pinebuds/rtos/rtx/TARGET_CORTEX_M/rt_System.c
Ben V. Brown 75381150fd Formatting
Formatting Pass 1

Lots of fixups to adding stdint and stdbool all over the place

Formatting Pass 2
Formatting Pass 3
Formatting Pass 4

Update app_bt_stream.cpp
2023-02-02 07:56:49 +11:00

447 lines
12 KiB
C

/*----------------------------------------------------------------------------
* RL-ARM - RTX
*----------------------------------------------------------------------------
* Name: RT_SYSTEM.C
* Purpose: System Task Manager
* Rev.: V4.60
*----------------------------------------------------------------------------
*
* Copyright (c) 1999-2009 KEIL, 2009-2012 ARM Germany GmbH
* All rights reserved.
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* - Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* - Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* - Neither the name of ARM nor the names of its contributors may be used
* to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDERS AND CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*---------------------------------------------------------------------------*/
#include "rt_System.h"
#include "RTX_Conf.h"
#include "rt_Event.h"
#include "rt_HAL_CM.h"
#include "rt_List.h"
#include "rt_Mailbox.h"
#include "rt_Robin.h"
#include "rt_Semaphore.h"
#include "rt_Task.h"
#include "rt_Time.h"
#include "rt_TypeDef.h"
#include "hal_sleep.h"
#include "hal_timer.h"
#include "hal_trace.h"
extern void sysTimerTick(void);
extern uint32_t rt_timer_delay_count(void);
/*----------------------------------------------------------------------------
* Global Variables
*---------------------------------------------------------------------------*/
int os_tick_irqn;
/*----------------------------------------------------------------------------
* Local Variables
*---------------------------------------------------------------------------*/
static volatile BIT os_lock;
static volatile BIT os_psh_flag;
static U8 pend_flags;
static U32 systick_lock_tick;
static U32 systick_lock_ts;
/*----------------------------------------------------------------------------
* Global Functions
*---------------------------------------------------------------------------*/
#if defined(__CC_ARM)
__asm void $$RTX$$version(void) {
/* Export a version number symbol for a version control. */
EXPORT __RL_RTX_VER
__RL_RTX_VER EQU 0x450
}
#endif
/*--------------------------- rt_suspend ------------------------------------*/
U32 rt_suspend(void) {
/* Suspend OS scheduler */
U32 delta = 0xFFFF;
U32 start_tick;
__disable_irq();
start_tick = NVIC_ST_CURRENT;
rt_tsk_lock();
systick_lock_tick = NVIC_ST_CURRENT;
systick_lock_ts = hal_sys_timer_get();
if (start_tick != 0 &&
(systick_lock_tick == 0 || start_tick < systick_lock_tick)) {
#if defined(DEBUG_SLEEP) && (DEBUG_SLEEP >= 1)
TRACE(6, "[%u/0x%X][%2u/%u] rt_suspend corner case: %02u -> %02u",
TICKS_TO_MS(hal_sys_timer_get()), hal_sys_timer_get(),
NVIC_ST_CURRENT, os_time, start_tick, systick_lock_tick);
#endif
pend_flags |= 1;
}
if (pend_flags) {
delta = 0;
}
__enable_irq();
if (delta == 0) {
return 0;
}
if (os_dly.p_dlnk) {
delta = os_dly.delta_time;
}
#ifdef __CMSIS_RTOS
{
uint32_t tcnt = rt_timer_delay_count();
if (tcnt && tcnt < delta) {
delta = tcnt;
}
}
#else
if (os_tmr.next) {
if (os_tmr.tcnt < delta)
delta = os_tmr.tcnt;
}
#endif
return (delta);
}
/*--------------------------- rt_resume -------------------------------------*/
void rt_resume(U32 sleep_time) {
/* Resume OS scheduler after suspend */
// P_TCB next;
U32 delta;
U32 resume_ts;
U32 unlock_ts;
U32 systick_remain;
U32 sleep_ticks;
U8 tick_running = 0;
const U32 reload = (NVIC_ST_RELOAD + 1);
__disable_irq();
resume_ts = hal_sys_timer_get();
__enable_irq();
sleep_ticks = (resume_ts - systick_lock_ts) *
(OS_CLOCK_NOMINAL / CONFIG_SYSTICK_HZ_NOMINAL);
if (systick_lock_tick == 0) {
sleep_time = sleep_ticks / reload;
systick_remain = reload - sleep_ticks % reload;
} else if (sleep_ticks >= systick_lock_tick) {
delta = sleep_ticks - systick_lock_tick;
sleep_time = delta / reload + 1;
systick_remain = reload - delta % reload;
} else {
sleep_time = 0;
systick_remain = systick_lock_tick - sleep_ticks;
}
if (sleep_time == 0) {
tick_running = 1;
goto _task_unlock;
}
// Task switching is allowed in SVC/PENDSV/SYSTICK handlers only
#if 0
os_tsk.run->state = READY;
rt_put_rdy_first (os_tsk.run);
#endif
_inc_sleep_time:
os_robin.task = NULL;
if (sleep_time) {
/* Update delays. */
if (os_dly.p_dlnk) {
delta = sleep_time;
if (delta >= os_dly.delta_time) {
delta -= os_dly.delta_time;
os_time += os_dly.delta_time;
os_dly.delta_time = 1;
while (os_dly.p_dlnk) {
rt_dec_dly();
if (delta == 0)
break;
delta--;
os_time++;
}
while (delta) {
delta--;
os_time++;
}
rt_psh_req();
} else {
os_time += delta;
os_dly.delta_time -= delta;
}
} else {
os_time += sleep_time;
}
os_idle_TCB.rtime += sleep_time;
#ifdef __CMSIS_RTOS
delta = sleep_time;
while (delta && rt_timer_delay_count()) {
sysTimerTick();
delta--;
}
#else
/* Check the user timers. */
if (os_tmr.next) {
delta = sleep_time;
if (delta >= os_tmr.tcnt) {
delta -= os_tmr.tcnt;
os_tmr.tcnt = 1;
while (os_tmr.next) {
rt_tmr_tick();
if (delta == 0)
break;
delta--;
}
} else {
os_tmr.tcnt -= delta;
}
}
#endif
} // sleep_time
// Task switching is allowed in SVC/PENDSV/SYSTICK handlers only
#if 0
/* Switch back to highest ready task */
next = rt_get_first (&os_rdy);
rt_switch_req (next);
#endif
#if defined(DEBUG_SLEEP) && (DEBUG_SLEEP >= 1)
if (sleep_time > 0) {
TRACE(7,
"[%u/0x%X][%2u/%u] rt_resume: sleep_ticks=%u sleep_time=%u "
"systick_remain=%u",
TICKS_TO_MS(hal_sys_timer_get()), hal_sys_timer_get(),
NVIC_ST_CURRENT, os_time, sleep_ticks, sleep_time, systick_remain);
}
#endif
_task_unlock:
sleep_time = 0;
__disable_irq();
// Handle corner case: systick counter wraps inside rt_resume()
unlock_ts = hal_sys_timer_get();
sleep_ticks = (unlock_ts - resume_ts) * 2;
// systick_remain value range: [1, reload]
if (sleep_ticks >= systick_remain) {
#if defined(DEBUG_SLEEP) && (DEBUG_SLEEP >= 1)
TRACE(6,
"[%u/0x%X][%2u/%u] rt_resume corner case: sleep_ticks=%u "
"systick_remain=%u",
TICKS_TO_MS(hal_sys_timer_get()), hal_sys_timer_get(),
NVIC_ST_CURRENT, os_time, sleep_ticks, systick_remain);
// Update timestamp since traces also consume time
unlock_ts = hal_sys_timer_get();
sleep_ticks = (unlock_ts - resume_ts) *
(OS_CLOCK_NOMINAL / CONFIG_SYSTICK_HZ_NOMINAL);
#endif
delta = sleep_ticks - systick_remain;
sleep_time = delta / reload + 1;
systick_remain = reload - delta % reload;
resume_ts = unlock_ts;
} else {
if (tick_running == 0) {
systick_remain -= sleep_ticks;
// Adjust systick_remain value range to [0, reload - 1]
if (systick_remain == reload) {
systick_remain = 0;
}
if (systick_remain) {
NVIC_ST_RELOAD = systick_remain;
NVIC_ST_CURRENT = 0;
while (NVIC_ST_CURRENT == 0)
;
NVIC_ST_RELOAD = reload - 1;
} else {
NVIC_ST_CURRENT = 0;
}
}
rt_tsk_unlock();
}
__enable_irq();
if (sleep_time) {
goto _inc_sleep_time;
}
}
/*--------------------------- rt_tsk_lock -----------------------------------*/
void rt_tsk_lock(void) {
/* Prevent task switching by locking out scheduler */
if (os_tick_irqn < 0) {
OS_LOCK();
os_lock = __TRUE;
OS_UNPEND(&pend_flags);
} else {
OS_X_LOCK(os_tick_irqn);
os_lock = __TRUE;
OS_X_UNPEND(&pend_flags);
}
}
/*--------------------------- rt_tsk_unlock ---------------------------------*/
void rt_tsk_unlock(void) {
/* Unlock scheduler and re-enable task switching */
if (os_tick_irqn < 0) {
OS_UNLOCK();
os_lock = __FALSE;
OS_PEND(pend_flags, os_psh_flag);
os_psh_flag = __FALSE;
} else {
OS_X_UNLOCK(os_tick_irqn);
os_lock = __FALSE;
OS_X_PEND(pend_flags, os_psh_flag);
os_psh_flag = __FALSE;
}
// Allow cpu sleep
hal_cpu_wake_unlock(HAL_CPU_WAKE_LOCK_USER_RTOS);
}
/*--------------------------- rt_psh_req ------------------------------------*/
void rt_psh_req(void) {
/* Initiate a post service handling request if required. */
if (os_lock == __FALSE) {
OS_PEND_IRQ();
} else {
os_psh_flag = __TRUE;
// Prohibit cpu sleep when an OS service request is enqueued during os lock
// (rt_suspend)
hal_cpu_wake_lock(HAL_CPU_WAKE_LOCK_USER_RTOS);
}
}
/*--------------------------- rt_pop_req ------------------------------------*/
void rt_pop_req(void) {
/* Process an ISR post service requests. */
struct OS_XCB *p_CB;
P_TCB next;
U32 idx;
os_tsk.run->state = READY;
if (os_tsk.run == &os_idle_TCB) {
rt_put_rdy_last(os_tsk.run);
} else {
rt_put_rdy_first(os_tsk.run);
}
idx = os_psq->last;
while (os_psq->count) {
p_CB = os_psq->q[idx].id;
if (p_CB->cb_type == TCB) {
/* Is of TCB type */
rt_evt_psh((P_TCB)p_CB, (U16)os_psq->q[idx].arg);
} else if (p_CB->cb_type == MCB) {
/* Is of MCB type */
rt_mbx_psh((P_MCB)p_CB, (void *)os_psq->q[idx].arg);
} else {
/* Must be of SCB type */
rt_sem_psh((P_SCB)p_CB);
}
if (++idx == os_psq->size)
idx = 0;
rt_dec(&os_psq->count);
}
os_psq->last = idx;
next = rt_get_first(&os_rdy);
rt_switch_req(next);
}
/*--------------------------- os_tick_init ----------------------------------*/
__weak int os_tick_init(void) {
/* Initialize SysTick timer as system tick timer. */
rt_systick_init();
return (-1); /* Return IRQ number of SysTick timer */
}
/*--------------------------- os_tick_irqack --------------------------------*/
__weak void os_tick_irqack(void) { /* Acknowledge timer interrupt. */
}
/*--------------------------- rt_systick ------------------------------------*/
void rt_systick(void) {
/* Check for system clock update, suspend running task. */
P_TCB next;
#if __RTX_CPU_STATISTICS__
os_tsk.run->rtime += 1;
#endif
os_tsk.run->state = READY;
rt_put_rdy_first(os_tsk.run);
/* Check Round Robin timeout. */
rt_chk_robin();
/* Update delays. */
os_time++;
rt_dec_dly();
/* Check the user timers. */
#ifdef __CMSIS_RTOS
sysTimerTick();
#else
rt_tmr_tick();
#endif
/* Switch back to highest ready task */
next = rt_get_first(&os_rdy);
rt_switch_req(next);
}
/*--------------------------- rt_stk_check ----------------------------------*/
__weak void rt_stk_check(void) {
/* Check for stack overflow. */
if (os_tsk.run->task_id == 0x01) {
// TODO: For the main thread the check should be done against the main heap
// pointer
} else {
if ((os_tsk.run->tsk_stack < (U32)os_tsk.run->stack) ||
(os_tsk.run->stack[0] != MAGIC_WORD)) {
os_error(OS_ERR_STK_OVF);
}
}
}
/*----------------------------------------------------------------------------
* end of file
*---------------------------------------------------------------------------*/