rt-thread-official/libcpu/arm/cortex-m7/cpuport.c

/*
 * Copyright (c) 2006-2021, RT-Thread Development Team
 *
 * SPDX-License-Identifier: Apache-2.0
 *
 * Change Logs:
 * Date           Author       Notes
 * 2011-10-21     Bernard      the first version.
 * 2011-10-27     aozima       update for cortex-M4 FPU.
 * 2011-12-31     aozima       fixed stack align issues.
 * 2012-01-01     aozima       support context switch load/store FPU register.
 * 2012-12-11     lgnq         fixed the coding style.
 * 2012-12-23     aozima       stack addr align to 8byte.
 * 2012-12-29     Bernard      Add exception hook.
 * 2013-06-23     aozima       support lazy stack optimized.
 * 2018-07-24     aozima       enhancement hard fault exception handler.
 * 2019-07-03     yangjie      add __rt_ffs() for armclang.
 */

#include <rtthread.h>

#if               /* ARMCC */ (  (defined ( __CC_ARM ) && defined ( __TARGET_FPU_VFP ))    \
                  /* Clang */ || (defined ( __clang__ ) && defined ( __VFP_FP__ ) && !defined(__SOFTFP__)) \
                  /* IAR */   || (defined ( __ICCARM__ ) && defined ( __ARMVFP__ ))        \
                  /* GNU */   || (defined ( __GNUC__ ) && defined ( __VFP_FP__ ) && !defined(__SOFTFP__)) )
#define USE_FPU   1
#else
#define USE_FPU   0
#endif

/* exception and interrupt handler table */
rt_uint32_t rt_interrupt_from_thread;
rt_uint32_t rt_interrupt_to_thread;
rt_uint32_t rt_thread_switch_interrupt_flag;
/* exception hook */
static rt_err_t (*rt_exception_hook)(void *context) = RT_NULL;

struct exception_stack_frame
{
    rt_uint32_t r0;
    rt_uint32_t r1;
    rt_uint32_t r2;
    rt_uint32_t r3;
    rt_uint32_t r12;
    rt_uint32_t lr;
    rt_uint32_t pc;
    rt_uint32_t psr;
};

struct stack_frame
{
#if USE_FPU
    rt_uint32_t flag;
#endif /* USE_FPU */

    /* r4 ~ r11 register */
    rt_uint32_t r4;
    rt_uint32_t r5;
    rt_uint32_t r6;
    rt_uint32_t r7;
    rt_uint32_t r8;
    rt_uint32_t r9;
    rt_uint32_t r10;
    rt_uint32_t r11;

    struct exception_stack_frame exception_stack_frame;
};

struct exception_stack_frame_fpu
{
    rt_uint32_t r0;
    rt_uint32_t r1;
    rt_uint32_t r2;
    rt_uint32_t r3;
    rt_uint32_t r12;
    rt_uint32_t lr;
    rt_uint32_t pc;
    rt_uint32_t psr;

#if USE_FPU
    /* FPU register */
    rt_uint32_t S0;
    rt_uint32_t S1;
    rt_uint32_t S2;
    rt_uint32_t S3;
    rt_uint32_t S4;
    rt_uint32_t S5;
    rt_uint32_t S6;
    rt_uint32_t S7;
    rt_uint32_t S8;
    rt_uint32_t S9;
    rt_uint32_t S10;
    rt_uint32_t S11;
    rt_uint32_t S12;
    rt_uint32_t S13;
    rt_uint32_t S14;
    rt_uint32_t S15;
    rt_uint32_t FPSCR;
    rt_uint32_t NO_NAME;
#endif
};

struct stack_frame_fpu
{
    rt_uint32_t flag;

    /* r4 ~ r11 register */
    rt_uint32_t r4;
    rt_uint32_t r5;
    rt_uint32_t r6;
    rt_uint32_t r7;
    rt_uint32_t r8;
    rt_uint32_t r9;
    rt_uint32_t r10;
    rt_uint32_t r11;

#if USE_FPU
    /* FPU register s16 ~ s31 */
    rt_uint32_t s16;
    rt_uint32_t s17;
    rt_uint32_t s18;
    rt_uint32_t s19;
    rt_uint32_t s20;
    rt_uint32_t s21;
    rt_uint32_t s22;
    rt_uint32_t s23;
    rt_uint32_t s24;
    rt_uint32_t s25;
    rt_uint32_t s26;
    rt_uint32_t s27;
    rt_uint32_t s28;
    rt_uint32_t s29;
    rt_uint32_t s30;
    rt_uint32_t s31;
#endif

    struct exception_stack_frame_fpu exception_stack_frame;
};

rt_uint8_t *rt_hw_stack_init(void       *tentry,
                             void       *parameter,
                             rt_uint8_t *stack_addr,
                             void       *texit)
{
    struct stack_frame *stack_frame;
    rt_uint8_t         *stk;
    unsigned long       i;

    stk  = stack_addr + sizeof(rt_uint32_t);
    stk  = (rt_uint8_t *)RT_ALIGN_DOWN((rt_uint32_t)stk, 8);
    stk -= sizeof(struct stack_frame);

    stack_frame = (struct stack_frame *)stk;

    /* init all register */
    for (i = 0; i < sizeof(struct stack_frame) / sizeof(rt_uint32_t); i ++)
    {
        ((rt_uint32_t *)stack_frame)[i] = 0xdeadbeef;
    }

    stack_frame->exception_stack_frame.r0  = (unsigned long)parameter; /* r0 : argument */
    stack_frame->exception_stack_frame.r1  = 0;                        /* r1 */
    stack_frame->exception_stack_frame.r2  = 0;                        /* r2 */
    stack_frame->exception_stack_frame.r3  = 0;                        /* r3 */
    stack_frame->exception_stack_frame.r12 = 0;                        /* r12 */
    stack_frame->exception_stack_frame.lr  = (unsigned long)texit;     /* lr */
    stack_frame->exception_stack_frame.pc  = (unsigned long)tentry;    /* entry point, pc */
    stack_frame->exception_stack_frame.psr = 0x01000000L;              /* PSR */

#if USE_FPU
    stack_frame->flag = 0;
#endif /* USE_FPU */

    /* return task's current stack address */
    return stk;
}

/**
 * This function set the hook, which is invoked on fault exception handling.
 *
 * @param exception_handle the exception handling hook function.
 */
void rt_hw_exception_install(rt_err_t (*exception_handle)(void *context))
{
    rt_exception_hook = exception_handle;
}

#define SCB_CFSR        (*(volatile const unsigned *)0xE000ED28) /* Configurable Fault Status Register */
#define SCB_HFSR        (*(volatile const unsigned *)0xE000ED2C) /* HardFault Status Register */
#define SCB_MMAR        (*(volatile const unsigned *)0xE000ED34) /* MemManage Fault Address register */
#define SCB_BFAR        (*(volatile const unsigned *)0xE000ED38) /* Bus Fault Address Register */
#define SCB_AIRCR       (*(volatile unsigned long *)0xE000ED0C)  /* Reset control Address Register */
#define SCB_RESET_VALUE 0x05FA0004                               /* Reset value, write to SCB_AIRCR can reset cpu */

#define SCB_CFSR_MFSR   (*(volatile const unsigned char*)0xE000ED28)  /* Memory-management Fault Status Register */
#define SCB_CFSR_BFSR   (*(volatile const unsigned char*)0xE000ED29)  /* Bus Fault Status Register */
#define SCB_CFSR_UFSR   (*(volatile const unsigned short*)0xE000ED2A) /* Usage Fault Status Register */

#ifdef RT_USING_FINSH
static void usage_fault_track(void)
{
    rt_kprintf("usage fault:\n");
    rt_kprintf("SCB_CFSR_UFSR:0x%02X ", SCB_CFSR_UFSR);

    if(SCB_CFSR_UFSR & (1<<0))
    {
        /* [0]:UNDEFINSTR */
        rt_kprintf("UNDEFINSTR ");
    }

    if(SCB_CFSR_UFSR & (1<<1))
    {
        /* [1]:INVSTATE */
        rt_kprintf("INVSTATE ");
    }

    if(SCB_CFSR_UFSR & (1<<2))
    {
        /* [2]:INVPC */
        rt_kprintf("INVPC ");
    }

    if(SCB_CFSR_UFSR & (1<<3))
    {
        /* [3]:NOCP */
        rt_kprintf("NOCP ");
    }

    if(SCB_CFSR_UFSR & (1<<8))
    {
        /* [8]:UNALIGNED */
        rt_kprintf("UNALIGNED ");
    }

    if(SCB_CFSR_UFSR & (1<<9))
    {
        /* [9]:DIVBYZERO */
        rt_kprintf("DIVBYZERO ");
    }

    rt_kprintf("\n");
}

static void bus_fault_track(void)
{
    rt_kprintf("bus fault:\n");
    rt_kprintf("SCB_CFSR_BFSR:0x%02X ", SCB_CFSR_BFSR);

    if(SCB_CFSR_BFSR & (1<<0))
    {
        /* [0]:IBUSERR */
        rt_kprintf("IBUSERR ");
    }

    if(SCB_CFSR_BFSR & (1<<1))
    {
        /* [1]:PRECISERR */
        rt_kprintf("PRECISERR ");
    }

    if(SCB_CFSR_BFSR & (1<<2))
    {
        /* [2]:IMPRECISERR */
        rt_kprintf("IMPRECISERR ");
    }

    if(SCB_CFSR_BFSR & (1<<3))
    {
        /* [3]:UNSTKERR */
        rt_kprintf("UNSTKERR ");
    }

    if(SCB_CFSR_BFSR & (1<<4))
    {
        /* [4]:STKERR */
        rt_kprintf("STKERR ");
    }

    if(SCB_CFSR_BFSR & (1<<7))
    {
        rt_kprintf("SCB->BFAR:%08X\n", SCB_BFAR);
    }
    else
    {
        rt_kprintf("\n");
    }
}

static void mem_manage_fault_track(void)
{
    rt_kprintf("mem manage fault:\n");
    rt_kprintf("SCB_CFSR_MFSR:0x%02X ", SCB_CFSR_MFSR);

    if(SCB_CFSR_MFSR & (1<<0))
    {
        /* [0]:IACCVIOL */
        rt_kprintf("IACCVIOL ");
    }

    if(SCB_CFSR_MFSR & (1<<1))
    {
        /* [1]:DACCVIOL */
        rt_kprintf("DACCVIOL ");
    }

    if(SCB_CFSR_MFSR & (1<<3))
    {
        /* [3]:MUNSTKERR */
        rt_kprintf("MUNSTKERR ");
    }

    if(SCB_CFSR_MFSR & (1<<4))
    {
        /* [4]:MSTKERR */
        rt_kprintf("MSTKERR ");
    }

    if(SCB_CFSR_MFSR & (1<<7))
    {
        /* [7]:MMARVALID */
        rt_kprintf("SCB->MMAR:%08X\n", SCB_MMAR);
    }
    else
    {
        rt_kprintf("\n");
    }
}

static void hard_fault_track(void)
{
    if(SCB_HFSR & (1UL<<1))
    {
        /* [1]:VECTBL, Indicates hard fault is caused by failed vector fetch. */
        rt_kprintf("failed vector fetch\n");
    }

    if(SCB_HFSR & (1UL<<30))
    {
        /* [30]:FORCED, Indicates hard fault is taken because of bus fault,
                        memory management fault, or usage fault. */
        if(SCB_CFSR_BFSR)
        {
            bus_fault_track();
        }

        if(SCB_CFSR_MFSR)
        {
            mem_manage_fault_track();
        }

        if(SCB_CFSR_UFSR)
        {
            usage_fault_track();
        }
    }

    if(SCB_HFSR & (1UL<<31))
    {
        /* [31]:DEBUGEVT, Indicates hard fault is triggered by debug event. */
        rt_kprintf("debug event\n");
    }
}
#endif /* RT_USING_FINSH */

struct exception_info
{
    rt_uint32_t exc_return;
    struct stack_frame stack_frame;
};

void rt_hw_hard_fault_exception(struct exception_info *exception_info)
{
#if defined(RT_USING_FINSH) && defined(MSH_USING_BUILT_IN_COMMANDS)
    extern long list_thread(void);
#endif
    struct exception_stack_frame *exception_stack = &exception_info->stack_frame.exception_stack_frame;
    struct stack_frame *context = &exception_info->stack_frame;

    if (rt_exception_hook != RT_NULL)
    {
        rt_err_t result;

        result = rt_exception_hook(exception_stack);
        if (result == RT_EOK) return;
    }

    rt_kprintf("psr: 0x%08x\n", context->exception_stack_frame.psr);

    rt_kprintf("r00: 0x%08x\n", context->exception_stack_frame.r0);
    rt_kprintf("r01: 0x%08x\n", context->exception_stack_frame.r1);
    rt_kprintf("r02: 0x%08x\n", context->exception_stack_frame.r2);
    rt_kprintf("r03: 0x%08x\n", context->exception_stack_frame.r3);
    rt_kprintf("r04: 0x%08x\n", context->r4);
    rt_kprintf("r05: 0x%08x\n", context->r5);
    rt_kprintf("r06: 0x%08x\n", context->r6);
    rt_kprintf("r07: 0x%08x\n", context->r7);
    rt_kprintf("r08: 0x%08x\n", context->r8);
    rt_kprintf("r09: 0x%08x\n", context->r9);
    rt_kprintf("r10: 0x%08x\n", context->r10);
    rt_kprintf("r11: 0x%08x\n", context->r11);
    rt_kprintf("r12: 0x%08x\n", context->exception_stack_frame.r12);
    rt_kprintf(" lr: 0x%08x\n", context->exception_stack_frame.lr);
    rt_kprintf(" pc: 0x%08x\n", context->exception_stack_frame.pc);

    if (exception_info->exc_return & (1 << 2))
    {
        rt_kprintf("hard fault on thread: %s\r\n\r\n", rt_thread_self()->parent.name);

#if defined(RT_USING_FINSH) && defined(MSH_USING_BUILT_IN_COMMANDS)
        list_thread();
#endif
    }
    else
    {
        rt_kprintf("hard fault on handler\r\n\r\n");
    }

    if ( (exception_info->exc_return & 0x10) == 0)
    {
        rt_kprintf("FPU active!\r\n");
    }

#ifdef RT_USING_FINSH
    hard_fault_track();
#endif /* RT_USING_FINSH */

    while (1);
}

/**
 * shutdown CPU
 */
rt_weak void rt_hw_cpu_shutdown(void)
{
    rt_kprintf("shutdown...\n");

    RT_ASSERT(0);
}

/**
 * reset CPU
 */
rt_weak void rt_hw_cpu_reset(void)
{
    SCB_AIRCR = SCB_RESET_VALUE;
}

#ifdef RT_USING_CPU_FFS
/**
 * This function finds the first bit set (beginning with the least significant bit)
 * in value and return the index of that bit.
 *
 * Bits are numbered starting at 1 (the least significant bit).  A return value of
 * zero from any of these functions means that the argument was zero.
 *
 * @return return the index of the first bit set. If value is 0, then this function
 * shall return 0.
 */
#if defined(__CC_ARM)
__asm int __rt_ffs(int value)
{
    CMP     r0, #0x00
    BEQ     exit

    RBIT    r0, r0
    CLZ     r0, r0
    ADDS    r0, r0, #0x01

exit
    BX      lr
}
#elif defined(__clang__)
int __rt_ffs(int value)
{
    __asm volatile(
        "CMP     %1, #0x00            \n"
        "BEQ     1f                   \n"

        "RBIT    %1, %1               \n"
        "CLZ     %0, %1               \n"
        "ADDS    %0, %0, #0x01        \n"

        "1:                           \n"

        : "=r"(value)
        : "r"(value)
    );
    return value;
}
#elif defined(__IAR_SYSTEMS_ICC__)
int __rt_ffs(int value)
{
    if (value == 0) return value;

    asm("RBIT %0, %1" : "=r"(value) : "r"(value));
    asm("CLZ  %0, %1" : "=r"(value) : "r"(value));
    asm("ADDS %0, %1, #0x01" : "=r"(value) : "r"(value));

    return value;
}
#elif defined(__GNUC__)
int __rt_ffs(int value)
{
    return __builtin_ffs(value);
}
#endif

#endif
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`/*`
[libcpu] auto formatted 2021-03-27 17:51:56 +08:00			`* Copyright (c) 2006-2021, RT-Thread Development Team`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`*`
[libcpu] Fix the FPU definition in M4/M7 for ARM Clang 2018-09-25 11:08:58 +08:00			`* SPDX-License-Identifier: Apache-2.0`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`*`
			`* Change Logs:`
			`* Date Author Notes`
			`* 2011-10-21 Bernard the first version.`
			`* 2011-10-27 aozima update for cortex-M4 FPU.`
			`* 2011-12-31 aozima fixed stack align issues.`
			`* 2012-01-01 aozima support context switch load/store FPU register.`
			`* 2012-12-11 lgnq fixed the coding style.`
			`* 2012-12-23 aozima stack addr align to 8byte.`
			`* 2012-12-29 Bernard Add exception hook.`
			`* 2013-06-23 aozima support lazy stack optimized.`
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`* 2018-07-24 aozima enhancement hard fault exception handler.`
[libcpu/arm]add __rt_ffs() for armclang in CORTEX M3/4/7 2019-07-03 18:47:11 +08:00			`* 2019-07-03 yangjie add __rt_ffs() for armclang.`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`*/`

			`#include <rtthread.h>`

[Kernel] Add ARMCC 6.x support. 2018-09-23 12:08:44 +08:00			`#if /* ARMCC */ ( (defined ( __CC_ARM ) && defined ( __TARGET_FPU_VFP )) \`
[armclang] 使用__clang__代替__CLANG_ARM 2021-12-30 03:14:07 +08:00			`/* Clang */ \|\| (defined ( __clang__ ) && defined ( __VFP_FP__ ) && !defined(__SOFTFP__)) \`
[Kernel] Add ARMCC 6.x support. 2018-09-23 12:08:44 +08:00			`/* IAR */ \|\| (defined ( __ICCARM__ ) && defined ( __ARMVFP__ )) \`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`/* GNU */ \|\| (defined ( __GNUC__ ) && defined ( __VFP_FP__ ) && !defined(__SOFTFP__)) )`
[Kernel] Add ARMCC 6.x support. 2018-09-23 12:08:44 +08:00			`#define USE_FPU 1`
			`#else`
			`#define USE_FPU 0`
			`#endif`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00
			`/* exception and interrupt handler table */`
			`rt_uint32_t rt_interrupt_from_thread;`
			`rt_uint32_t rt_interrupt_to_thread;`
			`rt_uint32_t rt_thread_switch_interrupt_flag;`
			`/* exception hook */`
			`static rt_err_t (rt_exception_hook)(void context) = RT_NULL;`

			`struct exception_stack_frame`
			`{`
			`rt_uint32_t r0;`
			`rt_uint32_t r1;`
			`rt_uint32_t r2;`
			`rt_uint32_t r3;`
			`rt_uint32_t r12;`
			`rt_uint32_t lr;`
			`rt_uint32_t pc;`
			`rt_uint32_t psr;`
			`};`

			`struct stack_frame`
			`{`
			`#if USE_FPU`
			`rt_uint32_t flag;`
			`#endif /* USE_FPU */`

			`/* r4 ~ r11 register */`
			`rt_uint32_t r4;`
			`rt_uint32_t r5;`
			`rt_uint32_t r6;`
			`rt_uint32_t r7;`
			`rt_uint32_t r8;`
			`rt_uint32_t r9;`
			`rt_uint32_t r10;`
			`rt_uint32_t r11;`

			`struct exception_stack_frame exception_stack_frame;`
			`};`

			`struct exception_stack_frame_fpu`
			`{`
			`rt_uint32_t r0;`
			`rt_uint32_t r1;`
			`rt_uint32_t r2;`
			`rt_uint32_t r3;`
			`rt_uint32_t r12;`
			`rt_uint32_t lr;`
			`rt_uint32_t pc;`
			`rt_uint32_t psr;`

			`#if USE_FPU`
			`/* FPU register */`
			`rt_uint32_t S0;`
			`rt_uint32_t S1;`
			`rt_uint32_t S2;`
			`rt_uint32_t S3;`
			`rt_uint32_t S4;`
			`rt_uint32_t S5;`
			`rt_uint32_t S6;`
			`rt_uint32_t S7;`
			`rt_uint32_t S8;`
			`rt_uint32_t S9;`
			`rt_uint32_t S10;`
			`rt_uint32_t S11;`
			`rt_uint32_t S12;`
			`rt_uint32_t S13;`
			`rt_uint32_t S14;`
			`rt_uint32_t S15;`
			`rt_uint32_t FPSCR;`
			`rt_uint32_t NO_NAME;`
			`#endif`
			`};`

			`struct stack_frame_fpu`
			`{`
			`rt_uint32_t flag;`

			`/* r4 ~ r11 register */`
			`rt_uint32_t r4;`
			`rt_uint32_t r5;`
			`rt_uint32_t r6;`
			`rt_uint32_t r7;`
			`rt_uint32_t r8;`
			`rt_uint32_t r9;`
			`rt_uint32_t r10;`
			`rt_uint32_t r11;`

			`#if USE_FPU`
			`/* FPU register s16 ~ s31 */`
			`rt_uint32_t s16;`
			`rt_uint32_t s17;`
			`rt_uint32_t s18;`
			`rt_uint32_t s19;`
			`rt_uint32_t s20;`
			`rt_uint32_t s21;`
			`rt_uint32_t s22;`
			`rt_uint32_t s23;`
			`rt_uint32_t s24;`
			`rt_uint32_t s25;`
			`rt_uint32_t s26;`
			`rt_uint32_t s27;`
			`rt_uint32_t s28;`
			`rt_uint32_t s29;`
			`rt_uint32_t s30;`
			`rt_uint32_t s31;`
			`#endif`

			`struct exception_stack_frame_fpu exception_stack_frame;`
			`};`

			`rt_uint8_t rt_hw_stack_init(void tentry,`
			`void *parameter,`
			`rt_uint8_t *stack_addr,`
			`void *texit)`
			`{`
			`struct stack_frame *stack_frame;`
			`rt_uint8_t *stk;`
			`unsigned long i;`

			`stk = stack_addr + sizeof(rt_uint32_t);`
			`stk = (rt_uint8_t *)RT_ALIGN_DOWN((rt_uint32_t)stk, 8);`
			`stk -= sizeof(struct stack_frame);`

			`stack_frame = (struct stack_frame *)stk;`

			`/* init all register */`
			`for (i = 0; i < sizeof(struct stack_frame) / sizeof(rt_uint32_t); i ++)`
			`{`
			`((rt_uint32_t *)stack_frame)[i] = 0xdeadbeef;`
			`}`

			`stack_frame->exception_stack_frame.r0 = (unsigned long)parameter; /* r0 : argument */`
			`stack_frame->exception_stack_frame.r1 = 0; /* r1 */`
			`stack_frame->exception_stack_frame.r2 = 0; /* r2 */`
			`stack_frame->exception_stack_frame.r3 = 0; /* r3 */`
			`stack_frame->exception_stack_frame.r12 = 0; /* r12 */`
			`stack_frame->exception_stack_frame.lr = (unsigned long)texit; /* lr */`
			`stack_frame->exception_stack_frame.pc = (unsigned long)tentry; /* entry point, pc */`
			`stack_frame->exception_stack_frame.psr = 0x01000000L; /* PSR */`

			`#if USE_FPU`
			`stack_frame->flag = 0;`
			`#endif /* USE_FPU */`

			`/* return task's current stack address */`
			`return stk;`
			`}`

			`/**`
			`* This function set the hook, which is invoked on fault exception handling.`
			`*`
			`* @param exception_handle the exception handling hook function.`
			`*/`
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`void rt_hw_exception_install(rt_err_t (exception_handle)(void context))`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`{`
			`rt_exception_hook = exception_handle;`
			`}`

[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`#define SCB_CFSR ((volatile const unsigned )0xE000ED28) /* Configurable Fault Status Register */`
			`#define SCB_HFSR ((volatile const unsigned )0xE000ED2C) /* HardFault Status Register */`
			`#define SCB_MMAR ((volatile const unsigned )0xE000ED34) /* MemManage Fault Address register */`
			`#define SCB_BFAR ((volatile const unsigned )0xE000ED38) /* Bus Fault Address Register */`
add rt_hw_cpu_reset for cortex-m cpu 2018-08-01 11:57:56 +08:00			`#define SCB_AIRCR ((volatile unsigned long )0xE000ED0C) /* Reset control Address Register */`
			`#define SCB_RESET_VALUE 0x05FA0004 /* Reset value, write to SCB_AIRCR can reset cpu */`
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00
			`#define SCB_CFSR_MFSR ((volatile const unsigned char)0xE000ED28) /* Memory-management Fault Status Register */`
			`#define SCB_CFSR_BFSR ((volatile const unsigned char)0xE000ED29) /* Bus Fault Status Register */`
			`#define SCB_CFSR_UFSR ((volatile const unsigned short)0xE000ED2A) /* Usage Fault Status Register */`

			`#ifdef RT_USING_FINSH`
			`static void usage_fault_track(void)`
			`{`
			`rt_kprintf("usage fault:\n");`
			`rt_kprintf("SCB_CFSR_UFSR:0x%02X ", SCB_CFSR_UFSR);`

			`if(SCB_CFSR_UFSR & (1<<0))`
			`{`
			`/* [0]:UNDEFINSTR */`
			`rt_kprintf("UNDEFINSTR ");`
			`}`

			`if(SCB_CFSR_UFSR & (1<<1))`
			`{`
			`/* [1]:INVSTATE */`
			`rt_kprintf("INVSTATE ");`
			`}`

			`if(SCB_CFSR_UFSR & (1<<2))`
			`{`
			`/* [2]:INVPC */`
			`rt_kprintf("INVPC ");`
			`}`

			`if(SCB_CFSR_UFSR & (1<<3))`
			`{`
			`/* [3]:NOCP */`
			`rt_kprintf("NOCP ");`
			`}`

			`if(SCB_CFSR_UFSR & (1<<8))`
			`{`
			`/* [8]:UNALIGNED */`
			`rt_kprintf("UNALIGNED ");`
			`}`

			`if(SCB_CFSR_UFSR & (1<<9))`
			`{`
			`/* [9]:DIVBYZERO */`
			`rt_kprintf("DIVBYZERO ");`
			`}`

			`rt_kprintf("\n");`
			`}`

			`static void bus_fault_track(void)`
			`{`
			`rt_kprintf("bus fault:\n");`
			`rt_kprintf("SCB_CFSR_BFSR:0x%02X ", SCB_CFSR_BFSR);`

			`if(SCB_CFSR_BFSR & (1<<0))`
			`{`
			`/* [0]:IBUSERR */`
			`rt_kprintf("IBUSERR ");`
			`}`

			`if(SCB_CFSR_BFSR & (1<<1))`
			`{`
			`/* [1]:PRECISERR */`
			`rt_kprintf("PRECISERR ");`
			`}`

			`if(SCB_CFSR_BFSR & (1<<2))`
			`{`
			`/* [2]:IMPRECISERR */`
			`rt_kprintf("IMPRECISERR ");`
			`}`

			`if(SCB_CFSR_BFSR & (1<<3))`
			`{`
			`/* [3]:UNSTKERR */`
			`rt_kprintf("UNSTKERR ");`
			`}`

			`if(SCB_CFSR_BFSR & (1<<4))`
			`{`
			`/* [4]:STKERR */`
			`rt_kprintf("STKERR ");`
			`}`

			`if(SCB_CFSR_BFSR & (1<<7))`
			`{`
			`rt_kprintf("SCB->BFAR:%08X\n", SCB_BFAR);`
			`}`
			`else`
			`{`
			`rt_kprintf("\n");`
			`}`
			`}`

			`static void mem_manage_fault_track(void)`
			`{`
			`rt_kprintf("mem manage fault:\n");`
			`rt_kprintf("SCB_CFSR_MFSR:0x%02X ", SCB_CFSR_MFSR);`

			`if(SCB_CFSR_MFSR & (1<<0))`
			`{`
			`/* [0]:IACCVIOL */`
			`rt_kprintf("IACCVIOL ");`
			`}`

			`if(SCB_CFSR_MFSR & (1<<1))`
			`{`
			`/* [1]:DACCVIOL */`
			`rt_kprintf("DACCVIOL ");`
			`}`

			`if(SCB_CFSR_MFSR & (1<<3))`
			`{`
			`/* [3]:MUNSTKERR */`
			`rt_kprintf("MUNSTKERR ");`
			`}`

			`if(SCB_CFSR_MFSR & (1<<4))`
			`{`
			`/* [4]:MSTKERR */`
			`rt_kprintf("MSTKERR ");`
			`}`

			`if(SCB_CFSR_MFSR & (1<<7))`
			`{`
			`/* [7]:MMARVALID */`
			`rt_kprintf("SCB->MMAR:%08X\n", SCB_MMAR);`
			`}`
			`else`
			`{`
			`rt_kprintf("\n");`
			`}`
			`}`

			`static void hard_fault_track(void)`
			`{`
			`if(SCB_HFSR & (1UL<<1))`
			`{`
			`/* [1]:VECTBL, Indicates hard fault is caused by failed vector fetch. */`
			`rt_kprintf("failed vector fetch\n");`
			`}`

			`if(SCB_HFSR & (1UL<<30))`
			`{`
			`/* [30]:FORCED, Indicates hard fault is taken because of bus fault,`
			`memory management fault, or usage fault. */`
			`if(SCB_CFSR_BFSR)`
			`{`
			`bus_fault_track();`
			`}`

			`if(SCB_CFSR_MFSR)`
			`{`
			`mem_manage_fault_track();`
			`}`

			`if(SCB_CFSR_UFSR)`
			`{`
			`usage_fault_track();`
			`}`
			`}`

			`if(SCB_HFSR & (1UL<<31))`
			`{`
			`/* [31]:DEBUGEVT, Indicates hard fault is triggered by debug event. */`
			`rt_kprintf("debug event\n");`
			`}`
			`}`
			`#endif /* RT_USING_FINSH */`

			`struct exception_info`
			`{`
			`rt_uint32_t exc_return;`
			`struct stack_frame stack_frame;`
			`};`

			`void rt_hw_hard_fault_exception(struct exception_info *exception_info)`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`{`
FINSH_USING_BUILT_IN_COMMANDS改MSH_USING_BUILT_IN_COMMANDS 2021-08-29 04:48:08 +08:00			`#if defined(RT_USING_FINSH) && defined(MSH_USING_BUILT_IN_COMMANDS)`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`extern long list_thread(void);`
[finsh] finsh组件可以选择是否包含内置命令 2021-08-26 07:10:01 +08:00			`#endif`
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`struct exception_stack_frame *exception_stack = &exception_info->stack_frame.exception_stack_frame;`
			`struct stack_frame *context = &exception_info->stack_frame;`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00
			`if (rt_exception_hook != RT_NULL)`
			`{`
			`rt_err_t result;`

			`result = rt_exception_hook(exception_stack);`
			`if (result == RT_EOK) return;`
			`}`

[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`rt_kprintf("psr: 0x%08x\n", context->exception_stack_frame.psr);`

			`rt_kprintf("r00: 0x%08x\n", context->exception_stack_frame.r0);`
			`rt_kprintf("r01: 0x%08x\n", context->exception_stack_frame.r1);`
			`rt_kprintf("r02: 0x%08x\n", context->exception_stack_frame.r2);`
			`rt_kprintf("r03: 0x%08x\n", context->exception_stack_frame.r3);`
			`rt_kprintf("r04: 0x%08x\n", context->r4);`
			`rt_kprintf("r05: 0x%08x\n", context->r5);`
			`rt_kprintf("r06: 0x%08x\n", context->r6);`
			`rt_kprintf("r07: 0x%08x\n", context->r7);`
			`rt_kprintf("r08: 0x%08x\n", context->r8);`
			`rt_kprintf("r09: 0x%08x\n", context->r9);`
			`rt_kprintf("r10: 0x%08x\n", context->r10);`
			`rt_kprintf("r11: 0x%08x\n", context->r11);`
			`rt_kprintf("r12: 0x%08x\n", context->exception_stack_frame.r12);`
			`rt_kprintf(" lr: 0x%08x\n", context->exception_stack_frame.lr);`
			`rt_kprintf(" pc: 0x%08x\n", context->exception_stack_frame.pc);`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`if (exception_info->exc_return & (1 << 2))`
			`{`
[kernel] 将rt_thread结构体改为显式继承rt_object (#7131) 2023-04-04 21:06:27 +08:00			`rt_kprintf("hard fault on thread: %s\r\n\r\n", rt_thread_self()->parent.name);`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00
FINSH_USING_BUILT_IN_COMMANDS改MSH_USING_BUILT_IN_COMMANDS 2021-08-29 04:48:08 +08:00			`#if defined(RT_USING_FINSH) && defined(MSH_USING_BUILT_IN_COMMANDS)`
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`list_thread();`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`#endif`
[libcpu][comtex-m7] enhancement hard fault exception handler. 2018-07-24 21:16:34 +08:00			`}`
			`else`
			`{`
			`rt_kprintf("hard fault on handler\r\n\r\n");`
			`}`

			`if ( (exception_info->exc_return & 0x10) == 0)`
			`{`
			`rt_kprintf("FPU active!\r\n");`
			`}`

			`#ifdef RT_USING_FINSH`
			`hard_fault_track();`
			`#endif /* RT_USING_FINSH */`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00
			`while (1);`
			`}`

			`/**`
			`* shutdown CPU`
			`*/`
[rtdef] use lower-case to define attributes (#6728) * [rtdef] rename RT_WEAK attribute as rt_weak * [rtdef] rename RT_USED attribute as rt_used * [rtdef] rename RT_SECTION attribute as rt_section * [rtdef] rename ALIGN attribute as rt_align * [legacy] add RT_USED ALIGN RT_SECTION RT_WEAK as legacy support 2022-12-12 02:12:03 +08:00			`rt_weak void rt_hw_cpu_shutdown(void)`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`{`
			`rt_kprintf("shutdown...\n");`

			`RT_ASSERT(0);`
			`}`

add rt_hw_cpu_reset for cortex-m cpu 2018-08-01 11:57:56 +08:00			`/**`
			`* reset CPU`
			`*/`
[rtdef] use lower-case to define attributes (#6728) * [rtdef] rename RT_WEAK attribute as rt_weak * [rtdef] rename RT_USED attribute as rt_used * [rtdef] rename RT_SECTION attribute as rt_section * [rtdef] rename ALIGN attribute as rt_align * [legacy] add RT_USED ALIGN RT_SECTION RT_WEAK as legacy support 2022-12-12 02:12:03 +08:00			`rt_weak void rt_hw_cpu_reset(void)`
add rt_hw_cpu_reset for cortex-m cpu 2018-08-01 11:57:56 +08:00			`{`
			`SCB_AIRCR = SCB_RESET_VALUE;`
			`}`

[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`#ifdef RT_USING_CPU_FFS`
			`/**`
			`* This function finds the first bit set (beginning with the least significant bit)`
			`* in value and return the index of that bit.`
			`*`
			`* Bits are numbered starting at 1 (the least significant bit). A return value of`
			`* zero from any of these functions means that the argument was zero.`
			`*`
			`* @return return the index of the first bit set. If value is 0, then this function`
			`* shall return 0.`
			`*/`
[libcpu/arm]add __rt_ffs() for armclang in CORTEX M3/4/7 2019-07-03 18:47:11 +08:00			`#if defined(__CC_ARM)`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`__asm int __rt_ffs(int value)`
			`{`
			`CMP r0, #0x00`
			`BEQ exit`
update cortex-m libcpu: fixed compile error. 2017-08-23 16:13:51 +08:00
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`RBIT r0, r0`
			`CLZ r0, r0`
			`ADDS r0, r0, #0x01`

			`exit`
			`BX lr`
			`}`
[armclang] 使用__clang__代替__CLANG_ARM 2021-12-30 03:14:07 +08:00			`#elif defined(__clang__)`
[libcpu/arm]add __rt_ffs() for armclang in CORTEX M3/4/7 2019-07-03 18:47:11 +08:00			`int __rt_ffs(int value)`
			`{`
			`__asm volatile(`
[libcpu][arm] fix armclang error when enable LTO 2022-08-11 14:45:43 +08:00			`"CMP %1, #0x00 \n"`
[libcpu/arm/*/cpuport.c]fixed __rt_ffs bug on account of armclang LTO. 2020-06-18 09:18:48 +08:00			`"BEQ 1f \n"`
[libcpu/arm]add __rt_ffs() for armclang in CORTEX M3/4/7 2019-07-03 18:47:11 +08:00
[libcpu][arm] fix armclang error when enable LTO 2022-08-11 14:45:43 +08:00			`"RBIT %1, %1 \n"`
			`"CLZ %0, %1 \n"`
			`"ADDS %0, %0, #0x01 \n"`
[libcpu/arm]add __rt_ffs() for armclang in CORTEX M3/4/7 2019-07-03 18:47:11 +08:00
[libcpu/arm/*/cpuport.c]fixed __rt_ffs bug on account of armclang LTO. 2020-06-18 09:18:48 +08:00			`"1: \n"`
[libcpu/arm]add __rt_ffs() for armclang in CORTEX M3/4/7 2019-07-03 18:47:11 +08:00
			`: "=r"(value)`
			`: "r"(value)`
			`);`
			`return value;`
			`}`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`#elif defined(__IAR_SYSTEMS_ICC__)`
			`int __rt_ffs(int value)`
			`{`
			`if (value == 0) return value;`

update cortex-m libcpu: fixed compile error. 2017-08-23 16:13:51 +08:00			`asm("RBIT %0, %1" : "=r"(value) : "r"(value));`
			`asm("CLZ %0, %1" : "=r"(value) : "r"(value));`
			`asm("ADDS %0, %1, #0x01" : "=r"(value) : "r"(value));`

			`return value;`
[bsp]add the stm32f74x bsp. 2015-08-07 13:30:13 +08:00			`}`
			`#elif defined(__GNUC__)`
			`int __rt_ffs(int value)`
			`{`
			`return __builtin_ffs(value);`
			`}`
			`#endif`

			`#endif`