/* * * Realtek Bluetooth USB driver * * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "rtk_coex.h" /* Software coex message can be sent to and receive from WiFi driver by * UDP socket or exported symbol */ /* #define RTK_COEX_OVER_SYMBOL */ #if BTRTL_HCI_IF == BTRTL_HCIUSB #include #include "rtk_bt.h" #undef RTKBT_DBG #undef RTKBT_INFO #undef RTKBT_WARN #undef RTKBT_ERR #elif BTRTL_HCI_IF == BTRTL_HCIUART /* #define HCI_VERSION_CODE KERNEL_VERSION(3, 14, 41) */ #define HCI_VERSION_CODE LINUX_VERSION_CODE #else #error "Please set type of HCI interface" #endif #define RTK_VERSION "1.2" #define RTKBT_DBG(fmt, arg...) printk(KERN_INFO "rtk_btcoex: " fmt "\n" , ## arg) #define RTKBT_INFO(fmt, arg...) printk(KERN_INFO "rtk_btcoex: " fmt "\n" , ## arg) #define RTKBT_WARN(fmt, arg...) printk(KERN_WARNING "rtk_btcoex: " fmt "\n", ## arg) #define RTKBT_ERR(fmt, arg...) printk(KERN_WARNING "rtk_btcoex: " fmt "\n", ## arg) static struct rtl_coex_struct btrtl_coex; #ifdef RTB_SOFTWARE_MAILBOX #ifdef RTK_COEX_OVER_SYMBOL static struct sk_buff_head rtw_q; static struct workqueue_struct *rtw_wq; static struct work_struct rtw_work; static u8 rtw_coex_on; #endif #endif #define is_profile_connected(profile) ((btrtl_coex.profile_bitmap & BIT(profile)) > 0) #define is_profile_busy(profile) ((btrtl_coex.profile_status & BIT(profile)) > 0) #ifdef RTB_SOFTWARE_MAILBOX static void rtk_handle_event_from_wifi(uint8_t * msg); #endif static int rtl_alloc_buff(struct rtl_coex_struct *coex) { struct rtl_hci_ev *ev; struct rtl_l2_buff *l2; int i; int order; unsigned long addr; unsigned long addr2; int ev_size; int l2_size; int n; spin_lock_init(&coex->buff_lock); INIT_LIST_HEAD(&coex->ev_used_list); INIT_LIST_HEAD(&coex->ev_free_list); INIT_LIST_HEAD(&coex->l2_used_list); INIT_LIST_HEAD(&coex->l2_free_list); n = NUM_RTL_HCI_EV * sizeof(struct rtl_hci_ev); ev_size = ALIGN(n, sizeof(unsigned long)); n = L2_MAX_PKTS * sizeof(struct rtl_l2_buff); l2_size = ALIGN(n, sizeof(unsigned long)); RTKBT_DBG("alloc buffers %d, %d for ev and l2", ev_size, l2_size); order = get_order(ev_size + l2_size); addr = __get_free_pages(GFP_KERNEL, order); if (!addr) { RTKBT_ERR("failed to alloc buffers for ev and l2."); return -ENOMEM; } memset((void *)addr, 0, ev_size + l2_size); coex->pages_addr = addr; coex->buff_size = ev_size + l2_size; ev = (struct rtl_hci_ev *)addr; for (i = 0; i < NUM_RTL_HCI_EV; i++) { list_add_tail(&ev->list, &coex->ev_free_list); ev++; } addr2 = addr + ev_size; l2 = (struct rtl_l2_buff *)addr2; for (i = 0; i < L2_MAX_PKTS; i++) { list_add_tail(&l2->list, &coex->l2_free_list); l2++; } return 0; } static void rtl_free_buff(struct rtl_coex_struct *coex) { struct rtl_hci_ev *ev; struct rtl_l2_buff *l2; unsigned long flags; spin_lock_irqsave(&coex->buff_lock, flags); while (!list_empty(&coex->ev_used_list)) { ev = list_entry(coex->ev_used_list.next, struct rtl_hci_ev, list); list_del(&ev->list); } while (!list_empty(&coex->ev_free_list)) { ev = list_entry(coex->ev_free_list.next, struct rtl_hci_ev, list); list_del(&ev->list); } while (!list_empty(&coex->l2_used_list)) { l2 = list_entry(coex->l2_used_list.next, struct rtl_l2_buff, list); list_del(&l2->list); } while (!list_empty(&coex->l2_free_list)) { l2 = list_entry(coex->l2_free_list.next, struct rtl_l2_buff, list); list_del(&l2->list); } spin_unlock_irqrestore(&coex->buff_lock, flags); if (coex->buff_size > 0) { free_pages(coex->pages_addr, get_order(coex->buff_size)); coex->pages_addr = 0; coex->buff_size = 0; } } static struct rtl_hci_ev *rtl_ev_node_get(struct rtl_coex_struct *coex) { struct rtl_hci_ev *ev; unsigned long flags; if (!coex->buff_size) return NULL; spin_lock_irqsave(&coex->buff_lock, flags); if (!list_empty(&coex->ev_free_list)) { ev = list_entry(coex->ev_free_list.next, struct rtl_hci_ev, list); list_del(&ev->list); } else ev = NULL; spin_unlock_irqrestore(&coex->buff_lock, flags); return ev; } static int rtl_ev_node_to_used(struct rtl_coex_struct *coex, struct rtl_hci_ev *ev) { unsigned long flags; spin_lock_irqsave(&coex->buff_lock, flags); list_add_tail(&ev->list, &coex->ev_used_list); spin_unlock_irqrestore(&coex->buff_lock, flags); return 0; } static struct rtl_l2_buff *rtl_l2_node_get(struct rtl_coex_struct *coex) { struct rtl_l2_buff *l2; unsigned long flags; if (!coex->buff_size) return NULL; spin_lock_irqsave(&coex->buff_lock, flags); if(!list_empty(&coex->l2_free_list)) { l2 = list_entry(coex->l2_free_list.next, struct rtl_l2_buff, list); list_del(&l2->list); } else l2 = NULL; spin_unlock_irqrestore(&coex->buff_lock, flags); return l2; } static int rtl_l2_node_to_used(struct rtl_coex_struct *coex, struct rtl_l2_buff *l2) { unsigned long flags; spin_lock_irqsave(&coex->buff_lock, flags); list_add_tail(&l2->list, &coex->l2_used_list); spin_unlock_irqrestore(&coex->buff_lock, flags); return 0; } static int8_t psm_to_profile_index(uint16_t psm) { switch (psm) { case PSM_AVCTP: case PSM_SDP: return -1; //ignore case PSM_HID: case PSM_HID_INT: return profile_hid; case PSM_AVDTP: return profile_a2dp; case PSM_PAN: case PSM_OPP: case PSM_FTP: case PSM_BIP: case PSM_RFCOMM: return profile_pan; default: return profile_pan; } } static rtk_prof_info *find_by_psm(u16 psm) { struct list_head *head = &btrtl_coex.profile_list; struct list_head *iter = NULL; struct list_head *temp = NULL; rtk_prof_info *desc = NULL; list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_prof_info, list); if (desc->psm == psm) return desc; } return NULL; } static void rtk_check_setup_timer(int8_t profile_index) { if (profile_index == profile_a2dp) { btrtl_coex.a2dp_packet_count = 0; btrtl_coex.a2dp_count_timer.expires = jiffies + msecs_to_jiffies(1000); mod_timer(&btrtl_coex.a2dp_count_timer, btrtl_coex.a2dp_count_timer.expires); } if (profile_index == profile_pan) { btrtl_coex.pan_packet_count = 0; btrtl_coex.pan_count_timer.expires = jiffies + msecs_to_jiffies(1000); mod_timer(&btrtl_coex.pan_count_timer, btrtl_coex.pan_count_timer.expires); } /* hogp & voice share one timer now */ if ((profile_index == profile_hogp) || (profile_index == profile_voice)) { if ((0 == btrtl_coex.profile_refcount[profile_hogp]) && (0 == btrtl_coex.profile_refcount[profile_voice])) { btrtl_coex.hogp_packet_count = 0; btrtl_coex.voice_packet_count = 0; btrtl_coex.hogp_count_timer.expires = jiffies + msecs_to_jiffies(1000); mod_timer(&btrtl_coex.hogp_count_timer, btrtl_coex.hogp_count_timer.expires); } } } static void rtk_check_del_timer(int8_t profile_index) { if (profile_a2dp == profile_index) { btrtl_coex.a2dp_packet_count = 0; del_timer_sync(&btrtl_coex.a2dp_count_timer); } if (profile_pan == profile_index) { btrtl_coex.pan_packet_count = 0; del_timer_sync(&btrtl_coex.pan_count_timer); } if (profile_hogp == profile_index) { btrtl_coex.hogp_packet_count = 0; if (btrtl_coex.profile_refcount[profile_voice] == 0) { del_timer_sync(&btrtl_coex.hogp_count_timer); } } if (profile_voice == profile_index) { btrtl_coex.voice_packet_count = 0; if (btrtl_coex.profile_refcount[profile_hogp] == 0) { del_timer_sync(&btrtl_coex.hogp_count_timer); } } } static rtk_conn_prof *find_connection_by_handle(struct rtl_coex_struct * coex, uint16_t handle) { struct list_head *head = &coex->conn_hash; struct list_head *iter = NULL, *temp = NULL; rtk_conn_prof *desc = NULL; list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_conn_prof, list); if ((handle & 0xEFF) == desc->handle) { return desc; } } return NULL; } static rtk_conn_prof *allocate_connection_by_handle(uint16_t handle) { rtk_conn_prof *phci_conn = NULL; phci_conn = kmalloc(sizeof(rtk_conn_prof), GFP_ATOMIC); if (phci_conn) phci_conn->handle = handle; return phci_conn; } static void init_connection_hash(struct rtl_coex_struct * coex) { struct list_head *head = &coex->conn_hash; INIT_LIST_HEAD(head); } static void add_connection_to_hash(struct rtl_coex_struct * coex, rtk_conn_prof * desc) { struct list_head *head = &coex->conn_hash; list_add_tail(&desc->list, head); } static void delete_connection_from_hash(rtk_conn_prof * desc) { if (desc) { list_del(&desc->list); kfree(desc); } } static void flush_connection_hash(struct rtl_coex_struct * coex) { struct list_head *head = &coex->conn_hash; struct list_head *iter = NULL, *temp = NULL; rtk_conn_prof *desc = NULL; list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_conn_prof, list); if (desc) { list_del(&desc->list); kfree(desc); } } //INIT_LIST_HEAD(head); } static void init_profile_hash(struct rtl_coex_struct * coex) { struct list_head *head = &coex->profile_list; INIT_LIST_HEAD(head); } static uint8_t list_allocate_add(uint16_t handle, uint16_t psm, int8_t profile_index, uint16_t dcid, uint16_t scid) { rtk_prof_info *pprof_info = NULL; if (profile_index < 0) { RTKBT_ERR("PSM 0x%x do not need parse", psm); return FALSE; } pprof_info = kmalloc(sizeof(rtk_prof_info), GFP_ATOMIC); if (NULL == pprof_info) { RTKBT_ERR("list_allocate_add: allocate error"); return FALSE; } /* Check if it is the second l2cap connection for a2dp * a2dp signal channel will be created first than media channel. */ if (psm == PSM_AVDTP) { rtk_prof_info *pinfo = find_by_psm(psm); if (!pinfo) { pprof_info->flags = A2DP_SIGNAL; RTKBT_INFO("%s: Add a2dp signal channel", __func__); } else { pprof_info->flags = A2DP_MEDIA; RTKBT_INFO("%s: Add a2dp media channel", __func__); } } pprof_info->handle = handle; pprof_info->psm = psm; pprof_info->scid = scid; pprof_info->dcid = dcid; pprof_info->profile_index = profile_index; list_add_tail(&(pprof_info->list), &(btrtl_coex.profile_list)); return TRUE; } static void delete_profile_from_hash(rtk_prof_info * desc) { RTKBT_DBG("Delete profile: hndl 0x%04x, psm 0x%04x, dcid 0x%04x, " "scid 0x%04x", desc->handle, desc->psm, desc->dcid, desc->scid); if (desc) { list_del(&desc->list); kfree(desc); desc = NULL; } } static void flush_profile_hash(struct rtl_coex_struct * coex) { struct list_head *head = &coex->profile_list; struct list_head *iter = NULL, *temp = NULL; rtk_prof_info *desc = NULL; spin_lock(&btrtl_coex.spin_lock_profile); list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_prof_info, list); delete_profile_from_hash(desc); } //INIT_LIST_HEAD(head); spin_unlock(&btrtl_coex.spin_lock_profile); } static rtk_prof_info *find_profile_by_handle_scid(struct rtl_coex_struct * coex, uint16_t handle, uint16_t scid) { struct list_head *head = &coex->profile_list; struct list_head *iter = NULL, *temp = NULL; rtk_prof_info *desc = NULL; list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_prof_info, list); if (((handle & 0xFFF) == desc->handle) && (scid == desc->scid)) { return desc; } } return NULL; } static rtk_prof_info *find_profile_by_handle_dcid(struct rtl_coex_struct * coex, uint16_t handle, uint16_t dcid) { struct list_head *head = &coex->profile_list; struct list_head *iter = NULL, *temp = NULL; rtk_prof_info *desc = NULL; list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_prof_info, list); if (((handle & 0xFFF) == desc->handle) && (dcid == desc->dcid)) { return desc; } } return NULL; } static rtk_prof_info *find_profile_by_handle_dcid_scid(struct rtl_coex_struct * coex, uint16_t handle, uint16_t dcid, uint16_t scid) { struct list_head *head = &coex->profile_list; struct list_head *iter = NULL, *temp = NULL; rtk_prof_info *desc = NULL; list_for_each_safe(iter, temp, head) { desc = list_entry(iter, rtk_prof_info, list); if (((handle & 0xFFF) == desc->handle) && (dcid == desc->dcid) && (scid == desc->scid)) { return desc; } } return NULL; } static void rtk_vendor_cmd_to_fw(uint16_t opcode, uint8_t parameter_len, uint8_t * parameter) { int len = HCI_CMD_PREAMBLE_SIZE + parameter_len; uint8_t *p; struct sk_buff *skb; struct hci_dev *hdev = btrtl_coex.hdev; if (!hdev) { RTKBT_ERR("No HCI device"); return; } else if (!test_bit(HCI_UP, &hdev->flags)) { RTKBT_WARN("HCI device is down"); return; } skb = bt_skb_alloc(len, GFP_ATOMIC); if (!skb) { RTKBT_DBG("there is no room for cmd 0x%x", opcode); return; } p = (uint8_t *) skb_put(skb, HCI_CMD_PREAMBLE_SIZE); UINT16_TO_STREAM(p, opcode); *p++ = parameter_len; if (parameter_len) memcpy(skb_put(skb, parameter_len), parameter, parameter_len); bt_cb(skb)->pkt_type = HCI_COMMAND_PKT; #if HCI_VERSION_CODE >= KERNEL_VERSION(3, 18, 0) #if HCI_VERSION_CODE < KERNEL_VERSION(4, 4, 0) bt_cb(skb)->opcode = opcode; #else bt_cb(skb)->hci.opcode = opcode; #endif #endif /* Stand-alone HCI commands must be flagged as * single-command requests. */ #if HCI_VERSION_CODE >= KERNEL_VERSION(3, 10, 0) #if HCI_VERSION_CODE < KERNEL_VERSION(4, 4, 0) bt_cb(skb)->req.start = true; #else #if HCI_VERSION_CODE < KERNEL_VERSION(4, 5, 0) bt_cb(skb)->hci.req_start = true; #else bt_cb(skb)->hci.req_flags |= HCI_REQ_START; #endif #endif /* 4.4.0 */ #endif /* 3.10.0 */ RTKBT_DBG("%s: opcode 0x%x", __func__, opcode); /* It is harmless if set skb->dev twice. The dev will be used in * btusb_send_frame() after or equal to kernel/hci 3.13.0, * the hdev will not come from skb->dev. */ #if HCI_VERSION_CODE < KERNEL_VERSION(3, 13, 0) skb->dev = (void *)btrtl_coex.hdev; #endif /* Put the skb to the global hdev->cmd_q */ skb_queue_tail(&hdev->cmd_q, skb); #if HCI_VERSION_CODE < KERNEL_VERSION(3, 3, 0) tasklet_schedule(&hdev->cmd_task); #else queue_work(hdev->workqueue, &hdev->cmd_work); #endif return; } static void rtk_notify_profileinfo_to_fw(void) { struct list_head *head = NULL; struct list_head *iter = NULL; struct list_head *temp = NULL; rtk_conn_prof *hci_conn = NULL; uint8_t handle_number = 0; uint32_t buffer_size = 0; uint8_t *p_buf = NULL; uint8_t *p = NULL; head = &btrtl_coex.conn_hash; list_for_each_safe(iter, temp, head) { hci_conn = list_entry(iter, rtk_conn_prof, list); if (hci_conn && hci_conn->profile_bitmap) handle_number++; } buffer_size = 1 + handle_number * 3 + 1; p_buf = kmalloc(buffer_size, GFP_ATOMIC); if (NULL == p_buf) { RTKBT_ERR("%s: alloc error", __func__); return; } p = p_buf; RTKBT_DBG("%s: BufferSize %u", __func__, buffer_size); *p++ = handle_number; RTKBT_DBG("%s: NumberOfHandles %u", __func__, handle_number); head = &btrtl_coex.conn_hash; list_for_each(iter, head) { hci_conn = list_entry(iter, rtk_conn_prof, list); if (hci_conn && hci_conn->profile_bitmap) { UINT16_TO_STREAM(p, hci_conn->handle); RTKBT_DBG("%s: handle 0x%04x", __func__, hci_conn->handle); *p++ = hci_conn->profile_bitmap; RTKBT_DBG("%s: profile_bitmap 0x%02x", __func__, hci_conn->profile_bitmap); handle_number--; } if (0 == handle_number) break; } *p++ = btrtl_coex.profile_status; RTKBT_DBG("%s: profile_status 0x%02x", __func__, btrtl_coex.profile_status); rtk_vendor_cmd_to_fw(HCI_VENDOR_SET_PROFILE_REPORT_COMMAND, buffer_size, p_buf); kfree(p_buf); return; } static void update_profile_state(uint8_t profile_index, uint8_t is_busy) { uint8_t need_update = FALSE; if ((btrtl_coex.profile_bitmap & BIT(profile_index)) == 0) { RTKBT_ERR("%s: : ERROR!!! profile(Index: %x) does not exist", __func__, profile_index); return; } if (is_busy) { if ((btrtl_coex.profile_status & BIT(profile_index)) == 0) { need_update = TRUE; btrtl_coex.profile_status |= BIT(profile_index); } } else { if ((btrtl_coex.profile_status & BIT(profile_index)) > 0) { need_update = TRUE; btrtl_coex.profile_status &= ~(BIT(profile_index)); } } if (need_update) { RTKBT_DBG("%s: btrtl_coex.profie_bitmap = %x", __func__, btrtl_coex.profile_bitmap); RTKBT_DBG("%s: btrtl_coex.profile_status = %x", __func__, btrtl_coex.profile_status); rtk_notify_profileinfo_to_fw(); } } static void update_profile_connection(rtk_conn_prof * phci_conn, int8_t profile_index, uint8_t is_add) { uint8_t need_update = FALSE; uint8_t kk; RTKBT_DBG("%s: is_add %d, profile_index %x", __func__, is_add, profile_index); if (profile_index < 0) return; if (is_add) { if (btrtl_coex.profile_refcount[profile_index] == 0) { need_update = TRUE; btrtl_coex.profile_bitmap |= BIT(profile_index); /* SCO is always busy */ if (profile_index == profile_sco) btrtl_coex.profile_status |= BIT(profile_index); rtk_check_setup_timer(profile_index); } btrtl_coex.profile_refcount[profile_index]++; if (0 == phci_conn->profile_refcount[profile_index]) { need_update = TRUE; phci_conn->profile_bitmap |= BIT(profile_index); } phci_conn->profile_refcount[profile_index]++; } else { if (!btrtl_coex.profile_refcount[profile_index]) { RTKBT_WARN("profile %u refcount is already zero", profile_index); return; } btrtl_coex.profile_refcount[profile_index]--; RTKBT_DBG("%s: btrtl_coex.profile_refcount[%x] = %x", __func__, profile_index, btrtl_coex.profile_refcount[profile_index]); if (btrtl_coex.profile_refcount[profile_index] == 0) { need_update = TRUE; btrtl_coex.profile_bitmap &= ~(BIT(profile_index)); /* if profile does not exist, status is meaningless */ btrtl_coex.profile_status &= ~(BIT(profile_index)); rtk_check_del_timer(profile_index); } phci_conn->profile_refcount[profile_index]--; if (0 == phci_conn->profile_refcount[profile_index]) { need_update = TRUE; phci_conn->profile_bitmap &= ~(BIT(profile_index)); /* clear profile_hid_interval if need */ if ((profile_hid == profile_index) && (phci_conn-> profile_bitmap & (BIT(profile_hid_interval)))) { phci_conn->profile_bitmap &= ~(BIT(profile_hid_interval)); btrtl_coex. profile_refcount[profile_hid_interval]--; } } } RTKBT_DBG("%s: btrtl_coex.profile_bitmap 0x%02x", __func__, btrtl_coex.profile_bitmap); for (kk = 0; kk < 8; kk++) RTKBT_DBG("%s: btrtl_coex.profile_refcount[%d] = %d", __func__, kk, btrtl_coex.profile_refcount[kk]); if (need_update) rtk_notify_profileinfo_to_fw(); } static void update_hid_active_state(uint16_t handle, uint16_t interval) { uint8_t need_update = 0; rtk_conn_prof *phci_conn = find_connection_by_handle(&btrtl_coex, handle); if (phci_conn == NULL) return; RTKBT_DBG("%s: handle 0x%04x, interval %u", __func__, handle, interval); if (((phci_conn->profile_bitmap) & (BIT(profile_hid))) == 0) { RTKBT_DBG("HID not connected, nothing to be down"); return; } if (interval < 60) { if ((phci_conn->profile_bitmap & (BIT(profile_hid_interval))) == 0) { need_update = 1; phci_conn->profile_bitmap |= BIT(profile_hid_interval); btrtl_coex.profile_refcount[profile_hid_interval]++; if (btrtl_coex. profile_refcount[profile_hid_interval] == 1) btrtl_coex.profile_status |= BIT(profile_hid); } } else { if ((phci_conn->profile_bitmap & (BIT(profile_hid_interval)))) { need_update = 1; phci_conn->profile_bitmap &= ~(BIT(profile_hid_interval)); btrtl_coex.profile_refcount[profile_hid_interval]--; if (btrtl_coex. profile_refcount[profile_hid_interval] == 0) btrtl_coex.profile_status &= ~(BIT(profile_hid)); } } if (need_update) rtk_notify_profileinfo_to_fw(); } static uint8_t handle_l2cap_con_req(uint16_t handle, uint16_t psm, uint16_t scid, uint8_t direction) { uint8_t status = FALSE; rtk_prof_info *prof_info = NULL; int8_t profile_index = psm_to_profile_index(psm); if (profile_index < 0) { RTKBT_DBG("PSM(0x%04x) do not need parse", psm); return status; } spin_lock(&btrtl_coex.spin_lock_profile); if (direction) //1: out prof_info = find_profile_by_handle_scid(&btrtl_coex, handle, scid); else // 0:in prof_info = find_profile_by_handle_dcid(&btrtl_coex, handle, scid); if (prof_info) { RTKBT_DBG("%s: this profile is already exist!", __func__); spin_unlock(&btrtl_coex.spin_lock_profile); return status; } if (direction) //1: out status = list_allocate_add(handle, psm, profile_index, 0, scid); else // 0:in status = list_allocate_add(handle, psm, profile_index, scid, 0); spin_unlock(&btrtl_coex.spin_lock_profile); if (!status) RTKBT_ERR("%s: list_allocate_add failed!", __func__); return status; } static uint8_t handle_l2cap_con_rsp(uint16_t handle, uint16_t dcid, uint16_t scid, uint8_t direction, uint8_t result) { rtk_prof_info *prof_info = NULL; rtk_conn_prof *phci_conn = NULL; spin_lock(&btrtl_coex.spin_lock_profile); if (!direction) //0, in prof_info = find_profile_by_handle_scid(&btrtl_coex, handle, scid); else //1, out prof_info = find_profile_by_handle_dcid(&btrtl_coex, handle, scid); if (!prof_info) { //RTKBT_DBG("handle_l2cap_con_rsp: prof_info Not Find!!"); spin_unlock(&btrtl_coex.spin_lock_profile); return FALSE; } if (!result) { //success RTKBT_DBG("l2cap connection success, update connection"); if (!direction) //0, in prof_info->dcid = dcid; else //1, out prof_info->scid = dcid; phci_conn = find_connection_by_handle(&btrtl_coex, handle); if (phci_conn) update_profile_connection(phci_conn, prof_info->profile_index, TRUE); } spin_unlock(&btrtl_coex.spin_lock_profile); return TRUE; } static uint8_t handle_l2cap_discon_req(uint16_t handle, uint16_t dcid, uint16_t scid, uint8_t direction) { rtk_prof_info *prof_info = NULL; rtk_conn_prof *phci_conn = NULL; RTKBT_DBG("%s: handle 0x%04x, dcid 0x%04x, scid 0x%04x, dir %u", __func__, handle, dcid, scid, direction); spin_lock(&btrtl_coex.spin_lock_profile); if (!direction) //0: in prof_info = find_profile_by_handle_dcid_scid(&btrtl_coex, handle, scid, dcid); else //1: out prof_info = find_profile_by_handle_dcid_scid(&btrtl_coex, handle, dcid, scid); if (!prof_info) { //LogMsg("handle_l2cap_discon_req: prof_info Not Find!"); spin_unlock(&btrtl_coex.spin_lock_profile); return 0; } phci_conn = find_connection_by_handle(&btrtl_coex, handle); if (!phci_conn) { spin_unlock(&btrtl_coex.spin_lock_profile); return 0; } update_profile_connection(phci_conn, prof_info->profile_index, FALSE); if (prof_info->profile_index == profile_a2dp && (phci_conn->profile_bitmap & BIT(profile_sink))) update_profile_connection(phci_conn, profile_sink, FALSE); delete_profile_from_hash(prof_info); spin_unlock(&btrtl_coex.spin_lock_profile); return 1; } static const char sample_freqs[4][8] = { "16", "32", "44.1", "48" }; static const uint8_t sbc_blocks[4] = { 4, 8, 12, 16 }; static const char chan_modes[4][16] = { "MONO", "DUAL_CHANNEL", "STEREO", "JOINT_STEREO" }; static const char alloc_methods[2][12] = { "LOUDNESS", "SNR" }; static const uint8_t subbands[2] = { 4, 8 }; void print_sbc_header(struct sbc_frame_hdr *hdr) { RTKBT_DBG("syncword: %02x", hdr->syncword); RTKBT_DBG("freq %skHz", sample_freqs[hdr->sampling_frequency]); RTKBT_DBG("blocks %u", sbc_blocks[hdr->blocks]); RTKBT_DBG("channel mode %s", chan_modes[hdr->channel_mode]); RTKBT_DBG("allocation method %s", alloc_methods[hdr->allocation_method]); RTKBT_DBG("subbands %u", subbands[hdr->subbands]); } static void packets_count(uint16_t handle, uint16_t scid, uint16_t length, uint8_t direction, u8 *user_data) { rtk_prof_info *prof_info = NULL; rtk_conn_prof *hci_conn = find_connection_by_handle(&btrtl_coex, handle); if (NULL == hci_conn) return; if (0 == hci_conn->type) { if (!direction) //0: in prof_info = find_profile_by_handle_scid(&btrtl_coex, handle, scid); else //1: out prof_info = find_profile_by_handle_dcid(&btrtl_coex, handle, scid); if (!prof_info) { //RTKBT_DBG("packets_count: prof_info Not Find!"); return; } /* avdtp media data */ if (prof_info->profile_index == profile_a2dp && prof_info->flags == A2DP_MEDIA) { if (!is_profile_busy(profile_a2dp)) { struct sbc_frame_hdr *sbc_header; struct rtp_header *rtph; u8 bitpool; update_profile_state(profile_a2dp, TRUE); if (!direction) { if (!(hci_conn->profile_bitmap & BIT(profile_sink))) { btrtl_coex.profile_bitmap |= BIT(profile_sink); hci_conn->profile_bitmap |= BIT(profile_sink); update_profile_connection(hci_conn, profile_sink, 1); } update_profile_state(profile_sink, TRUE); } /* We assume it is SBC if the packet length * is bigger than 100 bytes */ if (length > 100) { RTKBT_INFO("Length %u", length); rtph = (struct rtp_header *)user_data; RTKBT_DBG("rtp: v %u, cc %u, pt %u", rtph->v, rtph->cc, rtph->pt); /* move forward */ user_data += sizeof(struct rtp_header) + rtph->cc * 4 + 1; /* point to the sbc frame header */ sbc_header = (struct sbc_frame_hdr *)user_data; bitpool = sbc_header->bitpool; print_sbc_header(sbc_header); RTKBT_DBG("bitpool %u", bitpool); rtk_vendor_cmd_to_fw(HCI_VENDOR_SET_BITPOOL, 1, &bitpool); } } btrtl_coex.a2dp_packet_count++; } if (prof_info->profile_index == profile_pan) btrtl_coex.pan_packet_count++; } } #if LINUX_VERSION_CODE > KERNEL_VERSION(4, 14, 0) static void count_a2dp_packet_timeout(struct timer_list *unused) #else static void count_a2dp_packet_timeout(unsigned long data) #endif { if (btrtl_coex.a2dp_packet_count) RTKBT_DBG("%s: a2dp_packet_count %d", __func__, btrtl_coex.a2dp_packet_count); if (btrtl_coex.a2dp_packet_count == 0) { if (is_profile_busy(profile_a2dp)) { RTKBT_DBG("%s: a2dp busy->idle!", __func__); update_profile_state(profile_a2dp, FALSE); if (btrtl_coex.profile_bitmap & BIT(profile_sink)) update_profile_state(profile_sink, FALSE); } } btrtl_coex.a2dp_packet_count = 0; mod_timer(&btrtl_coex.a2dp_count_timer, jiffies + msecs_to_jiffies(1000)); } #if LINUX_VERSION_CODE > KERNEL_VERSION(4, 14, 0) static void count_pan_packet_timeout(struct timer_list *unused) #else static void count_pan_packet_timeout(unsigned long data) #endif { if (btrtl_coex.pan_packet_count) RTKBT_DBG("%s: pan_packet_count %d", __func__, btrtl_coex.pan_packet_count); if (btrtl_coex.pan_packet_count < PAN_PACKET_COUNT) { if (is_profile_busy(profile_pan)) { RTKBT_DBG("%s: pan busy->idle!", __func__); update_profile_state(profile_pan, FALSE); } } else { if (!is_profile_busy(profile_pan)) { RTKBT_DBG("timeout_handler: pan idle->busy!"); update_profile_state(profile_pan, TRUE); } } btrtl_coex.pan_packet_count = 0; mod_timer(&btrtl_coex.pan_count_timer, jiffies + msecs_to_jiffies(1000)); } #if LINUX_VERSION_CODE > KERNEL_VERSION(4, 14, 0) static void count_hogp_packet_timeout(struct timer_list *unused) #else static void count_hogp_packet_timeout(unsigned long data) #endif { if (btrtl_coex.hogp_packet_count) RTKBT_DBG("%s: hogp_packet_count %d", __func__, btrtl_coex.hogp_packet_count); if (btrtl_coex.hogp_packet_count == 0) { if (is_profile_busy(profile_hogp)) { RTKBT_DBG("%s: hogp busy->idle!", __func__); update_profile_state(profile_hogp, FALSE); } } btrtl_coex.hogp_packet_count = 0; if (btrtl_coex.voice_packet_count) RTKBT_DBG("%s: voice_packet_count %d", __func__, btrtl_coex.voice_packet_count); if (btrtl_coex.voice_packet_count == 0) { if (is_profile_busy(profile_voice)) { RTKBT_DBG("%s: voice busy->idle!", __func__); update_profile_state(profile_voice, FALSE); } } btrtl_coex.voice_packet_count = 0; mod_timer(&btrtl_coex.hogp_count_timer, jiffies + msecs_to_jiffies(1000)); } #ifdef RTB_SOFTWARE_MAILBOX #ifndef RTK_COEX_OVER_SYMBOL static int udpsocket_send(char *tx_msg, int msg_size) { u8 error = 0; struct msghdr udpmsg; mm_segment_t oldfs; struct iovec iov; RTKBT_DBG("send msg %s with len:%d", tx_msg, msg_size); if (btrtl_coex.sock_open) { iov.iov_base = (void *)tx_msg; iov.iov_len = msg_size; udpmsg.msg_name = &btrtl_coex.wifi_addr; udpmsg.msg_namelen = sizeof(struct sockaddr_in); #if LINUX_VERSION_CODE < KERNEL_VERSION(3, 19, 0) udpmsg.msg_iov = &iov; udpmsg.msg_iovlen = 1; #else iov_iter_init(&udpmsg.msg_iter, WRITE, &iov, 1, msg_size); #endif udpmsg.msg_control = NULL; udpmsg.msg_controllen = 0; udpmsg.msg_flags = MSG_DONTWAIT | MSG_NOSIGNAL; oldfs = get_fs(); set_fs(KERNEL_DS); #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 1, 0) error = sock_sendmsg(btrtl_coex.udpsock, &udpmsg, msg_size); #else error = sock_sendmsg(btrtl_coex.udpsock, &udpmsg); #endif set_fs(oldfs); if (error < 0) RTKBT_DBG("Error when sendimg msg, error:%d", error); } return error; } #endif #ifdef RTK_COEX_OVER_SYMBOL /* Receive message from WiFi */ u8 rtw_btcoex_wifi_to_bt(u8 *msg, u8 msg_size) { struct sk_buff *nskb; if (!rtw_coex_on) { RTKBT_WARN("Bluetooth is closed"); return 0; } nskb = alloc_skb(msg_size, GFP_ATOMIC); if (!nskb) { RTKBT_ERR("Couldnt alloc skb for WiFi coex message"); return 0; } memcpy(skb_put(nskb, msg_size), msg, msg_size); skb_queue_tail(&rtw_q, nskb); queue_work(rtw_wq, &rtw_work); return 1; } EXPORT_SYMBOL(rtw_btcoex_wifi_to_bt); static int rtk_send_coexmsg2wifi(u8 *msg, u8 size) { u8 result; u8 (*btmsg_to_wifi)(u8 *, u8); btmsg_to_wifi = __symbol_get(VMLINUX_SYMBOL_STR(rtw_btcoex_bt_to_wifi)); if (!btmsg_to_wifi) { /* RTKBT_ERR("Couldnt get symbol"); */ return -1; } result = btmsg_to_wifi(msg, size); __symbol_put(VMLINUX_SYMBOL_STR(rtw_btcoex_bt_to_wifi)); if (!result) { RTKBT_ERR("Couldnt send coex msg to WiFi"); return -1; } else if (result == 1){ /* successful to send message */ return 0; } else { RTKBT_ERR("Unknown result %d", result); return -1; } } static int rtkbt_process_coexskb(struct sk_buff *skb) { rtk_handle_event_from_wifi(skb->data); return 0; } static void rtw_work_func(struct work_struct *work) { struct sk_buff *skb; while ((skb = skb_dequeue(&rtw_q))) { rtkbt_process_coexskb(skb); kfree_skb(skb); } } #endif static int rtkbt_coexmsg_send(char *tx_msg, int msg_size) { #ifdef RTK_COEX_OVER_SYMBOL return rtk_send_coexmsg2wifi((uint8_t *)tx_msg, (u8)msg_size); #else return udpsocket_send(tx_msg, msg_size); #endif } #ifndef RTK_COEX_OVER_SYMBOL static void udpsocket_recv_data(void) { u8 recv_data[512]; u32 len = 0; u16 recv_length; struct sk_buff *skb; RTKBT_DBG("-"); spin_lock(&btrtl_coex.spin_lock_sock); len = skb_queue_len(&btrtl_coex.sk->sk_receive_queue); while (len > 0) { skb = skb_dequeue(&btrtl_coex.sk->sk_receive_queue); /*important: cut the udp header from skb->data! header length is 8 byte */ recv_length = skb->len - 8; memset(recv_data, 0, sizeof(recv_data)); memcpy(recv_data, skb->data + 8, recv_length); //RTKBT_DBG("received data: %s :with len %u", recv_data, recv_length); rtk_handle_event_from_wifi(recv_data); len--; kfree_skb(skb); } spin_unlock(&btrtl_coex.spin_lock_sock); } #if LINUX_VERSION_CODE < KERNEL_VERSION(3, 15, 0) static void udpsocket_recv(struct sock *sk, int bytes) #else static void udpsocket_recv(struct sock *sk) #endif { spin_lock(&btrtl_coex.spin_lock_sock); btrtl_coex.sk = sk; spin_unlock(&btrtl_coex.spin_lock_sock); queue_delayed_work(btrtl_coex.sock_wq, &btrtl_coex.sock_work, 0); } static void create_udpsocket(void) { int err; RTKBT_DBG("%s: connect_port: %d", __func__, CONNECT_PORT); btrtl_coex.sock_open = 0; err = sock_create(AF_INET, SOCK_DGRAM, IPPROTO_UDP, &btrtl_coex.udpsock); if (err < 0) { RTKBT_ERR("%s: sock create error, err = %d", __func__, err); return; } memset(&btrtl_coex.addr, 0, sizeof(struct sockaddr_in)); btrtl_coex.addr.sin_family = AF_INET; btrtl_coex.addr.sin_addr.s_addr = htonl(INADDR_LOOPBACK); btrtl_coex.addr.sin_port = htons(CONNECT_PORT); memset(&btrtl_coex.wifi_addr, 0, sizeof(struct sockaddr_in)); btrtl_coex.wifi_addr.sin_family = AF_INET; btrtl_coex.wifi_addr.sin_addr.s_addr = htonl(INADDR_LOOPBACK); btrtl_coex.wifi_addr.sin_port = htons(CONNECT_PORT_WIFI); err = btrtl_coex.udpsock->ops->bind(btrtl_coex.udpsock, (struct sockaddr *)&btrtl_coex. addr, sizeof(struct sockaddr)); if (err < 0) { sock_release(btrtl_coex.udpsock); RTKBT_ERR("%s: sock bind error, err = %d",__func__, err); return; } btrtl_coex.sock_open = 1; btrtl_coex.udpsock->sk->sk_data_ready = udpsocket_recv; } #endif /* !RTK_COEX_OVER_SYMBOL */ static void rtk_notify_extension_version_to_wifi(void) { uint8_t para_length = 2; char p_buf[2 + HCI_CMD_PREAMBLE_SIZE]; char *p = p_buf; if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_HCI_EXTENSION_VERSION_NOTIFY); *p++ = para_length; UINT16_TO_STREAM(p, HCI_EXTENSION_VERSION); RTKBT_DBG("extension version is 0x%x", HCI_EXTENSION_VERSION); if (rtkbt_coexmsg_send(p_buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } static void rtk_notify_btpatch_version_to_wifi(void) { uint8_t para_length = 4; char p_buf[para_length + HCI_CMD_PREAMBLE_SIZE]; char *p = p_buf; if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_HCI_BT_PATCH_VER_NOTIFY); *p++ = para_length; UINT16_TO_STREAM(p, btrtl_coex.hci_reversion); UINT16_TO_STREAM(p, btrtl_coex.lmp_subversion); RTKBT_DBG("btpatch ver: len %u, hci_rev 0x%04x, lmp_subver 0x%04x", para_length, btrtl_coex.hci_reversion, btrtl_coex.lmp_subversion); if (rtkbt_coexmsg_send(p_buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } static void rtk_notify_afhmap_to_wifi(void) { uint8_t para_length = 13; char p_buf[para_length + HCI_CMD_PREAMBLE_SIZE]; char *p = p_buf; uint8_t kk = 0; if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_HCI_BT_AFH_MAP_NOTIFY); *p++ = para_length; *p++ = btrtl_coex.piconet_id; *p++ = btrtl_coex.mode; *p++ = 10; memcpy(p, btrtl_coex.afh_map, 10); RTKBT_DBG("afhmap, piconet_id is 0x%x, map type is 0x%x", btrtl_coex.piconet_id, btrtl_coex.mode); for (kk = 0; kk < 10; kk++) RTKBT_DBG("afhmap data[%d] is 0x%x", kk, btrtl_coex.afh_map[kk]); if (rtkbt_coexmsg_send(p_buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } static void rtk_notify_btcoex_to_wifi(uint8_t opcode, uint8_t status) { uint8_t para_length = 2; char p_buf[para_length + HCI_CMD_PREAMBLE_SIZE]; char *p = p_buf; if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_HCI_BT_COEX_NOTIFY); *p++ = para_length; *p++ = opcode; if (!status) *p++ = 0; else *p++ = 1; RTKBT_DBG("btcoex, opcode is 0x%x, status is 0x%x", opcode, status); if (rtkbt_coexmsg_send(p_buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } static void rtk_notify_btoperation_to_wifi(uint8_t operation, uint8_t append_data_length, uint8_t * append_data) { uint8_t para_length = 3 + append_data_length; char p_buf[para_length + HCI_CMD_PREAMBLE_SIZE]; char *p = p_buf; uint8_t kk = 0; if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_BT_OPERATION_NOTIFY); *p++ = para_length; *p++ = operation; *p++ = append_data_length; if (append_data_length) memcpy(p, append_data, append_data_length); RTKBT_DBG("btoperation: op 0x%02x, append_data_length %u", operation, append_data_length); if (append_data_length) { for (kk = 0; kk < append_data_length; kk++) RTKBT_DBG("append data is 0x%x", *(append_data + kk)); } if (rtkbt_coexmsg_send(p_buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } static void rtk_notify_info_to_wifi(uint8_t reason, uint8_t length, uint8_t *report_info) { uint8_t para_length = 4 + length; char buf[para_length + HCI_CMD_PREAMBLE_SIZE]; char *p = buf; struct rtl_btinfo *report = (struct rtl_btinfo *)report_info; if (length) { RTKBT_DBG("bt info: cmd %2.2X", report->cmd); RTKBT_DBG("bt info: len %2.2X", report->len); RTKBT_DBG("bt info: data %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X", report->data[0], report->data[1], report->data[2], report->data[3], report->data[4], report->data[5]); } RTKBT_DBG("bt info: reason 0x%2x, length 0x%2x", reason, length); if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_HCI_BT_INFO_NOTIFY); *p++ = para_length; *p++ = btrtl_coex.polling_enable; *p++ = btrtl_coex.polling_interval; *p++ = reason; *p++ = length; if (length) memcpy(p, report_info, length); RTKBT_DBG("para length %2x, polling_enable %u, poiiling_interval %u", para_length, btrtl_coex.polling_enable, btrtl_coex.polling_interval); /* send BT INFO to Wi-Fi driver */ if (rtkbt_coexmsg_send(buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } static void rtk_notify_regester_to_wifi(uint8_t * reg_value) { uint8_t para_length = 9; char p_buf[para_length + HCI_CMD_PREAMBLE_SIZE]; char *p = p_buf; hci_mailbox_register *reg = (hci_mailbox_register *) reg_value; if (!btrtl_coex.wifi_on) return; UINT16_TO_STREAM(p, HCI_OP_HCI_BT_REGISTER_VALUE_NOTIFY); *p++ = para_length; memcpy(p, reg_value, para_length); RTKBT_DBG("bt register, register type is %x", reg->type); RTKBT_DBG("bt register, register offset is %x", reg->offset); RTKBT_DBG("bt register, register value is %x", reg->value); if (rtkbt_coexmsg_send(p_buf, para_length + HCI_CMD_PREAMBLE_SIZE) < 0) RTKBT_ERR("%s: sock send error", __func__); } #endif void rtk_btcoex_parse_cmd(uint8_t *buffer, int count) { u16 opcode = (buffer[0]) + (buffer[1] << 8); if (!test_bit(RTL_COEX_RUNNING, &btrtl_coex.flags)) { RTKBT_INFO("%s: Coex is closed, ignore", __func__); return; } switch (opcode) { case HCI_OP_INQUIRY: case HCI_OP_PERIODIC_INQ: if (!btrtl_coex.isinquirying) { btrtl_coex.isinquirying = 1; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci (periodic)inq, notify wifi " "inquiry start"); rtk_notify_btoperation_to_wifi(BT_OPCODE_INQUIRY_START, 0, NULL); #else RTKBT_INFO("hci (periodic)inq start"); #endif } break; case HCI_OP_INQUIRY_CANCEL: case HCI_OP_EXIT_PERIODIC_INQ: if (btrtl_coex.isinquirying) { btrtl_coex.isinquirying = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci (periodic)inq cancel/exit, notify wifi " "inquiry stop"); rtk_notify_btoperation_to_wifi(BT_OPCODE_INQUIRY_END, 0, NULL); #else RTKBT_INFO("hci (periodic)inq cancel/exit"); #endif } break; case HCI_OP_ACCEPT_CONN_REQ: if (!btrtl_coex.ispaging) { btrtl_coex.ispaging = 1; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci accept connreq, notify wifi page start"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAGE_START, 0, NULL); #else RTKBT_INFO("hci accept conn req"); #endif } break; case HCI_OP_DISCONNECT: RTKBT_INFO("HCI Disconnect, handle %04x, reason 0x%02x", ((u16)buffer[4] << 8 | buffer[3]), buffer[5]); break; default: break; } } static void rtk_handle_inquiry_complete(void) { if (btrtl_coex.isinquirying) { btrtl_coex.isinquirying = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("inq complete, notify wifi inquiry end"); rtk_notify_btoperation_to_wifi(BT_OPCODE_INQUIRY_END, 0, NULL); #else RTKBT_INFO("inquiry complete"); #endif } } static void rtk_handle_pin_code_req(void) { if (!btrtl_coex.ispairing) { btrtl_coex.ispairing = 1; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("pin code req, notify wifi pair start"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAIR_START, 0, NULL); #else RTKBT_INFO("pin code request"); #endif } } static void rtk_handle_io_capa_req(void) { if (!btrtl_coex.ispairing) { btrtl_coex.ispairing = 1; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("io cap req, notify wifi pair start"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAIR_START, 0, NULL); #else RTKBT_INFO("io capability request"); #endif } } static void rtk_handle_auth_request(void) { if (btrtl_coex.ispairing) { btrtl_coex.ispairing = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("auth req, notify wifi pair end"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAIR_END, 0, NULL); #else RTKBT_INFO("authentication request"); #endif } } static void rtk_handle_link_key_notify(void) { if (btrtl_coex.ispairing) { btrtl_coex.ispairing = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("link key notify, notify wifi pair end"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAIR_END, 0, NULL); #else RTKBT_INFO("link key notify"); #endif } } static void rtk_handle_mode_change_evt(u8 * p) { u16 mode_change_handle, mode_interval; p++; STREAM_TO_UINT16(mode_change_handle, p); p++; STREAM_TO_UINT16(mode_interval, p); update_hid_active_state(mode_change_handle, mode_interval); } #ifdef RTB_SOFTWARE_MAILBOX static void rtk_parse_vendor_mailbox_cmd_evt(u8 * p, u8 total_len) { u8 status, subcmd; u8 temp_cmd[10]; status = *p++; if (total_len <= 4) { RTKBT_DBG("receive mailbox cmd from fw, total length <= 4"); return; } subcmd = *p++; RTKBT_DBG("receive mailbox cmd from fw, subcmd is 0x%x, status is 0x%x", subcmd, status); switch (subcmd) { case HCI_VENDOR_SUB_CMD_BT_REPORT_CONN_SCO_INQ_INFO: if (status == 0) //success rtk_notify_info_to_wifi(POLLING_RESPONSE, RTL_BTINFO_LEN, (uint8_t *)p); break; case HCI_VENDOR_SUB_CMD_WIFI_CHANNEL_AND_BANDWIDTH_CMD: rtk_notify_btcoex_to_wifi(WIFI_BW_CHNL_NOTIFY, status); break; case HCI_VENDOR_SUB_CMD_WIFI_FORCE_TX_POWER_CMD: rtk_notify_btcoex_to_wifi(BT_POWER_DECREASE_CONTROL, status); break; case HCI_VENDOR_SUB_CMD_BT_ENABLE_IGNORE_WLAN_ACT_CMD: rtk_notify_btcoex_to_wifi(IGNORE_WLAN_ACTIVE_CONTROL, status); break; case HCI_VENDOR_SUB_CMD_SET_BT_PSD_MODE: rtk_notify_btcoex_to_wifi(BT_PSD_MODE_CONTROL, status); break; case HCI_VENDOR_SUB_CMD_SET_BT_LNA_CONSTRAINT: rtk_notify_btcoex_to_wifi(LNA_CONSTRAIN_CONTROL, status); break; case HCI_VENDOR_SUB_CMD_BT_AUTO_REPORT_ENABLE: break; case HCI_VENDOR_SUB_CMD_BT_SET_TXRETRY_REPORT_PARAM: break; case HCI_VENDOR_SUB_CMD_BT_SET_PTATABLE: break; case HCI_VENDOR_SUB_CMD_GET_AFH_MAP_L: if (status == 0) { memcpy(btrtl_coex.afh_map, p + 4, 4); /* cmd_idx, length, piconet_id, mode */ temp_cmd[0] = HCI_VENDOR_SUB_CMD_GET_AFH_MAP_M; temp_cmd[1] = 2; temp_cmd[2] = btrtl_coex.piconet_id; temp_cmd[3] = btrtl_coex.mode; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 4, temp_cmd); } else { memset(btrtl_coex.afh_map, 0, 10); rtk_notify_afhmap_to_wifi(); } break; case HCI_VENDOR_SUB_CMD_GET_AFH_MAP_M: if (status == 0) { memcpy(btrtl_coex.afh_map + 4, p + 4, 4); temp_cmd[0] = HCI_VENDOR_SUB_CMD_GET_AFH_MAP_H; temp_cmd[1] = 2; temp_cmd[2] = btrtl_coex.piconet_id; temp_cmd[3] = btrtl_coex.mode; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 4, temp_cmd); } else { memset(btrtl_coex.afh_map, 0, 10); rtk_notify_afhmap_to_wifi(); } break; case HCI_VENDOR_SUB_CMD_GET_AFH_MAP_H: if (status == 0) memcpy(btrtl_coex.afh_map + 8, p + 4, 2); else memset(btrtl_coex.afh_map, 0, 10); rtk_notify_afhmap_to_wifi(); break; case HCI_VENDOR_SUB_CMD_RD_REG_REQ: if (status == 0) rtk_notify_regester_to_wifi(p + 3); /* cmd_idx,length,regist type */ break; case HCI_VENDOR_SUB_CMD_WR_REG_REQ: rtk_notify_btcoex_to_wifi(BT_REGISTER_ACCESS, status); break; default: break; } } #endif /* RTB_SOFTWARE_MAILBOX */ static void rtk_handle_cmd_complete_evt(u8 total_len, u8 * p) { u16 opcode; p++; STREAM_TO_UINT16(opcode, p); //RTKBT_DBG("cmd_complete, opcode is 0x%x", opcode); if (opcode == HCI_OP_PERIODIC_INQ) { if (*p++ && btrtl_coex.isinquirying) { btrtl_coex.isinquirying = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci period inq, start error, notify wifi " "inquiry stop"); rtk_notify_btoperation_to_wifi(BT_OPCODE_INQUIRY_END, 0, NULL); #else RTKBT_INFO("hci period inquiry start error"); #endif } } if (opcode == HCI_OP_READ_LOCAL_VERSION) { if (!(*p++)) { p++; STREAM_TO_UINT16(btrtl_coex.hci_reversion, p); p += 3; STREAM_TO_UINT16(btrtl_coex.lmp_subversion, p); RTKBT_DBG("BTCOEX hci_rev 0x%04x", btrtl_coex.hci_reversion); RTKBT_DBG("BTCOEX lmp_subver 0x%04x", btrtl_coex.lmp_subversion); } } #ifdef RTB_SOFTWARE_MAILBOX if (opcode == HCI_VENDOR_MAILBOX_CMD) { rtk_parse_vendor_mailbox_cmd_evt(p, total_len); } #endif } static void rtk_handle_cmd_status_evt(u8 * p) { u16 opcode; u8 status; status = *p++; p++; STREAM_TO_UINT16(opcode, p); //RTKBT_DBG("cmd_status, opcode is 0x%x", opcode); if ((opcode == HCI_OP_INQUIRY) && (status)) { if (btrtl_coex.isinquirying) { btrtl_coex.isinquirying = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci inq, start error, notify wifi inq stop"); rtk_notify_btoperation_to_wifi(BT_OPCODE_INQUIRY_END, 0, NULL); #else RTKBT_INFO("hci inquiry start error"); #endif } } if (opcode == HCI_OP_CREATE_CONN) { if (!status && !btrtl_coex.ispaging) { btrtl_coex.ispaging = 1; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci create conn, notify wifi start page"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAGE_START, 0, NULL); #else RTKBT_INFO("hci create connection, start paging"); #endif } } } static void rtk_handle_connection_complete_evt(u8 * p) { u16 handle; u8 status, link_type; rtk_conn_prof *hci_conn = NULL; status = *p++; STREAM_TO_UINT16(handle, p); p += 6; link_type = *p++; RTKBT_INFO("connected, handle %04x, status 0x%02x", handle, status); if (status == 0) { if (btrtl_coex.ispaging) { btrtl_coex.ispaging = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("notify wifi page success end"); rtk_notify_btoperation_to_wifi (BT_OPCODE_PAGE_SUCCESS_END, 0, NULL); #else RTKBT_INFO("Page success"); #endif } hci_conn = find_connection_by_handle(&btrtl_coex, handle); if (hci_conn == NULL) { hci_conn = allocate_connection_by_handle(handle); if (hci_conn) { add_connection_to_hash(&btrtl_coex, hci_conn); hci_conn->profile_bitmap = 0; memset(hci_conn->profile_refcount, 0, 8); if ((0 == link_type) || (2 == link_type)) { //sco or esco hci_conn->type = 1; update_profile_connection(hci_conn, profile_sco, TRUE); } else hci_conn->type = 0; } else { RTKBT_ERR("hci connection allocate fail"); } } else { RTKBT_DBG("hci conn handle 0x%04x already existed!", handle); hci_conn->profile_bitmap = 0; memset(hci_conn->profile_refcount, 0, 8); if ((0 == link_type) || (2 == link_type)) { //sco or esco hci_conn->type = 1; update_profile_connection(hci_conn, profile_sco, TRUE); } else hci_conn->type = 0; } } else if (btrtl_coex.ispaging) { btrtl_coex.ispaging = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("notify wifi page unsuccess end"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAGE_UNSUCCESS_END, 0, NULL); #else RTKBT_INFO("Page failed"); #endif } } static void rtk_handle_le_connection_complete_evt(u8 enhanced, u8 * p) { u16 handle, interval; u8 status; rtk_conn_prof *hci_conn = NULL; status = *p++; STREAM_TO_UINT16(handle, p); if (!enhanced) p += 8; /* role, address type, address */ else p += (8 + 12); /* plus two bluetooth addresses */ STREAM_TO_UINT16(interval, p); RTKBT_INFO("LE connected, handle %04x, status 0x%02x, interval %u", handle, status, interval); if (status == 0) { if (btrtl_coex.ispaging) { btrtl_coex.ispaging = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("notify wifi page success end"); rtk_notify_btoperation_to_wifi (BT_OPCODE_PAGE_SUCCESS_END, 0, NULL); #else RTKBT_INFO("Page success end"); #endif } hci_conn = find_connection_by_handle(&btrtl_coex, handle); if (hci_conn == NULL) { hci_conn = allocate_connection_by_handle(handle); if (hci_conn) { add_connection_to_hash(&btrtl_coex, hci_conn); hci_conn->profile_bitmap = 0; memset(hci_conn->profile_refcount, 0, 8); hci_conn->type = 2; update_profile_connection(hci_conn, profile_hid, TRUE); //for coex, le is the same as hid update_hid_active_state(handle, interval); } else { RTKBT_ERR("hci connection allocate fail"); } } else { RTKBT_DBG("hci conn handle 0x%04x already existed!", handle); hci_conn->profile_bitmap = 0; memset(hci_conn->profile_refcount, 0, 8); hci_conn->type = 2; update_profile_connection(hci_conn, profile_hid, TRUE); update_hid_active_state(handle, interval); } } else if (btrtl_coex.ispaging) { btrtl_coex.ispaging = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("notify wifi page unsuccess end"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAGE_UNSUCCESS_END, 0, NULL); #else RTKBT_INFO("Page failed"); #endif } } static void rtk_handle_le_connection_update_complete_evt(u8 * p) { u16 handle, interval; /* u8 status; */ /* status = *p++; */ p++; STREAM_TO_UINT16(handle, p); STREAM_TO_UINT16(interval, p); update_hid_active_state(handle, interval); } static void rtk_handle_le_meta_evt(u8 * p) { u8 sub_event = *p++; switch (sub_event) { case HCI_EV_LE_CONN_COMPLETE: rtk_handle_le_connection_complete_evt(0, p); break; case HCI_EV_LE_ENHANCED_CONN_COMPLETE: rtk_handle_le_connection_complete_evt(1, p); break; case HCI_EV_LE_CONN_UPDATE_COMPLETE: rtk_handle_le_connection_update_complete_evt(p); break; default: break; } } static u8 disconn_profile(struct rtl_hci_conn *conn, u8 pfe_index) { u8 need_update = 0; if (!btrtl_coex.profile_refcount[pfe_index]) { RTKBT_WARN("profile %u ref is 0", pfe_index); return 0; } btrtl_coex.profile_refcount[pfe_index]--; RTKBT_INFO("%s: profile_ref[%u] %u", __func__, pfe_index, btrtl_coex.profile_refcount[pfe_index]); if (!btrtl_coex.profile_refcount[pfe_index]) { need_update = 1; btrtl_coex.profile_bitmap &= ~(BIT(pfe_index)); /* if profile does not exist, status is meaningless */ btrtl_coex.profile_status &= ~(BIT(pfe_index)); rtk_check_del_timer(pfe_index); } if (conn->profile_refcount[pfe_index]) conn->profile_refcount[pfe_index]--; else RTKBT_INFO("%s: conn pfe ref[%u] is 0", __func__, conn->profile_refcount[pfe_index]); if (!conn->profile_refcount[pfe_index]) { need_update = 1; conn->profile_bitmap &= ~(BIT(pfe_index)); /* clear profile_hid_interval if need */ if ((profile_hid == pfe_index) && (conn->profile_bitmap & (BIT(profile_hid_interval)))) { conn->profile_bitmap &= ~(BIT(profile_hid_interval)); if (btrtl_coex.profile_refcount[profile_hid_interval]) btrtl_coex.profile_refcount[profile_hid_interval]--; } } return need_update; } static void disconn_acl(u16 handle, struct rtl_hci_conn *conn) { struct rtl_coex_struct *coex = &btrtl_coex; rtk_prof_info *prof_info = NULL; struct list_head *iter = NULL, *temp = NULL; u8 need_update = 0; spin_lock(&coex->spin_lock_profile); list_for_each_safe(iter, temp, &coex->profile_list) { prof_info = list_entry(iter, rtk_prof_info, list); if (handle == prof_info->handle && prof_info->scid && prof_info->dcid) { RTKBT_DBG("hci disconn, hndl %x, psm %x, dcid %x, " "scid %x, profile %u", prof_info->handle, prof_info->psm, prof_info->dcid, prof_info->scid, prof_info->profile_index); //If both scid and dcid > 0, L2cap connection is exist. need_update |= disconn_profile(conn, prof_info->profile_index); if ((prof_info->flags & A2DP_MEDIA) && (conn->profile_bitmap & BIT(profile_sink))) need_update |= disconn_profile(conn, profile_sink); delete_profile_from_hash(prof_info); } } if (need_update) rtk_notify_profileinfo_to_fw(); spin_unlock(&coex->spin_lock_profile); } static void rtk_handle_disconnect_complete_evt(u8 * p) { u16 handle; u8 status; u8 reason; rtk_conn_prof *hci_conn = NULL; if (btrtl_coex.ispairing) { //for slave: connection will be disconnected if authentication fail btrtl_coex.ispairing = 0; #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("hci disc complete, notify wifi pair end"); rtk_notify_btoperation_to_wifi(BT_OPCODE_PAIR_END, 0, NULL); #else RTKBT_INFO("hci disconnection complete"); #endif } status = *p++; STREAM_TO_UINT16(handle, p); reason = *p; RTKBT_INFO("disconn cmpl evt: status 0x%02x, handle %04x, reason 0x%02x", status, handle, reason); if (status == 0) { RTKBT_DBG("process disconn complete event."); hci_conn = find_connection_by_handle(&btrtl_coex, handle); if (hci_conn) { switch (hci_conn->type) { case 0: /* FIXME: If this is interrupted by l2cap rx, * there may be deadlock on spin_lock_profile */ disconn_acl(handle, hci_conn); break; case 1: update_profile_connection(hci_conn, profile_sco, FALSE); break; case 2: update_profile_connection(hci_conn, profile_hid, FALSE); break; default: break; } delete_connection_from_hash(hci_conn); } else RTKBT_ERR("hci conn handle 0x%04x not found", handle); } } static void rtk_handle_specific_evt(u8 * p) { u16 subcode; STREAM_TO_UINT16(subcode, p); if (subcode == HCI_VENDOR_PTA_AUTO_REPORT_EVENT) { #ifdef RTB_SOFTWARE_MAILBOX RTKBT_DBG("notify wifi driver with autoreport data"); rtk_notify_info_to_wifi(AUTO_REPORT, RTL_BTINFO_LEN, (uint8_t *)p); #else RTKBT_INFO("auto report data"); #endif } } static void rtk_parse_event_data(struct rtl_coex_struct *coex, u8 *data, u16 len) { u8 *p = data; u8 event_code = *p++; u8 total_len = *p++; (void)coex; (void)&len; switch (event_code) { case HCI_EV_INQUIRY_COMPLETE: rtk_handle_inquiry_complete(); break; case HCI_EV_PIN_CODE_REQ: rtk_handle_pin_code_req(); break; case HCI_EV_IO_CAPA_REQUEST: rtk_handle_io_capa_req(); break; case HCI_EV_AUTH_COMPLETE: rtk_handle_auth_request(); break; case HCI_EV_LINK_KEY_NOTIFY: rtk_handle_link_key_notify(); break; case HCI_EV_MODE_CHANGE: rtk_handle_mode_change_evt(p); break; case HCI_EV_CMD_COMPLETE: rtk_handle_cmd_complete_evt(total_len, p); break; case HCI_EV_CMD_STATUS: rtk_handle_cmd_status_evt(p); break; case HCI_EV_CONN_COMPLETE: case HCI_EV_SYNC_CONN_COMPLETE: rtk_handle_connection_complete_evt(p); break; case HCI_EV_DISCONN_COMPLETE: rtk_handle_disconnect_complete_evt(p); break; case HCI_EV_LE_META: rtk_handle_le_meta_evt(p); break; case HCI_EV_VENDOR_SPECIFIC: rtk_handle_specific_evt(p); break; default: break; } } const char l2_dir_str[][4] = { "RX", "TX", }; void rtl_process_l2_sig(struct rtl_l2_buff *l2) { /* u8 flag; */ u8 code; /* u8 identifier; */ u16 handle; /* u16 total_len; */ /* u16 pdu_len, channel_id; */ /* u16 command_len; */ u16 psm, scid, dcid, result; /* u16 status; */ u8 *pp = l2->data; STREAM_TO_UINT16(handle, pp); /* flag = handle >> 12; */ handle = handle & 0x0FFF; /* STREAM_TO_UINT16(total_len, pp); */ pp += 2; /* data total length */ /* STREAM_TO_UINT16(pdu_len, pp); * STREAM_TO_UINT16(channel_id, pp); */ pp += 4; /* l2 len and channel id */ code = *pp++; switch (code) { case L2CAP_CONN_REQ: /* identifier = *pp++; */ pp++; /* STREAM_TO_UINT16(command_len, pp); */ pp += 2; STREAM_TO_UINT16(psm, pp); STREAM_TO_UINT16(scid, pp); RTKBT_DBG("%s l2cap conn req, hndl 0x%04x, PSM 0x%04x, " "scid 0x%04x", l2_dir_str[l2->out], handle, psm, scid); handle_l2cap_con_req(handle, psm, scid, l2->out); break; case L2CAP_CONN_RSP: /* identifier = *pp++; */ pp++; /* STREAM_TO_UINT16(command_len, pp); */ pp += 2; STREAM_TO_UINT16(dcid, pp); STREAM_TO_UINT16(scid, pp); STREAM_TO_UINT16(result, pp); /* STREAM_TO_UINT16(status, pp); */ pp += 2; RTKBT_DBG("%s l2cap conn rsp, hndl 0x%04x, dcid 0x%04x, " "scid 0x%04x, result 0x%04x", l2_dir_str[l2->out], handle, dcid, scid, result); handle_l2cap_con_rsp(handle, dcid, scid, l2->out, result); break; case L2CAP_DISCONN_REQ: /* identifier = *pp++; */ pp++; /* STREAM_TO_UINT16(command_len, pp); */ pp += 2; STREAM_TO_UINT16(dcid, pp); STREAM_TO_UINT16(scid, pp); RTKBT_DBG("%s l2cap disconn req, hndl 0x%04x, dcid 0x%04x, " "scid 0x%04x", l2_dir_str[l2->out], handle, dcid, scid); handle_l2cap_discon_req(handle, dcid, scid, l2->out); break; default: RTKBT_DBG("undesired l2 command %u", code); break; } } static void rtl_l2_data_process(u8 *pp, u16 len, int dir) { u8 code; u8 flag; u16 handle, pdu_len, channel_id; /* u16 total_len; */ struct rtl_l2_buff *l2 = NULL; u8 *hd = pp; /* RTKBT_DBG("l2 sig data %p, len %u, dir %d", pp, len, dir); */ STREAM_TO_UINT16(handle, pp); flag = handle >> 12; handle = handle & 0x0FFF; /* STREAM_TO_UINT16(total_len, pp); */ pp += 2; /* data total length */ STREAM_TO_UINT16(pdu_len, pp); STREAM_TO_UINT16(channel_id, pp); if (channel_id == 0x0001) { code = *pp++; switch (code) { case L2CAP_CONN_REQ: case L2CAP_CONN_RSP: case L2CAP_DISCONN_REQ: RTKBT_DBG("l2cap op %u, len %u, out %d", code, len, dir); l2 = rtl_l2_node_get(&btrtl_coex); if (l2) { u16 n; n = min_t(uint, len, L2_MAX_SUBSEC_LEN); memcpy(l2->data, hd, n); l2->out = dir; rtl_l2_node_to_used(&btrtl_coex, l2); queue_delayed_work(btrtl_coex.fw_wq, &btrtl_coex.l2_work, 0); } else RTKBT_ERR("%s: failed to get l2 node", __func__); break; case L2CAP_DISCONN_RSP: break; default: break; } } else { if ((flag != 0x01) && (is_profile_connected(profile_a2dp) || is_profile_connected(profile_pan))) /* Do not count the continuous packets */ packets_count(handle, channel_id, pdu_len, dir, pp); } return; } static void rtl_l2_work(struct work_struct *work) { struct rtl_coex_struct *coex; struct rtl_l2_buff *l2; unsigned long flags; coex = container_of(work, struct rtl_coex_struct, l2_work.work); spin_lock_irqsave(&coex->buff_lock, flags); while (!list_empty(&coex->l2_used_list)) { l2 = list_entry(coex->l2_used_list.next, struct rtl_l2_buff, list); list_del(&l2->list); spin_unlock_irqrestore(&coex->buff_lock, flags); rtl_process_l2_sig(l2); spin_lock_irqsave(&coex->buff_lock, flags); list_add_tail(&l2->list, &coex->l2_free_list); } spin_unlock_irqrestore(&coex->buff_lock, flags); return; } static void rtl_ev_work(struct work_struct *work) { struct rtl_coex_struct *coex; struct rtl_hci_ev *ev; unsigned long flags; coex = container_of(work, struct rtl_coex_struct, fw_work.work); spin_lock_irqsave(&coex->buff_lock, flags); while (!list_empty(&coex->ev_used_list)) { ev = list_entry(coex->ev_used_list.next, struct rtl_hci_ev, list); list_del(&ev->list); spin_unlock_irqrestore(&coex->buff_lock, flags); rtk_parse_event_data(coex, ev->data, ev->len); spin_lock_irqsave(&coex->buff_lock, flags); list_add_tail(&ev->list, &coex->ev_free_list); } spin_unlock_irqrestore(&coex->buff_lock, flags); } int ev_filter_out(u8 *buf) { switch (buf[0]) { case HCI_EV_INQUIRY_COMPLETE: case HCI_EV_PIN_CODE_REQ: case HCI_EV_IO_CAPA_REQUEST: case HCI_EV_AUTH_COMPLETE: case HCI_EV_LINK_KEY_NOTIFY: case HCI_EV_MODE_CHANGE: case HCI_EV_CMD_COMPLETE: case HCI_EV_CMD_STATUS: case HCI_EV_CONN_COMPLETE: case HCI_EV_SYNC_CONN_COMPLETE: case HCI_EV_DISCONN_COMPLETE: case HCI_EV_VENDOR_SPECIFIC: return 0; case HCI_EV_LE_META: /* Ignore frequent but not useful events that result in * costing too much space. */ switch (buf[2]) { case HCI_EV_LE_CONN_COMPLETE: case HCI_EV_LE_ENHANCED_CONN_COMPLETE: case HCI_EV_LE_CONN_UPDATE_COMPLETE: return 0; } return 1; default: return 1; } } static void rtk_btcoex_evt_enqueue(__u8 *s, __u16 count) { struct rtl_hci_ev *ev; if (ev_filter_out(s)) return; ev = rtl_ev_node_get(&btrtl_coex); if (!ev) { RTKBT_ERR("%s: no free ev node.", __func__); return; } if (count > MAX_LEN_OF_HCI_EV) { memcpy(ev->data, s, MAX_LEN_OF_HCI_EV); ev->len = MAX_LEN_OF_HCI_EV; } else { memcpy(ev->data, s, count); ev->len = count; } rtl_ev_node_to_used(&btrtl_coex, ev); queue_delayed_work(btrtl_coex.fw_wq, &btrtl_coex.fw_work, 0); } /* Context: in_interrupt() */ void rtk_btcoex_parse_event(uint8_t *buffer, int count) { struct rtl_coex_struct *coex = &btrtl_coex; __u8 *tbuff; __u16 elen = 0; /* RTKBT_DBG("%s: parse ev.", __func__); */ if (!test_bit(RTL_COEX_RUNNING, &btrtl_coex.flags)) { /* RTKBT_INFO("%s: Coex is closed, ignore", __func__); */ RTKBT_INFO("%s: Coex is closed, ignore %x, %x", __func__, buffer[0], buffer[1]); return; } spin_lock(&coex->rxlock); /* coex->tbuff will be set to NULL when initializing or * there is a complete frame or there is start of a frame */ tbuff = coex->tbuff; while (count) { int len; /* Start of a frame */ if (!tbuff) { tbuff = coex->back_buff; coex->tbuff = NULL; coex->elen = 0; coex->pkt_type = HCI_EVENT_PKT; coex->expect = HCI_EVENT_HDR_SIZE; } len = min_t(uint, coex->expect, count); memcpy(tbuff, buffer, len); tbuff += len; coex->elen += len; count -= len; buffer += len; coex->expect -= len; if (coex->elen == HCI_EVENT_HDR_SIZE) { /* Complete event header */ coex->expect = ((struct hci_event_hdr *)coex->back_buff)->plen; if (coex->expect > HCI_MAX_EVENT_SIZE - coex->elen) { tbuff = NULL; coex->elen = 0; RTKBT_ERR("tbuff room is not enough"); break; } } if (coex->expect == 0) { /* Complete frame */ elen = coex->elen; spin_unlock(&coex->rxlock); rtk_btcoex_evt_enqueue(coex->back_buff, elen); spin_lock(&coex->rxlock); tbuff = NULL; coex->elen = 0; } } /* coex->tbuff would be non-NULL if there isn't a complete frame * And it will be updated next time */ coex->tbuff = tbuff; spin_unlock(&coex->rxlock); } void rtk_btcoex_parse_l2cap_data_tx(uint8_t *buffer, int count) { if (!test_bit(RTL_COEX_RUNNING, &btrtl_coex.flags)) { RTKBT_INFO("%s: Coex is closed, ignore", __func__); return; } rtl_l2_data_process(buffer, count, 1); //u16 handle, total_len, pdu_len, channel_ID, command_len, psm, scid, // dcid, result, status; //u8 flag, code, identifier; //u8 *pp = (u8 *) (skb->data); //STREAM_TO_UINT16(handle, pp); //flag = handle >> 12; //handle = handle & 0x0FFF; //STREAM_TO_UINT16(total_len, pp); //STREAM_TO_UINT16(pdu_len, pp); //STREAM_TO_UINT16(channel_ID, pp); //if (channel_ID == 0x0001) { // code = *pp++; // switch (code) { // case L2CAP_CONN_REQ: // identifier = *pp++; // STREAM_TO_UINT16(command_len, pp); // STREAM_TO_UINT16(psm, pp); // STREAM_TO_UINT16(scid, pp); // RTKBT_DBG("TX l2cap conn req, hndl %x, PSM %x, scid=%x", // handle, psm, scid); // handle_l2cap_con_req(handle, psm, scid, 1); // break; // case L2CAP_CONN_RSP: // identifier = *pp++; // STREAM_TO_UINT16(command_len, pp); // STREAM_TO_UINT16(dcid, pp); // STREAM_TO_UINT16(scid, pp); // STREAM_TO_UINT16(result, pp); // STREAM_TO_UINT16(status, pp); // RTKBT_DBG("TX l2cap conn rsp, hndl %x, dcid %x, " // "scid %x, result %x", // handle, dcid, scid, result); // handle_l2cap_con_rsp(handle, dcid, scid, 1, result); // break; // case L2CAP_DISCONN_REQ: // identifier = *pp++; // STREAM_TO_UINT16(command_len, pp); // STREAM_TO_UINT16(dcid, pp); // STREAM_TO_UINT16(scid, pp); // RTKBT_DBG("TX l2cap disconn req, hndl %x, dcid %x, " // "scid %x", handle, dcid, scid); // handle_l2cap_discon_req(handle, dcid, scid, 1); // break; // case L2CAP_DISCONN_RSP: // break; // default: // break; // } //} else { // if ((flag != 0x01) && (is_profile_connected(profile_a2dp) || is_profile_connected(profile_pan))) //Do not count the continuous packets // packets_count(handle, channel_ID, pdu_len, 1, pp); //} } void rtk_btcoex_parse_l2cap_data_rx(uint8_t *buffer, int count) { if (!test_bit(RTL_COEX_RUNNING, &btrtl_coex.flags)) { RTKBT_INFO("%s: Coex is closed, ignore", __func__); return; } rtl_l2_data_process(buffer, count, 0); //u16 handle, total_len, pdu_len, channel_ID, command_len, psm, scid, // dcid, result, status; //u8 flag, code, identifier; //u8 *pp = urb->transfer_buffer; //STREAM_TO_UINT16(handle, pp); //flag = handle >> 12; //handle = handle & 0x0FFF; //STREAM_TO_UINT16(total_len, pp); //STREAM_TO_UINT16(pdu_len, pp); //STREAM_TO_UINT16(channel_ID, pp); //if (channel_ID == 0x0001) { // code = *pp++; // switch (code) { // case L2CAP_CONN_REQ: // identifier = *pp++; // STREAM_TO_UINT16(command_len, pp); // STREAM_TO_UINT16(psm, pp); // STREAM_TO_UINT16(scid, pp); // RTKBT_DBG("RX l2cap conn req, hndl %x, PSM %x, scid %x", // handle, psm, scid); // handle_l2cap_con_req(handle, psm, scid, 0); // break; // case L2CAP_CONN_RSP: // identifier = *pp++; // STREAM_TO_UINT16(command_len, pp); // STREAM_TO_UINT16(dcid, pp); // STREAM_TO_UINT16(scid, pp); // STREAM_TO_UINT16(result, pp); // STREAM_TO_UINT16(status, pp); // RTKBT_DBG("RX l2cap conn rsp, hndl %x, dcid %x, " // "scid %x, result %x", // handle, dcid, scid, result); // handle_l2cap_con_rsp(handle, dcid, scid, 0, result); // break; // case L2CAP_DISCONN_REQ: // identifier = *pp++; // STREAM_TO_UINT16(command_len, pp); // STREAM_TO_UINT16(dcid, pp); // STREAM_TO_UINT16(scid, pp); // RTKBT_DBG("RX l2cap disconn req, hndl %x, dcid %x, " // "scid %x", handle, dcid, scid); // handle_l2cap_discon_req(handle, dcid, scid, 0); // break; // case L2CAP_DISCONN_RSP: // break; // default: // break; // } //} else { // if ((flag != 0x01) && (is_profile_connected(profile_a2dp) || is_profile_connected(profile_pan))) //Do not count the continuous packets // packets_count(handle, channel_ID, pdu_len, 0, pp); //} } #ifdef RTB_SOFTWARE_MAILBOX #if LINUX_VERSION_CODE > KERNEL_VERSION(4, 14, 0) static void polling_bt_info(struct timer_list *unused) #else static void polling_bt_info(unsigned long data) #endif { uint8_t temp_cmd[1]; RTKBT_DBG("polling timer"); if (btrtl_coex.polling_enable) { //temp_cmd[0] = HCI_VENDOR_SUB_CMD_BT_REPORT_CONN_SCO_INQ_INFO; temp_cmd[0] = HCI_VENDOR_SUB_CMD_BT_AUTO_REPORT_STATUS_INFO; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 1, temp_cmd); } mod_timer(&btrtl_coex.polling_timer, jiffies + msecs_to_jiffies(1000 * btrtl_coex.polling_interval)); } static void rtk_handle_bt_info_control(uint8_t *p) { uint8_t temp_cmd[20]; struct rtl_btinfo_ctl *ctl = (struct rtl_btinfo_ctl*)p; RTKBT_DBG("Received polling_enable %u, polling_time %u, " "autoreport_enable %u", ctl->polling_enable, ctl->polling_time, ctl->autoreport_enable); RTKBT_DBG("coex: original polling_enable %u", btrtl_coex.polling_enable); if (ctl->polling_enable && !btrtl_coex.polling_enable) { /* setup polling timer for getting bt info from firmware */ btrtl_coex.polling_timer.expires = jiffies + msecs_to_jiffies(ctl->polling_time * 1000); mod_timer(&btrtl_coex.polling_timer, btrtl_coex.polling_timer.expires); } /* Close bt info polling timer */ if (!ctl->polling_enable && btrtl_coex.polling_enable) del_timer(&btrtl_coex.polling_timer); if (btrtl_coex.autoreport != ctl->autoreport_enable) { temp_cmd[0] = HCI_VENDOR_SUB_CMD_BT_AUTO_REPORT_ENABLE; temp_cmd[1] = 1; temp_cmd[2] = ctl->autoreport_enable; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 3, temp_cmd); } btrtl_coex.polling_enable = ctl->polling_enable; btrtl_coex.polling_interval = ctl->polling_time; btrtl_coex.autoreport = ctl->autoreport_enable; rtk_notify_info_to_wifi(HOST_RESPONSE, 0, NULL); } static void rtk_handle_bt_coex_control(uint8_t * p) { uint8_t temp_cmd[20]; uint8_t opcode, opcode_len, value, power_decrease, psd_mode, access_type; opcode = *p++; RTKBT_DBG("receive bt coex control event from wifi, op 0x%02x", opcode); switch (opcode) { case BT_PATCH_VERSION_QUERY: rtk_notify_btpatch_version_to_wifi(); break; case IGNORE_WLAN_ACTIVE_CONTROL: opcode_len = *p++; value = *p++; temp_cmd[0] = HCI_VENDOR_SUB_CMD_BT_ENABLE_IGNORE_WLAN_ACT_CMD; temp_cmd[1] = 1; temp_cmd[2] = value; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 3, temp_cmd); break; case LNA_CONSTRAIN_CONTROL: opcode_len = *p++; value = *p++; temp_cmd[0] = HCI_VENDOR_SUB_CMD_SET_BT_LNA_CONSTRAINT; temp_cmd[1] = 1; temp_cmd[2] = value; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 3, temp_cmd); break; case BT_POWER_DECREASE_CONTROL: opcode_len = *p++; power_decrease = *p++; temp_cmd[0] = HCI_VENDOR_SUB_CMD_WIFI_FORCE_TX_POWER_CMD; temp_cmd[1] = 1; temp_cmd[2] = power_decrease; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 3, temp_cmd); break; case BT_PSD_MODE_CONTROL: opcode_len = *p++; psd_mode = *p++; temp_cmd[0] = HCI_VENDOR_SUB_CMD_SET_BT_PSD_MODE; temp_cmd[1] = 1; temp_cmd[2] = psd_mode; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 3, temp_cmd); break; case WIFI_BW_CHNL_NOTIFY: opcode_len = *p++; temp_cmd[0] = HCI_VENDOR_SUB_CMD_WIFI_CHANNEL_AND_BANDWIDTH_CMD; temp_cmd[1] = 3; memcpy(temp_cmd + 2, p, 3); //wifi_state, wifi_centralchannel, chnnels_btnotuse rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 5, temp_cmd); break; case QUERY_BT_AFH_MAP: opcode_len = *p++; btrtl_coex.piconet_id = *p++; btrtl_coex.mode = *p++; temp_cmd[0] = HCI_VENDOR_SUB_CMD_GET_AFH_MAP_L; temp_cmd[1] = 2; temp_cmd[2] = btrtl_coex.piconet_id; temp_cmd[3] = btrtl_coex.mode; rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 4, temp_cmd); break; case BT_REGISTER_ACCESS: opcode_len = *p++; access_type = *p++; if (access_type == 0) { //read temp_cmd[0] = HCI_VENDOR_SUB_CMD_RD_REG_REQ; temp_cmd[1] = 5; temp_cmd[2] = *p++; memcpy(temp_cmd + 3, p, 4); rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 7, temp_cmd); } else { //write temp_cmd[0] = HCI_VENDOR_SUB_CMD_RD_REG_REQ; temp_cmd[1] = 5; temp_cmd[2] = *p++; memcpy(temp_cmd + 3, p, 8); rtk_vendor_cmd_to_fw(HCI_VENDOR_MAILBOX_CMD, 11, temp_cmd); } break; default: break; } } static void rtk_handle_event_from_wifi(uint8_t * msg) { uint8_t *p = msg; uint8_t event_code = *p++; uint8_t total_length; uint8_t extension_event; uint8_t operation; uint16_t wifi_opcode; uint8_t op_status; if (memcmp(msg, invite_rsp, sizeof(invite_rsp)) == 0) { RTKBT_DBG("receive invite rsp from wifi, wifi is already on"); btrtl_coex.wifi_on = 1; rtk_notify_extension_version_to_wifi(); } if (memcmp(msg, attend_req, sizeof(attend_req)) == 0) { RTKBT_DBG("receive attend req from wifi, wifi turn on"); btrtl_coex.wifi_on = 1; rtkbt_coexmsg_send(attend_ack, sizeof(attend_ack)); rtk_notify_extension_version_to_wifi(); } if (memcmp(msg, wifi_leave, sizeof(wifi_leave)) == 0) { RTKBT_DBG("receive wifi leave from wifi, wifi turn off"); btrtl_coex.wifi_on = 0; rtkbt_coexmsg_send(leave_ack, sizeof(leave_ack)); if (btrtl_coex.polling_enable) { btrtl_coex.polling_enable = 0; del_timer(&btrtl_coex.polling_timer); } } if (memcmp(msg, leave_ack, sizeof(leave_ack)) == 0) { RTKBT_DBG("receive leave ack from wifi"); } if (event_code == 0xFE) { total_length = *p++; extension_event = *p++; switch (extension_event) { case RTK_HS_EXTENSION_EVENT_WIFI_SCAN: operation = *p; RTKBT_DBG("Recv WiFi scan notify event from WiFi, " "op 0x%02x", operation); break; case RTK_HS_EXTENSION_EVENT_HCI_BT_INFO_CONTROL: rtk_handle_bt_info_control(p); break; case RTK_HS_EXTENSION_EVENT_HCI_BT_COEX_CONTROL: rtk_handle_bt_coex_control(p); break; default: break; } } if (event_code == 0x0E) { p += 2; //length, number of complete packets STREAM_TO_UINT16(wifi_opcode, p); op_status = *p; RTKBT_DBG("Recv cmd complete event from WiFi, op 0x%02x, " "status 0x%02x", wifi_opcode, op_status); } } #endif /* RTB_SOFTWARE_MAILBOX */ static inline void rtl_free_frags(struct rtl_coex_struct *coex) { unsigned long flags; spin_lock_irqsave(&coex->rxlock, flags); coex->elen = 0; coex->tbuff = NULL; spin_unlock_irqrestore(&coex->rxlock, flags); } void rtk_btcoex_open(struct hci_dev *hdev) { if (test_and_set_bit(RTL_COEX_RUNNING, &btrtl_coex.flags)) { RTKBT_WARN("RTL COEX is already running."); return; } RTKBT_INFO("Open BTCOEX"); /* Just for test */ //struct rtl_btinfo_ctl ctl; INIT_DELAYED_WORK(&btrtl_coex.fw_work, (void *)rtl_ev_work); #ifdef RTB_SOFTWARE_MAILBOX #ifdef RTK_COEX_OVER_SYMBOL INIT_WORK(&rtw_work, rtw_work_func); skb_queue_head_init(&rtw_q); rtw_coex_on = 1; #else INIT_DELAYED_WORK(&btrtl_coex.sock_work, (void *)udpsocket_recv_data); #endif #endif /* RTB_SOFTWARE_MAILBOX */ INIT_DELAYED_WORK(&btrtl_coex.l2_work, (void *)rtl_l2_work); #if LINUX_VERSION_CODE > KERNEL_VERSION(4, 14, 0) #ifdef RTB_SOFTWARE_MAILBOX timer_setup(&btrtl_coex.polling_timer, polling_bt_info, 0); #endif timer_setup(&btrtl_coex.a2dp_count_timer, count_a2dp_packet_timeout, 0); timer_setup(&btrtl_coex.pan_count_timer, count_pan_packet_timeout, 0); timer_setup(&btrtl_coex.hogp_count_timer, count_hogp_packet_timeout, 0); #else #ifdef RTB_SOFTWARE_MAILBOX setup_timer(&btrtl_coex.polling_timer, polling_bt_info, 0); #endif setup_timer(&btrtl_coex.a2dp_count_timer, count_a2dp_packet_timeout, 0); setup_timer(&btrtl_coex.pan_count_timer, count_pan_packet_timeout, 0); setup_timer(&btrtl_coex.hogp_count_timer, count_hogp_packet_timeout, 0); #endif btrtl_coex.hdev = hdev; #ifdef RTB_SOFTWARE_MAILBOX btrtl_coex.wifi_on = 0; #endif init_profile_hash(&btrtl_coex); init_connection_hash(&btrtl_coex); btrtl_coex.pkt_type = 0; btrtl_coex.expect = 0; btrtl_coex.elen = 0; btrtl_coex.tbuff = NULL; #ifdef RTB_SOFTWARE_MAILBOX #ifndef RTK_COEX_OVER_SYMBOL create_udpsocket(); #endif rtkbt_coexmsg_send(invite_req, sizeof(invite_req)); #endif /* Just for test */ //ctl.polling_enable = 1; //ctl.polling_time = 1; //ctl.autoreport_enable = 1; //rtk_handle_bt_info_control((u8 *)&ctl); } void rtk_btcoex_close(void) { int kk = 0; if (!test_and_clear_bit(RTL_COEX_RUNNING, &btrtl_coex.flags)) { RTKBT_WARN("RTL COEX is already closed."); return; } RTKBT_INFO("Close BTCOEX"); #ifdef RTB_SOFTWARE_MAILBOX /* Close coex socket */ if (btrtl_coex.wifi_on) rtkbt_coexmsg_send(bt_leave, sizeof(bt_leave)); #ifdef RTK_COEX_OVER_SYMBOL rtw_coex_on = 0; skb_queue_purge(&rtw_q); cancel_work_sync(&rtw_work); #else cancel_delayed_work_sync(&btrtl_coex.sock_work); if (btrtl_coex.sock_open) { btrtl_coex.sock_open = 0; RTKBT_DBG("release udp socket"); sock_release(btrtl_coex.udpsock); } #endif /* Delete all timers */ if (btrtl_coex.polling_enable) { btrtl_coex.polling_enable = 0; del_timer_sync(&(btrtl_coex.polling_timer)); } #endif /* RTB_SOFTWARE_MAILBOX */ del_timer_sync(&btrtl_coex.a2dp_count_timer); del_timer_sync(&btrtl_coex.pan_count_timer); del_timer_sync(&btrtl_coex.hogp_count_timer); cancel_delayed_work_sync(&btrtl_coex.fw_work); cancel_delayed_work_sync(&btrtl_coex.l2_work); flush_connection_hash(&btrtl_coex); flush_profile_hash(&btrtl_coex); btrtl_coex.profile_bitmap = 0; btrtl_coex.profile_status = 0; for (kk = 0; kk < 8; kk++) btrtl_coex.profile_refcount[kk] = 0; rtl_free_frags(&btrtl_coex); RTKBT_DBG("-x"); } void rtk_btcoex_probe(struct hci_dev *hdev) { btrtl_coex.hdev = hdev; spin_lock_init(&btrtl_coex.spin_lock_sock); spin_lock_init(&btrtl_coex.spin_lock_profile); } void rtk_btcoex_init(void) { RTKBT_DBG("%s: version: %s", __func__, RTK_VERSION); RTKBT_DBG("create workqueue"); #ifdef RTB_SOFTWARE_MAILBOX #ifdef RTK_COEX_OVER_SYMBOL RTKBT_INFO("Coex over Symbol"); rtw_wq = create_workqueue("btcoexwork"); skb_queue_head_init(&rtw_q); #else RTKBT_INFO("Coex over UDP"); btrtl_coex.sock_wq = create_workqueue("btudpwork"); #endif #endif /* RTB_SOFTWARE_MAILBOX */ btrtl_coex.fw_wq = create_workqueue("btfwwork"); rtl_alloc_buff(&btrtl_coex); spin_lock_init(&btrtl_coex.rxlock); } void rtk_btcoex_exit(void) { RTKBT_DBG("%s: destroy workqueue", __func__); #ifdef RTB_SOFTWARE_MAILBOX #ifdef RTK_COEX_OVER_SYMBOL flush_workqueue(rtw_wq); destroy_workqueue(rtw_wq); #else flush_workqueue(btrtl_coex.sock_wq); destroy_workqueue(btrtl_coex.sock_wq); #endif #endif flush_workqueue(btrtl_coex.fw_wq); destroy_workqueue(btrtl_coex.fw_wq); rtl_free_buff(&btrtl_coex); }