1*10465441SEvalZero /*
2*10465441SEvalZero * Copyright (c) 2006-2018, RT-Thread Development Team
3*10465441SEvalZero *
4*10465441SEvalZero * SPDX-License-Identifier: Apache-2.0
5*10465441SEvalZero *
6*10465441SEvalZero * Change Logs:
7*10465441SEvalZero * Date Author Notes
8*10465441SEvalZero * 2006-03-13 Bernard first version
9*10465441SEvalZero * 2006-05-27 Bernard add skyeye support
10*10465441SEvalZero * 2007-11-19 Yi.Qiu fix rt_hw_trap_irq function
11*10465441SEvalZero * 2013-03-29 aozima Modify the interrupt interface implementations.
12*10465441SEvalZero */
13*10465441SEvalZero
14*10465441SEvalZero #include <rtthread.h>
15*10465441SEvalZero #include <rthw.h>
16*10465441SEvalZero
17*10465441SEvalZero #include <sep4020.h>
18*10465441SEvalZero
19*10465441SEvalZero /**
20*10465441SEvalZero * @addtogroup S3C24X0
21*10465441SEvalZero */
22*10465441SEvalZero /*@{*/
23*10465441SEvalZero
24*10465441SEvalZero extern struct rt_thread *rt_current_thread;
25*10465441SEvalZero
26*10465441SEvalZero /**
27*10465441SEvalZero * this function will show registers of CPU
28*10465441SEvalZero *
29*10465441SEvalZero * @param regs the registers point
30*10465441SEvalZero */
31*10465441SEvalZero
rt_hw_show_register(struct rt_hw_register * regs)32*10465441SEvalZero void rt_hw_show_register (struct rt_hw_register *regs)
33*10465441SEvalZero {
34*10465441SEvalZero rt_kprintf("Execption:\n");
35*10465441SEvalZero rt_kprintf("r00:0x%08x r01:0x%08x r02:0x%08x r03:0x%08x\n", regs->r0, regs->r1, regs->r2, regs->r3);
36*10465441SEvalZero rt_kprintf("r04:0x%08x r05:0x%08x r06:0x%08x r07:0x%08x\n", regs->r4, regs->r5, regs->r6, regs->r7);
37*10465441SEvalZero rt_kprintf("r08:0x%08x r09:0x%08x r10:0x%08x\n", regs->r8, regs->r9, regs->r10);
38*10465441SEvalZero rt_kprintf("fp :0x%08x ip :0x%08x\n", regs->fp, regs->ip);
39*10465441SEvalZero rt_kprintf("sp :0x%08x lr :0x%08x pc :0x%08x\n", regs->sp, regs->lr, regs->pc);
40*10465441SEvalZero rt_kprintf("cpsr:0x%08x\n", regs->cpsr);
41*10465441SEvalZero }
42*10465441SEvalZero
43*10465441SEvalZero /**
44*10465441SEvalZero * When ARM7TDMI comes across an instruction which it cannot handle,
45*10465441SEvalZero * it takes the undefined instruction trap.
46*10465441SEvalZero *
47*10465441SEvalZero * @param regs system registers
48*10465441SEvalZero *
49*10465441SEvalZero * @note never invoke this function in application
50*10465441SEvalZero */
rt_hw_trap_udef(struct rt_hw_register * regs)51*10465441SEvalZero void rt_hw_trap_udef(struct rt_hw_register *regs)
52*10465441SEvalZero {
53*10465441SEvalZero rt_hw_show_register(regs);
54*10465441SEvalZero
55*10465441SEvalZero rt_kprintf("undefined instruction\n");
56*10465441SEvalZero rt_kprintf("thread - %s stack:\n", rt_current_thread->name);
57*10465441SEvalZero rt_hw_backtrace((rt_uint32_t *)regs->fp, (rt_uint32_t)rt_current_thread->entry);
58*10465441SEvalZero
59*10465441SEvalZero rt_hw_cpu_shutdown();
60*10465441SEvalZero }
61*10465441SEvalZero
62*10465441SEvalZero /**
63*10465441SEvalZero * The software interrupt instruction (SWI) is used for entering
64*10465441SEvalZero * Supervisor mode, usually to request a particular supervisor
65*10465441SEvalZero * function.
66*10465441SEvalZero *
67*10465441SEvalZero * @param regs system registers
68*10465441SEvalZero *
69*10465441SEvalZero * @note never invoke this function in application
70*10465441SEvalZero */
rt_hw_trap_swi(struct rt_hw_register * regs)71*10465441SEvalZero void rt_hw_trap_swi(struct rt_hw_register *regs)
72*10465441SEvalZero {
73*10465441SEvalZero rt_hw_show_register(regs);
74*10465441SEvalZero
75*10465441SEvalZero rt_kprintf("software interrupt\n");
76*10465441SEvalZero rt_hw_cpu_shutdown();
77*10465441SEvalZero }
78*10465441SEvalZero
79*10465441SEvalZero /**
80*10465441SEvalZero * An abort indicates that the current memory access cannot be completed,
81*10465441SEvalZero * which occurs during an instruction prefetch.
82*10465441SEvalZero *
83*10465441SEvalZero * @param regs system registers
84*10465441SEvalZero *
85*10465441SEvalZero * @note never invoke this function in application
86*10465441SEvalZero */
rt_hw_trap_pabt(struct rt_hw_register * regs)87*10465441SEvalZero void rt_hw_trap_pabt(struct rt_hw_register *regs)
88*10465441SEvalZero {
89*10465441SEvalZero rt_hw_show_register(regs);
90*10465441SEvalZero
91*10465441SEvalZero rt_kprintf("prefetch abort\n");
92*10465441SEvalZero rt_kprintf("thread - %s stack:\n", rt_current_thread->name);
93*10465441SEvalZero rt_hw_backtrace((rt_uint32_t *)regs->fp, (rt_uint32_t)rt_current_thread->entry);
94*10465441SEvalZero
95*10465441SEvalZero rt_hw_cpu_shutdown();
96*10465441SEvalZero }
97*10465441SEvalZero
98*10465441SEvalZero /**
99*10465441SEvalZero * An abort indicates that the current memory access cannot be completed,
100*10465441SEvalZero * which occurs during a data access.
101*10465441SEvalZero *
102*10465441SEvalZero * @param regs system registers
103*10465441SEvalZero *
104*10465441SEvalZero * @note never invoke this function in application
105*10465441SEvalZero */
rt_hw_trap_dabt(struct rt_hw_register * regs)106*10465441SEvalZero void rt_hw_trap_dabt(struct rt_hw_register *regs)
107*10465441SEvalZero {
108*10465441SEvalZero rt_hw_show_register(regs);
109*10465441SEvalZero
110*10465441SEvalZero rt_kprintf("data abort\n");
111*10465441SEvalZero rt_kprintf("thread - %s stack:\n", rt_current_thread->name);
112*10465441SEvalZero rt_hw_backtrace((rt_uint32_t *)regs->fp, (rt_uint32_t)rt_current_thread->entry);
113*10465441SEvalZero
114*10465441SEvalZero rt_hw_cpu_shutdown();
115*10465441SEvalZero }
116*10465441SEvalZero
117*10465441SEvalZero /**
118*10465441SEvalZero * Normally, system will never reach here
119*10465441SEvalZero *
120*10465441SEvalZero * @param regs system registers
121*10465441SEvalZero *
122*10465441SEvalZero * @note never invoke this function in application
123*10465441SEvalZero */
rt_hw_trap_resv(struct rt_hw_register * regs)124*10465441SEvalZero void rt_hw_trap_resv(struct rt_hw_register *regs)
125*10465441SEvalZero {
126*10465441SEvalZero rt_kprintf("not used\n");
127*10465441SEvalZero rt_hw_show_register(regs);
128*10465441SEvalZero rt_hw_cpu_shutdown();
129*10465441SEvalZero }
130*10465441SEvalZero
131*10465441SEvalZero extern struct rt_irq_desc isr_table[];
132*10465441SEvalZero
rt_hw_trap_irq(void)133*10465441SEvalZero void rt_hw_trap_irq(void)
134*10465441SEvalZero {
135*10465441SEvalZero unsigned long intstat;
136*10465441SEvalZero rt_uint32_t irq = 0;
137*10465441SEvalZero rt_isr_handler_t isr_func;
138*10465441SEvalZero void *param;
139*10465441SEvalZero
140*10465441SEvalZero /*Get the final intrrupt source*/
141*10465441SEvalZero intstat = *(RP)(INTC_IFSR);;
142*10465441SEvalZero
143*10465441SEvalZero /*Shift to get the intrrupt number*/
144*10465441SEvalZero while(intstat != 1)
145*10465441SEvalZero {
146*10465441SEvalZero intstat = intstat >> 1;
147*10465441SEvalZero irq++;
148*10465441SEvalZero }
149*10465441SEvalZero
150*10465441SEvalZero /* get interrupt service routine */
151*10465441SEvalZero isr_func = isr_table[irq].handler;
152*10465441SEvalZero param = isr_table[irq].param;
153*10465441SEvalZero
154*10465441SEvalZero /* turn to interrupt service routine */
155*10465441SEvalZero isr_func(irq, param);
156*10465441SEvalZero
157*10465441SEvalZero #ifdef RT_USING_INTERRUPT_INFO
158*10465441SEvalZero isr_table[irq].counter++;
159*10465441SEvalZero #endif /* RT_USING_INTERRUPT_INFO */
160*10465441SEvalZero }
161*10465441SEvalZero
rt_hw_trap_fiq(void)162*10465441SEvalZero void rt_hw_trap_fiq(void)
163*10465441SEvalZero {
164*10465441SEvalZero rt_kprintf("fast interrupt request\n");
165*10465441SEvalZero }
166*10465441SEvalZero
167*10465441SEvalZero /*@}*/
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