } static void brcmf_msgbuf_process_msgtype(struct brcmf_msgbuf *msgbuf, void *buf) { struct msgbuf_common_hdr *msg; msg = (struct msgbuf_common_hdr *)buf; switch (msg->msgtype) { case MSGBUF_TYPE_FLOW_RING_CREATE_CMPLT: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_FLOW_RING_CREATE_CMPLT\n"); brcmf_msgbuf_process_flow_ring_create_response(msgbuf, buf); break; case MSGBUF_TYPE_FLOW_RING_DELETE_CMPLT: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_FLOW_RING_DELETE_CMPLT\n"); brcmf_msgbuf_process_flow_ring_delete_response(msgbuf, buf); break; case MSGBUF_TYPE_IOCTLPTR_REQ_ACK: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_IOCTLPTR_REQ_ACK\n"); break; case MSGBUF_TYPE_IOCTL_CMPLT: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_IOCTL_CMPLT\n"); brcmf_msgbuf_process_ioctl_complete(msgbuf, buf); break; case MSGBUF_TYPE_WL_EVENT: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_WL_EVENT\n"); brcmf_msgbuf_process_event(msgbuf, buf); break; case MSGBUF_TYPE_TX_STATUS: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_TX_STATUS\n"); brcmf_msgbuf_process_txstatus(msgbuf, buf); break; case MSGBUF_TYPE_RX_CMPLT: brcmf_dbg(MSGBUF, "MSGBUF_TYPE_RX_CMPLT\n"); brcmf_msgbuf_process_rx_complete(msgbuf, buf); break; default: brcmf_err("Unsupported msgtype %d\n", msg->msgtype); break; } } static void brcmf_msgbuf_process_rx(struct brcmf_msgbuf *msgbuf, struct brcmf_commonring *commonring) { void *buf; u16 count; again: buf = brcmf_commonring_get_read_ptr(commonring, &count); if (buf == NULL) return; while (count) { brcmf_msgbuf_process_msgtype(msgbuf, buf + msgbuf->rx_dataoffset); buf += brcmf_commonring_len_item(commonring); count--; } brcmf_commonring_read_complete(commonring); if (commonring->r_ptr == 0) goto again; } int brcmf_proto_msgbuf_rx_trigger(struct device *dev) { struct brcmf_bus *bus_if = dev_get_drvdata(dev); struct brcmf_pub *drvr = bus_if->drvr; struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; struct brcmf_commonring *commonring; void *buf; u32 flowid; int qlen; buf = msgbuf->commonrings[BRCMF_D2H_MSGRING_RX_COMPLETE]; brcmf_msgbuf_process_rx(msgbuf, buf); buf = msgbuf->commonrings[BRCMF_D2H_MSGRING_TX_COMPLETE]; brcmf_msgbuf_process_rx(msgbuf, buf); buf = msgbuf->commonrings[BRCMF_D2H_MSGRING_CONTROL_COMPLETE]; brcmf_msgbuf_process_rx(msgbuf, buf); for_each_set_bit(flowid, msgbuf->txstatus_done_map, msgbuf->nrof_flowrings) { clear_bit(flowid, msgbuf->txstatus_done_map); commonring = msgbuf->flowrings[flowid]; qlen = brcmf_flowring_qlen(msgbuf->flow, flowid); if ((qlen > BRCMF_MSGBUF_TRICKLE_TXWORKER_THRS) || ((qlen) && (atomic_read(&commonring->outstanding_tx) < BRCMF_MSGBUF_TRICKLE_TXWORKER_THRS))) brcmf_msgbuf_schedule_txdata(msgbuf, flowid, true); } return 0; } void brcmf_msgbuf_delete_flowring(struct brcmf_pub *drvr, u8 flowid) { struct brcmf_msgbuf *msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; struct msgbuf_tx_flowring_delete_req *delete; struct brcmf_commonring *commonring; void *ret_ptr; u8 ifidx; int err; commonring = msgbuf->commonrings[BRCMF_H2D_MSGRING_CONTROL_SUBMIT]; brcmf_commonring_lock(commonring); ret_ptr = brcmf_commonring_reserve_for_write(commonring); if (!ret_ptr) { brcmf_err("FW unaware, flowring will be removed !!\n"); brcmf_commonring_unlock(commonring); brcmf_msgbuf_remove_flowring(msgbuf, flowid); return; } delete = (struct msgbuf_tx_flowring_delete_req *)ret_ptr; ifidx = brcmf_flowring_ifidx_get(msgbuf->flow, flowid); delete->msg.msgtype = MSGBUF_TYPE_FLOW_RING_DELETE; delete->msg.ifidx = ifidx; delete->msg.request_id = 0; delete->flow_ring_id = cpu_to_le16(flowid + BRCMF_NROF_H2D_COMMON_MSGRINGS); delete->reason = 0; brcmf_dbg(MSGBUF, "Send Flow Delete Req flow ID %d, ifindex %d\n", flowid, ifidx); err = brcmf_commonring_write_complete(commonring); brcmf_commonring_unlock(commonring); if (err) { brcmf_err("Failed to submit RING_DELETE, flowring will be removed\n"); brcmf_msgbuf_remove_flowring(msgbuf, flowid); } } int brcmf_proto_msgbuf_attach(struct brcmf_pub *drvr) { struct brcmf_bus_msgbuf *if_msgbuf; struct brcmf_msgbuf *msgbuf; u64 address; u32 count; if_msgbuf = drvr->bus_if->msgbuf; msgbuf = kzalloc(sizeof(*msgbuf), GFP_KERNEL); if (!msgbuf) goto fail; msgbuf->txflow_wq = create_singlethread_workqueue("msgbuf_txflow"); if (msgbuf->txflow_wq == NULL) { brcmf_err("workqueue creation failed\n"); goto fail; } INIT_WORK(&msgbuf->txflow_work, brcmf_msgbuf_txflow_worker); count = BITS_TO_LONGS(if_msgbuf->nrof_flowrings); count = count * sizeof(unsigned long); msgbuf->flow_map = kzalloc(count, GFP_KERNEL); if (!msgbuf->flow_map) goto fail; msgbuf->txstatus_done_map = kzalloc(count, GFP_KERNEL); if (!msgbuf->txstatus_done_map) goto fail; msgbuf->drvr = drvr; msgbuf->ioctbuf = dma_alloc_coherent(drvr->bus_if->dev, BRCMF_TX_IOCTL_MAX_MSG_SIZE, &msgbuf->ioctbuf_handle, GFP_KERNEL); if (!msgbuf->ioctbuf) goto fail; address = (u64)msgbuf->ioctbuf_handle; msgbuf->ioctbuf_phys_hi = address >> 32; msgbuf->ioctbuf_phys_lo = address & 0xffffffff; drvr->proto->hdrpull = brcmf_msgbuf_hdrpull; drvr->proto->query_dcmd = brcmf_msgbuf_query_dcmd; drvr->proto->set_dcmd = brcmf_msgbuf_set_dcmd; drvr->proto->txdata = brcmf_msgbuf_txdata; drvr->proto->configure_addr_mode = brcmf_msgbuf_configure_addr_mode; drvr->proto->delete_peer = brcmf_msgbuf_delete_peer; drvr->proto->add_tdls_peer = brcmf_msgbuf_add_tdls_peer; drvr->proto->pd = msgbuf; init_waitqueue_head(&msgbuf->ioctl_resp_wait); msgbuf->commonrings = (struct brcmf_commonring **)if_msgbuf->commonrings; msgbuf->flowrings = (struct brcmf_commonring **)if_msgbuf->flowrings; msgbuf->nrof_flowrings = if_msgbuf->nrof_flowrings; msgbuf->flowring_dma_handle = kzalloc(msgbuf->nrof_flowrings * sizeof(*msgbuf->flowring_dma_handle), GFP_KERNEL); if (!msgbuf->flowring_dma_handle) goto fail; msgbuf->rx_dataoffset = if_msgbuf->rx_dataoffset; msgbuf->max_rxbufpost = if_msgbuf->max_rxbufpost; msgbuf->max_ioctlrespbuf = BRCMF_MSGBUF_MAX_IOCTLRESPBUF_POST; msgbuf->max_eventbuf = BRCMF_MSGBUF_MAX_EVENTBUF_POST; msgbuf->tx_pktids = brcmf_msgbuf_init_pktids(NR_TX_PKTIDS, DMA_TO_DEVICE); if (!msgbuf->tx_pktids) goto fail; msgbuf->rx_pktids = brcmf_msgbuf_init_pktids(NR_RX_PKTIDS, DMA_FROM_DEVICE); if (!msgbuf->rx_pktids) goto fail; msgbuf->flow = brcmf_flowring_attach(drvr->bus_if->dev, if_msgbuf->nrof_flowrings); if (!msgbuf->flow) goto fail; brcmf_dbg(MSGBUF, "Feeding buffers, rx data %d, rx event %d, rx ioctl resp %d\n", msgbuf->max_rxbufpost, msgbuf->max_eventbuf, msgbuf->max_ioctlrespbuf); count = 0; do { brcmf_msgbuf_rxbuf_data_fill(msgbuf); if (msgbuf->max_rxbufpost != msgbuf->rxbufpost) msleep(10); else break; count++; } while (count < 10); brcmf_msgbuf_rxbuf_event_post(msgbuf); brcmf_msgbuf_rxbuf_ioctlresp_post(msgbuf); INIT_WORK(&msgbuf->flowring_work, brcmf_msgbuf_flowring_worker); spin_lock_init(&msgbuf->flowring_work_lock); INIT_LIST_HEAD(&msgbuf->work_queue); return 0; fail: if (msgbuf) { kfree(msgbuf->flow_map); kfree(msgbuf->txstatus_done_map); brcmf_msgbuf_release_pktids(msgbuf); kfree(msgbuf->flowring_dma_handle); if (msgbuf->ioctbuf) dma_free_coherent(drvr->bus_if->dev, BRCMF_TX_IOCTL_MAX_MSG_SIZE, msgbuf->ioctbuf, msgbuf->ioctbuf_handle); kfree(msgbuf); } return -ENOMEM; } void brcmf_proto_msgbuf_detach(struct brcmf_pub *drvr) { struct brcmf_msgbuf *msgbuf; struct brcmf_msgbuf_work_item *work; brcmf_dbg(TRACE, "Enter\n"); if (drvr->proto->pd) { msgbuf = (struct brcmf_msgbuf *)drvr->proto->pd; cancel_work_sync(&msgbuf->flowring_work); while (!list_empty(&msgbuf->work_queue)) { work = list_first_entry(&msgbuf->work_queue, struct brcmf_msgbuf_work_item, queue); list_del(&work->queue); kfree(work); } kfree(msgbuf->flow_map); kfree(msgbuf->txstatus_done_map); if (msgbuf->txflow_wq) destroy_workqueue(msgbuf->txflow_wq); brcmf_flowring_detach(msgbuf->flow); dma_free_coherent(drvr->bus_if->dev, BRCMF_TX_IOCTL_MAX_MSG_SIZE, msgbuf->ioctbuf, msgbuf->ioctbuf_handle); brcmf_msgbuf_release_pktids(msgbuf); kfree(msgbuf->flowring_dma_handle); kfree(msgbuf); drvr->proto->pd = NULL; } }