blob: e58f4cb3b4da127ec1b026faaa7f942d2e2b1e9e [file] [log] [blame]
/******************************************************************************
*
* Copyright (C) 1999-2012 Broadcom Corporation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
******************************************************************************/
/******************************************************************************
*
* This file contains the main Bluetooth Upper Layer processing loop.
* The Broadcom implementations of L2CAP RFCOMM, SDP and the BTIf run as one
* GKI task. This btu_task switches between them.
*
* Note that there will always be an L2CAP, but there may or may not be an
* RFCOMM or SDP. Whether these layers are present or not is determined by
* compile switches.
*
******************************************************************************/
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include "bt_target.h"
#include "gki.h"
#include "bt_types.h"
#include "hcimsgs.h"
#include "l2c_int.h"
#include "btu.h"
#include "bt_utils.h"
#include "sdpint.h"
#if ( defined(RFCOMM_INCLUDED) && RFCOMM_INCLUDED == TRUE )
#include "port_api.h"
#include "port_ext.h"
#endif
#include "btm_api.h"
#include "btm_int.h"
#if (defined(EVAL) && EVAL == TRUE)
#include "btu_eval.h"
#endif
#if GAP_INCLUDED == TRUE
#include "gap_int.h"
#endif
#if (defined(OBX_INCLUDED) && OBX_INCLUDED == TRUE)
#include "obx_int.h"
#if (defined(BIP_INCLUDED) && BIP_INCLUDED == TRUE)
#include "bip_int.h"
#endif /* BIP */
#if (BPP_SND_INCLUDED == TRUE || BPP_INCLUDED == TRUE)
#include "bpp_int.h"
#endif /* BPP */
#endif /* OBX */
#include "bt_trace.h"
/* BTE application task */
#if APPL_INCLUDED == TRUE
#include "bte_appl.h"
#endif
#if (defined(RPC_INCLUDED) && RPC_INCLUDED == TRUE)
#include "rpct_main.h"
#endif
#if (defined(BNEP_INCLUDED) && BNEP_INCLUDED == TRUE)
#include "bnep_int.h"
#endif
#if (defined(PAN_INCLUDED) && PAN_INCLUDED == TRUE)
#include "pan_int.h"
#endif
#if (defined(SAP_SERVER_INCLUDED) && SAP_SERVER_INCLUDED == TRUE)
#include "sap_int.h"
#endif
#if (defined(HID_DEV_INCLUDED) && HID_DEV_INCLUDED == TRUE )
#include "hidd_int.h"
#endif
#if (defined(HID_HOST_INCLUDED) && HID_HOST_INCLUDED == TRUE )
#include "hidh_int.h"
#endif
#if (defined(AVDT_INCLUDED) && AVDT_INCLUDED == TRUE)
#include "avdt_int.h"
#else
extern void avdt_rcv_sync_info (BT_HDR *p_buf); /* this is for hci_test */
#endif
#if (defined(MCA_INCLUDED) && MCA_INCLUDED == TRUE)
#include "mca_api.h"
#include "mca_defs.h"
#include "mca_int.h"
#endif
#if (defined(BTU_BTA_INCLUDED) && BTU_BTA_INCLUDED == TRUE)
#include "bta_sys.h"
#endif
#if (BLE_INCLUDED == TRUE)
#include "gatt_int.h"
#if (SMP_INCLUDED == TRUE)
#include "smp_int.h"
#endif
#include "btm_ble_int.h"
#endif
#ifdef __cplusplus
extern "C"
{
#endif
BT_API extern void BTE_InitStack(void);
#ifdef __cplusplus
}
#endif
/* Define BTU storage area
*/
#if BTU_DYNAMIC_MEMORY == FALSE
tBTU_CB btu_cb;
#endif
/* Define a function prototype to allow a generic timeout handler */
typedef void (tUSER_TIMEOUT_FUNC) (TIMER_LIST_ENT *p_tle);
/*******************************************************************************
**
** Function btu_task
**
** Description This is the main task of the Bluetooth Upper Layers unit.
** It sits in a loop waiting for messages, and dispatches them
** to the appropiate handlers.
**
** Returns should never return
**
*******************************************************************************/
BTU_API UINT32 btu_task (UINT32 param)
{
UINT16 event;
BT_HDR *p_msg;
UINT8 i;
UINT16 mask;
BOOLEAN handled;
UNUSED(param);
#if (defined(HCISU_H4_INCLUDED) && HCISU_H4_INCLUDED == TRUE)
/* wait an event that HCISU is ready */
BT_TRACE(TRACE_LAYER_BTU, TRACE_TYPE_API,
"btu_task pending for preload complete event");
for (;;)
{
event = GKI_wait (0xFFFF, 0);
if (event & EVENT_MASK(GKI_SHUTDOWN_EVT))
{
/* indicates BT ENABLE abort */
BT_TRACE(TRACE_LAYER_BTU, TRACE_TYPE_WARNING,
"btu_task start abort!");
return (0);
}
else if (event & BT_EVT_PRELOAD_CMPL)
{
break;
}
else
{
BT_TRACE(TRACE_LAYER_BTU, TRACE_TYPE_WARNING,
"btu_task ignore evt %04x while pending for preload complete",
event);
}
}
BT_TRACE(TRACE_LAYER_BTU, TRACE_TYPE_API,
"btu_task received preload complete event");
#endif
/* Initialize the mandatory core stack control blocks
(BTU, BTM, L2CAP, and SDP)
*/
btu_init_core();
/* Initialize any optional stack components */
BTE_InitStack();
#if (defined(BTU_BTA_INCLUDED) && BTU_BTA_INCLUDED == TRUE)
bta_sys_init();
#endif
/* Initialise platform trace levels at this point as BTE_InitStack() and bta_sys_init()
* reset the control blocks and preset the trace level with XXX_INITIAL_TRACE_LEVEL
*/
#if ( BT_USE_TRACES==TRUE )
BTE_InitTraceLevels();
#endif
/* Send a startup evt message to BTIF_TASK to kickstart the init procedure */
GKI_send_event(BTIF_TASK, BT_EVT_TRIGGER_STACK_INIT);
raise_priority_a2dp(TASK_HIGH_BTU);
/* Wait for, and process, events */
for (;;)
{
event = GKI_wait (0xFFFF, 0);
if (event & TASK_MBOX_0_EVT_MASK)
{
/* Process all messages in the queue */
while ((p_msg = (BT_HDR *) GKI_read_mbox (BTU_HCI_RCV_MBOX)) != NULL)
{
/* Determine the input message type. */
switch (p_msg->event & BT_EVT_MASK)
{
case BT_EVT_TO_BTU_HCI_ACL:
/* All Acl Data goes to L2CAP */
l2c_rcv_acl_data (p_msg);
break;
case BT_EVT_TO_BTU_L2C_SEG_XMIT:
/* L2CAP segment transmit complete */
l2c_link_segments_xmitted (p_msg);
break;
case BT_EVT_TO_BTU_HCI_SCO:
#if BTM_SCO_INCLUDED == TRUE
btm_route_sco_data (p_msg);
break;
#endif
case BT_EVT_TO_BTU_HCI_EVT:
btu_hcif_process_event ((UINT8)(p_msg->event & BT_SUB_EVT_MASK), p_msg);
GKI_freebuf(p_msg);
#if (defined(HCILP_INCLUDED) && HCILP_INCLUDED == TRUE)
/* If host receives events which it doesn't response to, */
/* host should start idle timer to enter sleep mode. */
btu_check_bt_sleep ();
#endif
break;
case BT_EVT_TO_BTU_HCI_CMD:
btu_hcif_send_cmd ((UINT8)(p_msg->event & BT_SUB_EVT_MASK), p_msg);
break;
#if (defined(OBX_INCLUDED) && OBX_INCLUDED == TRUE)
#if (defined(OBX_SERVER_INCLUDED) && OBX_SERVER_INCLUDED == TRUE)
case BT_EVT_TO_OBX_SR_MSG:
obx_sr_proc_evt((tOBX_PORT_EVT *)(p_msg + 1));
GKI_freebuf (p_msg);
break;
case BT_EVT_TO_OBX_SR_L2C_MSG:
obx_sr_proc_l2c_evt((tOBX_L2C_EVT_MSG *)(p_msg + 1));
GKI_freebuf (p_msg);
break;
#endif
#if (defined(OBX_CLIENT_INCLUDED) && OBX_CLIENT_INCLUDED == TRUE)
case BT_EVT_TO_OBX_CL_MSG:
obx_cl_proc_evt((tOBX_PORT_EVT *)(p_msg + 1));
GKI_freebuf (p_msg);
break;
case BT_EVT_TO_OBX_CL_L2C_MSG:
obx_cl_proc_l2c_evt((tOBX_L2C_EVT_MSG *)(p_msg + 1));
GKI_freebuf (p_msg);
break;
#endif
#if (defined(BIP_INCLUDED) && BIP_INCLUDED == TRUE)
case BT_EVT_TO_BIP_CMDS :
bip_proc_btu_event(p_msg);
GKI_freebuf (p_msg);
break;
#endif /* BIP */
#if (BPP_SND_INCLUDED == TRUE || BPP_INCLUDED == TRUE)
case BT_EVT_TO_BPP_PR_CMDS:
bpp_pr_proc_event(p_msg);
GKI_freebuf (p_msg);
break;
case BT_EVT_TO_BPP_SND_CMDS:
bpp_snd_proc_event(p_msg);
GKI_freebuf (p_msg);
break;
#endif /* BPP */
#endif /* OBX */
#if (defined(SAP_SERVER_INCLUDED) && SAP_SERVER_INCLUDED == TRUE)
case BT_EVT_TO_BTU_SAP :
sap_proc_btu_event(p_msg);
GKI_freebuf (p_msg);
break;
#endif /* SAP */
#if (defined(GAP_CONN_INCLUDED) && GAP_CONN_INCLUDED == TRUE && GAP_CONN_POST_EVT_INCLUDED == TRUE)
case BT_EVT_TO_GAP_MSG :
gap_proc_btu_event(p_msg);
GKI_freebuf (p_msg);
break;
#endif
case BT_EVT_TO_START_TIMER :
/* Start free running 1 second timer for list management */
GKI_start_timer (TIMER_0, GKI_SECS_TO_TICKS (1), TRUE);
GKI_freebuf (p_msg);
break;
case BT_EVT_TO_STOP_TIMER:
if (GKI_timer_queue_is_empty(&btu_cb.timer_queue)) {
GKI_stop_timer(TIMER_0);
}
GKI_freebuf (p_msg);
break;
case BT_EVT_TO_START_TIMER_ONESHOT:
if (!GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
TIMER_LIST_ENT *tle = GKI_timer_getfirst(&btu_cb.timer_queue_oneshot);
// Start non-repeating timer.
GKI_start_timer(TIMER_3, tle->ticks, FALSE);
} else {
BTM_TRACE_WARNING("Oneshot timer queue empty when received start request");
}
GKI_freebuf(p_msg);
break;
case BT_EVT_TO_STOP_TIMER_ONESHOT:
if (GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
GKI_stop_timer(TIMER_3);
} else {
BTM_TRACE_WARNING("Oneshot timer queue not empty when received stop request");
}
GKI_freebuf (p_msg);
break;
#if defined(QUICK_TIMER_TICKS_PER_SEC) && (QUICK_TIMER_TICKS_PER_SEC > 0)
case BT_EVT_TO_START_QUICK_TIMER :
GKI_start_timer (TIMER_2, QUICK_TIMER_TICKS, TRUE);
GKI_freebuf (p_msg);
break;
#endif
default:
i = 0;
mask = (UINT16) (p_msg->event & BT_EVT_MASK);
handled = FALSE;
for (; !handled && i < BTU_MAX_REG_EVENT; i++)
{
if (btu_cb.event_reg[i].event_cb == NULL)
continue;
if (mask == btu_cb.event_reg[i].event_range)
{
if (btu_cb.event_reg[i].event_cb)
{
btu_cb.event_reg[i].event_cb(p_msg);
handled = TRUE;
}
}
}
if (handled == FALSE)
GKI_freebuf (p_msg);
break;
}
}
}
if (event & TIMER_0_EVT_MASK) {
GKI_update_timer_list (&btu_cb.timer_queue, 1);
while (!GKI_timer_queue_is_empty(&btu_cb.timer_queue)) {
TIMER_LIST_ENT *p_tle = GKI_timer_getfirst(&btu_cb.timer_queue);
if (p_tle->ticks != 0)
break;
GKI_remove_from_timer_list(&btu_cb.timer_queue, p_tle);
switch (p_tle->event) {
case BTU_TTYPE_BTM_DEV_CTL:
btm_dev_timeout(p_tle);
break;
case BTU_TTYPE_BTM_ACL:
btm_acl_timeout(p_tle);
break;
case BTU_TTYPE_L2CAP_LINK:
case BTU_TTYPE_L2CAP_CHNL:
case BTU_TTYPE_L2CAP_HOLD:
case BTU_TTYPE_L2CAP_INFO:
case BTU_TTYPE_L2CAP_FCR_ACK:
#if (BLE_INCLUDED == TRUE)
case BTU_TTYPE_L2CAP_END_CONN_UPD:
#endif
l2c_process_timeout (p_tle);
break;
case BTU_TTYPE_SDP:
sdp_conn_timeout ((tCONN_CB *)p_tle->param);
break;
case BTU_TTYPE_BTM_RMT_NAME:
btm_inq_rmt_name_failed();
break;
#if (defined(RFCOMM_INCLUDED) && RFCOMM_INCLUDED == TRUE)
case BTU_TTYPE_RFCOMM_MFC:
case BTU_TTYPE_RFCOMM_PORT:
rfcomm_process_timeout (p_tle);
break;
#endif /* If defined(RFCOMM_INCLUDED) && RFCOMM_INCLUDED == TRUE */
#if ((defined(BNEP_INCLUDED) && BNEP_INCLUDED == TRUE))
case BTU_TTYPE_BNEP:
bnep_process_timeout(p_tle);
break;
#endif
#if (defined(AVDT_INCLUDED) && AVDT_INCLUDED == TRUE)
case BTU_TTYPE_AVDT_CCB_RET:
case BTU_TTYPE_AVDT_CCB_RSP:
case BTU_TTYPE_AVDT_CCB_IDLE:
case BTU_TTYPE_AVDT_SCB_TC:
avdt_process_timeout(p_tle);
break;
#endif
#if (defined(OBX_INCLUDED) && OBX_INCLUDED == TRUE)
#if (defined(OBX_CLIENT_INCLUDED) && OBX_CLIENT_INCLUDED == TRUE)
case BTU_TTYPE_OBX_CLIENT_TO:
obx_cl_timeout(p_tle);
break;
#endif
#if (defined(OBX_SERVER_INCLUDED) && OBX_SERVER_INCLUDED == TRUE)
case BTU_TTYPE_OBX_SERVER_TO:
obx_sr_timeout(p_tle);
break;
case BTU_TTYPE_OBX_SVR_SESS_TO:
obx_sr_sess_timeout(p_tle);
break;
#endif
#endif
#if (defined(SAP_SERVER_INCLUDED) && SAP_SERVER_INCLUDED == TRUE)
case BTU_TTYPE_SAP_TO:
sap_process_timeout(p_tle);
break;
#endif
case BTU_TTYPE_BTU_CMD_CMPL:
btu_hcif_cmd_timeout((UINT8)(p_tle->event - BTU_TTYPE_BTU_CMD_CMPL));
break;
#if (defined(HID_HOST_INCLUDED) && HID_HOST_INCLUDED == TRUE)
case BTU_TTYPE_HID_HOST_REPAGE_TO :
hidh_proc_repage_timeout(p_tle);
break;
#endif
#if (defined(BLE_INCLUDED) && BLE_INCLUDED == TRUE)
case BTU_TTYPE_BLE_INQUIRY:
case BTU_TTYPE_BLE_GAP_LIM_DISC:
case BTU_TTYPE_BLE_GAP_FAST_ADV:
case BTU_TTYPE_BLE_OBSERVE:
btm_ble_timeout(p_tle);
break;
case BTU_TTYPE_ATT_WAIT_FOR_RSP:
gatt_rsp_timeout(p_tle);
break;
case BTU_TTYPE_ATT_WAIT_FOR_IND_ACK:
gatt_ind_ack_timeout(p_tle);
break;
#if (defined(SMP_INCLUDED) && SMP_INCLUDED == TRUE)
case BTU_TTYPE_SMP_PAIRING_CMD:
smp_rsp_timeout(p_tle);
break;
#endif
#endif
#if (MCA_INCLUDED == TRUE)
case BTU_TTYPE_MCA_CCB_RSP:
mca_process_timeout(p_tle);
break;
#endif
case BTU_TTYPE_USER_FUNC:
{
tUSER_TIMEOUT_FUNC *p_uf = (tUSER_TIMEOUT_FUNC *)p_tle->param;
(*p_uf)(p_tle);
}
break;
default:
i = 0;
handled = FALSE;
for (; !handled && i < BTU_MAX_REG_TIMER; i++)
{
if (btu_cb.timer_reg[i].timer_cb == NULL)
continue;
if (btu_cb.timer_reg[i].p_tle == p_tle)
{
btu_cb.timer_reg[i].timer_cb(p_tle);
handled = TRUE;
}
}
break;
}
}
/* if timer list is empty stop periodic GKI timer */
if (btu_cb.timer_queue.p_first == NULL)
{
GKI_stop_timer(TIMER_0);
}
}
#if defined(QUICK_TIMER_TICKS_PER_SEC) && (QUICK_TIMER_TICKS_PER_SEC > 0)
if (event & TIMER_2_EVT_MASK)
{
btu_process_quick_timer_evt();
}
#endif
#if (RPC_INCLUDED == TRUE)
/* if RPC message queue event */
if (event & RPCGEN_MSG_EVT)
{
if ((p_msg = (BT_HDR *) GKI_read_mbox(RPCGEN_MSG_MBOX)) != NULL)
RPCT_RpcgenMsg(p_msg); /* handle RPC message queue */
}
#endif
#if (defined(BTU_BTA_INCLUDED) && BTU_BTA_INCLUDED == TRUE)
if (event & TASK_MBOX_2_EVT_MASK)
{
while ((p_msg = (BT_HDR *) GKI_read_mbox(TASK_MBOX_2)) != NULL)
{
bta_sys_event(p_msg);
}
}
if (event & TIMER_1_EVT_MASK)
{
bta_sys_timer_update();
}
#endif
if (event & TIMER_3_EVT_MASK) {
BTM_TRACE_API("Received oneshot timer event complete");
if (!GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
TIMER_LIST_ENT *p_tle = GKI_timer_getfirst(&btu_cb.timer_queue_oneshot);
INT32 ticks_since_last_update = GKI_timer_ticks_getinitial(GKI_timer_getfirst(&btu_cb.timer_queue_oneshot));
GKI_update_timer_list(&btu_cb.timer_queue_oneshot, ticks_since_last_update);
}
while (!GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
TIMER_LIST_ENT *p_tle = GKI_timer_getfirst(&btu_cb.timer_queue_oneshot);
if (p_tle->ticks != 0)
break;
GKI_remove_from_timer_list(&btu_cb.timer_queue_oneshot, p_tle);
switch (p_tle->event) {
case BTU_TTYPE_BLE_RANDOM_ADDR:
btm_ble_timeout(p_tle);
break;
default:
// FAIL
BTM_TRACE_WARNING("Received unexpected oneshot timer event:0x%x\n",
p_tle->event);
break;
}
}
/* Update GKI timer with new tick value from first timer. */
if (!GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
TIMER_LIST_ENT *p_tle = GKI_timer_getfirst(&btu_cb.timer_queue_oneshot);
if (p_tle->ticks > 0)
GKI_start_timer(TIMER_3, p_tle->ticks, FALSE);
} else {
GKI_stop_timer(TIMER_3);
}
}
if (event & EVENT_MASK(APPL_EVT_7))
break;
}
return(0);
}
/*******************************************************************************
**
** Function btu_start_timer
**
** Description Start a timer for the specified amount of time.
** NOTE: The timeout resolution is in SECONDS! (Even
** though the timer structure field is ticks)
**
** Returns void
**
*******************************************************************************/
void btu_start_timer (TIMER_LIST_ENT *p_tle, UINT16 type, UINT32 timeout)
{
BT_HDR *p_msg;
GKI_disable();
/* if timer list is currently empty, start periodic GKI timer */
if (btu_cb.timer_queue.p_first == NULL)
{
/* if timer starts on other than BTU task */
if (GKI_get_taskid() != BTU_TASK)
{
/* post event to start timer in BTU task */
if ((p_msg = (BT_HDR *)GKI_getbuf(BT_HDR_SIZE)) != NULL)
{
p_msg->event = BT_EVT_TO_START_TIMER;
GKI_send_msg (BTU_TASK, TASK_MBOX_0, p_msg);
}
}
else
{
/* Start free running 1 second timer for list management */
GKI_start_timer (TIMER_0, GKI_SECS_TO_TICKS (1), TRUE);
}
}
GKI_remove_from_timer_list (&btu_cb.timer_queue, p_tle);
p_tle->event = type;
p_tle->ticks = timeout;
p_tle->ticks_initial = timeout;
GKI_add_to_timer_list (&btu_cb.timer_queue, p_tle);
GKI_enable();
}
/*******************************************************************************
**
** Function btu_remaining_time
**
** Description Return amount of time to expire
**
** Returns time in second
**
*******************************************************************************/
UINT32 btu_remaining_time (TIMER_LIST_ENT *p_tle)
{
return(GKI_get_remaining_ticks (&btu_cb.timer_queue, p_tle));
}
/*******************************************************************************
**
** Function btu_stop_timer
**
** Description Stop a timer.
**
** Returns void
**
*******************************************************************************/
void btu_stop_timer (TIMER_LIST_ENT *p_tle)
{
BT_HDR *p_msg;
GKI_disable();
GKI_remove_from_timer_list (&btu_cb.timer_queue, p_tle);
/* if timer is stopped on other than BTU task */
if (GKI_get_taskid() != BTU_TASK)
{
/* post event to stop timer in BTU task */
if ((p_msg = (BT_HDR *)GKI_getbuf(BT_HDR_SIZE)) != NULL)
{
p_msg->event = BT_EVT_TO_STOP_TIMER;
GKI_send_msg (BTU_TASK, TASK_MBOX_0, p_msg);
}
}
else
{
/* if timer list is empty stop periodic GKI timer */
if (btu_cb.timer_queue.p_first == NULL)
{
GKI_stop_timer(TIMER_0);
}
}
GKI_enable();
}
#if defined(QUICK_TIMER_TICKS_PER_SEC) && (QUICK_TIMER_TICKS_PER_SEC > 0)
/*******************************************************************************
**
** Function btu_start_quick_timer
**
** Description Start a timer for the specified amount of time.
** NOTE: The timeout resolution depends on including modules.
** QUICK_TIMER_TICKS_PER_SEC should be used to convert from
** time to ticks.
**
**
** Returns void
**
*******************************************************************************/
void btu_start_quick_timer (TIMER_LIST_ENT *p_tle, UINT16 type, UINT32 timeout)
{
BT_HDR *p_msg;
GKI_disable();
/* if timer list is currently empty, start periodic GKI timer */
if (btu_cb.quick_timer_queue.p_first == NULL)
{
/* script test calls stack API without posting event */
if (GKI_get_taskid() != BTU_TASK)
{
/* post event to start timer in BTU task */
if ((p_msg = (BT_HDR *)GKI_getbuf(BT_HDR_SIZE)) != NULL)
{
p_msg->event = BT_EVT_TO_START_QUICK_TIMER;
GKI_send_msg (BTU_TASK, TASK_MBOX_0, p_msg);
}
}
else
GKI_start_timer(TIMER_2, QUICK_TIMER_TICKS, TRUE);
}
GKI_remove_from_timer_list (&btu_cb.quick_timer_queue, p_tle);
p_tle->event = type;
p_tle->ticks = timeout;
p_tle->ticks_initial = timeout;
GKI_add_to_timer_list (&btu_cb.quick_timer_queue, p_tle);
GKI_enable();
}
/*******************************************************************************
**
** Function btu_stop_quick_timer
**
** Description Stop a timer.
**
** Returns void
**
*******************************************************************************/
void btu_stop_quick_timer (TIMER_LIST_ENT *p_tle)
{
GKI_disable();
GKI_remove_from_timer_list (&btu_cb.quick_timer_queue, p_tle);
/* if timer list is empty stop periodic GKI timer */
if (btu_cb.quick_timer_queue.p_first == NULL)
{
GKI_stop_timer(TIMER_2);
}
GKI_enable();
}
/*******************************************************************************
**
** Function btu_process_quick_timer_evt
**
** Description Process quick timer event
**
** Returns void
**
*******************************************************************************/
void btu_process_quick_timer_evt(void)
{
process_quick_timer_evt(&btu_cb.quick_timer_queue);
/* if timer list is empty stop periodic GKI timer */
if (btu_cb.quick_timer_queue.p_first == NULL)
{
GKI_stop_timer(TIMER_2);
}
}
/*******************************************************************************
**
** Function process_quick_timer_evt
**
** Description Process quick timer event
**
** Returns void
**
*******************************************************************************/
void process_quick_timer_evt(TIMER_LIST_Q *p_tlq)
{
TIMER_LIST_ENT *p_tle;
GKI_update_timer_list (p_tlq, 1);
while ((p_tlq->p_first) && (!p_tlq->p_first->ticks))
{
p_tle = p_tlq->p_first;
GKI_remove_from_timer_list (p_tlq, p_tle);
switch (p_tle->event)
{
case BTU_TTYPE_L2CAP_CHNL: /* monitor or retransmission timer */
case BTU_TTYPE_L2CAP_FCR_ACK: /* ack timer */
l2c_process_timeout (p_tle);
break;
default:
break;
}
}
}
#endif /* defined(QUICK_TIMER_TICKS_PER_SEC) && (QUICK_TIMER_TICKS_PER_SEC > 0) */
/*
* Starts a oneshot timer with a timeout in seconds.
*/
void btu_start_timer_oneshot(TIMER_LIST_ENT *p_tle, UINT16 type, UINT32 timeout_in_secs) {
INT32 timeout_in_ticks = GKI_SECS_TO_TICKS(timeout_in_secs);
BTM_TRACE_DEBUG("Starting oneshot timer type:%d timeout:%ds", type, timeout_in_secs);
GKI_disable();
if (GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
/* RPC to BTU thread if timer start request from non-BTU task */
if (GKI_get_taskid() != BTU_TASK) {
/* post event to start timer in BTU task */
BTM_TRACE_WARNING("Posting oneshot timer event to btu_task");
BT_HDR *p_msg = (BT_HDR *)GKI_getbuf(BT_HDR_SIZE);
if (p_msg != NULL) {
p_msg->event = BT_EVT_TO_START_TIMER_ONESHOT;
GKI_send_msg (BTU_TASK, TASK_MBOX_0, p_msg);
}
} else {
GKI_start_timer(TIMER_3, timeout_in_ticks, FALSE);
}
}
GKI_remove_from_timer_list(&btu_cb.timer_queue_oneshot, p_tle);
p_tle->event = type;
p_tle->ticks = timeout_in_ticks;
p_tle->ticks_initial = timeout_in_ticks;
GKI_add_to_timer_list(&btu_cb.timer_queue_oneshot, p_tle);
GKI_enable();
}
void btu_stop_timer_oneshot(TIMER_LIST_ENT *p_tle) {
GKI_disable();
GKI_remove_from_timer_list(&btu_cb.timer_queue_oneshot, p_tle);
if (GKI_get_taskid() != BTU_TASK) {
/* post event to stop timer in BTU task */
BT_HDR *p_msg = (BT_HDR *)GKI_getbuf(BT_HDR_SIZE);
if (p_msg != NULL) {
p_msg->event = BT_EVT_TO_STOP_TIMER_ONESHOT;
GKI_send_msg (BTU_TASK, TASK_MBOX_0, p_msg);
}
} else {
if (GKI_timer_queue_is_empty(&btu_cb.timer_queue_oneshot)) {
BTM_TRACE_WARNING("Stopping oneshot timer");
GKI_stop_timer(TIMER_3);
} else {
BTM_TRACE_WARNING("Request to stop oneshot timer with non empty queue");
}
}
GKI_enable();
}
#if (defined(HCILP_INCLUDED) && HCILP_INCLUDED == TRUE)
/*******************************************************************************
**
** Function btu_check_bt_sleep
**
** Description This function is called to check if controller can go to sleep.
**
** Returns void
**
*******************************************************************************/
void btu_check_bt_sleep (void)
{
if ((btu_cb.hci_cmd_cb[LOCAL_BR_EDR_CONTROLLER_ID].cmd_cmpl_q.count == 0)
&&(btu_cb.hci_cmd_cb[LOCAL_BR_EDR_CONTROLLER_ID].cmd_xmit_q.count == 0))
{
if (l2cb.controller_xmit_window == l2cb.num_lm_acl_bufs)
{
/* enable dev to sleep in the cmd cplt and cmd status only and num cplt packet */
HCI_LP_ALLOW_BT_DEVICE_SLEEP();
}
}
}
#endif