rt-thread/bsp/nuvoton/libraries/nuc980/rtt_port/drv_sys.c

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/**************************************************************************//**
*
* @copyright (C) 2020 Nuvoton Technology Corp. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2020-11-11 Wayne First version
*
******************************************************************************/
#include <rthw.h>
#include <rtthread.h>
#include "NuMicro.h"
#include "drv_sys.h"
#define SYS_MIN_INT_SOURCE 1
#define SYS_MAX_INT_SOURCE 63
#define SYS_NUM_OF_AICREG 16
#define INT_IRQ 0x00
#define INT_FIQ 0x01
extern rt_uint32_t rt_interrupt_nest;
rt_uint32_t rt_interrupt_from_thread, rt_interrupt_to_thread;
rt_uint32_t rt_thread_switch_interrupt_flag;
struct rt_irq_desc irq_desc[SYS_MAX_INT_SOURCE + 1];
void rt_hw_interrupt_dummy_handler(int vector, void *param)
{
rt_kprintf("Unhandled interrupt %d occurred!!!\n", vector);
RT_ASSERT(0);
}
rt_uint32_t rt_hw_interrupt_get_active(rt_uint32_t fiq_irq)
{
rt_uint32_t active = 0;
#if 0
rt_uint32_t volatile _mIPER, _mISNR;
_mIPER = (inpw(REG_AIC_IPER) >> 2) & 0x3f;
_mISNR = inpw(REG_AIC_ISNR);
if ((_mISNR != 0) && (_mIPER == _mISNR))
active = _mISNR;
#else
if (fiq_irq != INT_FIQ)
{
active = inpw(REG_AIC_IRQNUM);
}
else
active = inpw(REG_AIC_FIQNUM);
#endif
return active;
}
void rt_hw_interrupt_set_priority(int vector, int IntTypeLevel)
{
rt_uint32_t _mRegAddr;
rt_uint32_t shift;
if ((vector > SYS_MAX_INT_SOURCE) || (vector < SYS_MIN_INT_SOURCE))
return;
_mRegAddr = REG_AIC_SRCCTL0 + ((vector / 4) * 4);
shift = (vector % 4) * 8;
IntTypeLevel &= 0x7;
outpw(_mRegAddr, (inpw(_mRegAddr) & ~(0x07 << shift)) | (IntTypeLevel << shift));
}
void rt_hw_interrupt_ack(rt_uint32_t fiq_irq, rt_uint32_t id)
{
if (fiq_irq != INT_FIQ)
outpw(REG_AIC_EOIS, 1);
else
outpw(REG_AIC_EOFS, 1);
}
void rt_interrupt_dispatch(rt_uint32_t fiq_irq)
{
rt_isr_handler_t isr_func;
rt_uint32_t irq;
void *param;
/* get irq number */
irq = rt_hw_interrupt_get_active(fiq_irq);
/* get interrupt service routine */
isr_func = irq_desc[irq].handler;
param = irq_desc[irq].param;
/* turn to interrupt service routine */
isr_func(irq, param);
rt_hw_interrupt_ack(fiq_irq, irq);
#ifdef RT_USING_INTERRUPT_INFO
irq_desc[irq].counter ++;
#endif
}
void rt_hw_interrupt_init(void)
{
int i;
*((volatile unsigned int *)REG_AIC_INTDIS0) = 0xFFFFFFFF; // disable all interrupt channel
*((volatile unsigned int *)REG_AIC_INTDIS1) = 0xFFFFFFFF; // disable all interrupt channel
/* init interrupt nest, and context in thread sp */
rt_interrupt_nest = 0;
rt_interrupt_from_thread = 0;
rt_interrupt_to_thread = 0;
rt_thread_switch_interrupt_flag = 0;
for (i = 1; i <= SYS_MAX_INT_SOURCE; i++)
{
rt_hw_interrupt_install(i, rt_hw_interrupt_dummy_handler, RT_NULL, (char *)"dummy");
rt_hw_interrupt_mask(i);
}
}
rt_isr_handler_t rt_hw_interrupt_install(int vector, rt_isr_handler_t handler, void *param, const char *name)
{
rt_isr_handler_t old_handler = RT_NULL;
if (vector > SYS_MAX_INT_SOURCE)
return RT_NULL;
/* Set default priority IRQ_LEVEL_7 */
rt_hw_interrupt_set_priority(vector, IRQ_LEVEL_7);
old_handler = irq_desc[vector].handler;
if (handler != RT_NULL)
{
irq_desc[vector].handler = (rt_isr_handler_t)handler;
irq_desc[vector].param = param;
#ifdef RT_USING_INTERRUPT_INFO
rt_snprintf(irq_desc[vector].name, RT_NAME_MAX - 1, "%s", name);
irq_desc[vector].counter = 0;
#endif
}
return old_handler;
}
/* Disable interrupt */
void rt_hw_interrupt_mask(int vector)
{
sysDisableInterrupt((IRQn_Type)vector);
}
void rt_hw_interrupt_umask(int vector)
{
sysEnableInterrupt((IRQn_Type)vector);
}
/* TYPE
* #define LOW_LEVEL_SENSITIVE 0x00
* #define HIGH_LEVEL_SENSITIVE 0x40
* #define NEGATIVE_EDGE_TRIGGER 0x80
* #define POSITIVE_EDGE_TRIGGER 0xC0
*/
void rt_hw_interrupt_set_type(int vector, int type)
{
rt_uint32_t _mRegAddr;
rt_uint32_t shift;
if ((vector > SYS_MAX_INT_SOURCE) || (vector < SYS_MIN_INT_SOURCE))
return ;
_mRegAddr = REG_AIC_SRCCTL0 + ((vector / 4) * 4);
shift = (vector % 4) * 8;
type &= 0xC0;
outpw(_mRegAddr, (inpw(_mRegAddr) & ~(0xC0 << shift)) | (type << shift));
}
void rt_low_level_init(void)
{
}
void nu_clock_base_init(void)
{
nu_sys_ipclk_enable(CPUCKEN);
nu_sys_ipclk_enable(HCLKCKEN);
nu_sys_ipclk_enable(HCLK1CKEN);
nu_sys_ipclk_enable(HCLK3CKEN);
nu_sys_ipclk_enable(HCLK4CKEN);
nu_sys_ipclk_enable(PCLK0CKEN);
nu_sys_ipclk_enable(PCLK1CKEN);
nu_sys_ipclk_enable(SRAMCKEN);
nu_sys_ipclk_enable(SDICCKEN);
nu_sys_ipclk_enable(PCLK2CKEN);
nu_sys_ipclk_enable(PCLKEN0_Reserved_3);
}
void machine_reset(void)
{
rt_kprintf("machine_reset...\n");
rt_hw_interrupt_disable();
/* Unlock */
SYS_UnlockReg();
nu_sys_ip_reset(CHIPRST);
while (1);
}
void machine_shutdown(void)
{
rt_kprintf("machine_shutdown...\n");
rt_hw_interrupt_disable();
/* Unlock */
SYS_UnlockReg();
while (1);
}
void nu_sys_ip_reset(E_SYS_IPRST eIPRstIdx)
{
uint32_t u32IPRSTRegAddr;
uint32_t u32IPRSTRegBit;
rt_uint32_t level;
if (eIPRstIdx >= SYS_IPRST_CNT)
return;
u32IPRSTRegAddr = REG_SYS_AHBIPRST + (4ul * (eIPRstIdx / 32));
u32IPRSTRegBit = eIPRstIdx % 32;
/* Enter critical section */
level = rt_hw_interrupt_disable();
/* Enable IP reset */
outpw(u32IPRSTRegAddr, inpw(u32IPRSTRegAddr) | (1 << u32IPRSTRegBit));
/* Disable IP reset */
outpw(u32IPRSTRegAddr, inpw(u32IPRSTRegAddr) & ~(1 << u32IPRSTRegBit));
/* Leave critical section */
rt_hw_interrupt_enable(level);
}
static void _nu_sys_ipclk(E_SYS_IPCLK eIPClkIdx, uint32_t bEnable)
{
uint32_t u32IPCLKRegAddr;
uint32_t u32IPCLKRegBit;
rt_uint32_t level;
if (eIPClkIdx >= SYS_IPCLK_CNT)
return;
u32IPCLKRegAddr = REG_CLK_HCLKEN + (4ul * (eIPClkIdx / 32));
u32IPCLKRegBit = eIPClkIdx % 32;
/* Enter critical section */
level = rt_hw_interrupt_disable();
if (bEnable)
{
/* Enable IP CLK */
outpw(u32IPCLKRegAddr, inpw(u32IPCLKRegAddr) | (1 << u32IPCLKRegBit));
}
else
{
/* Disable IP CLK */
outpw(u32IPCLKRegAddr, inpw(u32IPCLKRegAddr) & ~(1 << u32IPCLKRegBit));
}
/* Leave critical section */
rt_hw_interrupt_enable(level);
}
void nu_sys_ipclk_enable(E_SYS_IPCLK eIPClkIdx)
{
_nu_sys_ipclk(eIPClkIdx, 1);
}
void nu_sys_ipclk_disable(E_SYS_IPCLK eIPClkIdx)
{
_nu_sys_ipclk(eIPClkIdx, 0);
}
E_SYS_USB0_ID nu_sys_usb0_role(void)
{
/* Check Role on USB0 dual-role port. */
/*
[17] USB0_IDS
USB0_ID Status
0 = USB port 0 used as a USB device port.
1 = USB port 0 used as a USB host port.
*/
return ((inpw(REG_SYS_MISCISR) & (1 << 17)) > 0) ? USB0_ID_HOST : USB0_ID_DEVICE;
}
#ifdef RT_USING_FINSH
#include <finsh.h>
FINSH_FUNCTION_EXPORT_ALIAS(rt_hw_cpu_reset, reset, restart the system);
#ifdef FINSH_USING_MSH
int cmd_reset(int argc, char **argv)
{
rt_hw_cpu_reset();
return 0;
}
int cmd_shutdown(int argc, char **argv)
{
rt_hw_cpu_shutdown();
return 0;
}
FINSH_FUNCTION_EXPORT_ALIAS(cmd_reset, __cmd_reset, restart the system.);
FINSH_FUNCTION_EXPORT_ALIAS(cmd_shutdown, __cmd_shutdown, shutdown the system.);
int nu_clocks(int argc, char **argv)
{
rt_kprintf("SYS_UPLL = %d MHz\n", sysGetClock(SYS_UPLL));
rt_kprintf("SYS_APLL = %d MHz\n", sysGetClock(SYS_APLL));
rt_kprintf("SYS_SYSTEM = %d MHz\n", sysGetClock(SYS_SYSTEM));
rt_kprintf("SYS_HCLK = %d MHz\n", sysGetClock(SYS_HCLK));
rt_kprintf("SYS_PCLK01 = %d MHz\n", sysGetClock(SYS_PCLK01));
rt_kprintf("SYS_PCLK2 = %d MHz\n", sysGetClock(SYS_PCLK2));
rt_kprintf("SYS_CPU = %d MHz\n", sysGetClock(SYS_CPU));
rt_kprintf("CLK_HCLKEN = %08X\n", inpw(REG_CLK_HCLKEN));
rt_kprintf("CLK_PCLKEN0 = %08X\n", inpw(REG_CLK_PCLKEN0));
rt_kprintf("CLK_PCLKEN1 = %08X\n", inpw(REG_CLK_PCLKEN1));
rt_kprintf("AIC_INTMSK0 = %08X\n", inpw(REG_AIC_INTMSK0));
rt_kprintf("AIC_INTMSK1 = %08X\n", inpw(REG_AIC_INTMSK1));
rt_kprintf("AIC_INTEN0 = %08X\n", inpw(REG_AIC_INTEN0));
rt_kprintf("AIC_INTEN1 = %08X\n", inpw(REG_AIC_INTEN1));
rt_kprintf("AIC_INTDIS0 = %08X\n", inpw(REG_AIC_INTDIS0));
rt_kprintf("AIC_INTDIS1 = %08X\n", inpw(REG_AIC_INTDIS1));
return 0;
}
MSH_CMD_EXPORT(nu_clocks, Get all system clocks);
#endif
#endif