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#include <cpu.h>
#include <cpu/irq.h>
#include <globals.h>
#include <graphics/lfb.h>
#include <symbols.h>
#include <sys/core.h>
#include <sys/schedule.h>
#include <tests/test.h>
#include <util/mutex.h>
#include <util/status.h>
#include <util/time.h>
#include <usr/main.h>
#define CPS 1000
static unsigned long counter = 0;
unsigned long c_irq_handler(void)
{
unsigned long source = load32(CORE0_IRQ_SOURCE);
// Check if GPU Interrupt
if (source & (1 << 8)) {
// Check if UART Interrupt
if(load32(IRQ_PENDING2) & (1 << 25)) {
// Check if UART Interrupt is Masked
if(load32(UART0_MIS) & (1<<4)) {
// Get the UART data
unsigned long data = load32(UART0_DR);
// Handle the recieved data
#ifdef DEBUG
// Ctrl+G to output scheduler debug info
if (data == 0x7) {
uart_scheduler();
uart_mutexes();
}
#endif
// Add task to handle the data
if (irqs[UART_IRQ].handler != 0) {
struct UartInfo* uart_info = irqs[UART_IRQ].handler_info;
add_thread(irqs[UART_IRQ].handler, (void*)data, uart_info->priority);
return 1;
}
}
}
// Check if System Time Compare 0 Triggered the Interrupt
if (*(volatile unsigned long*)SYS_TIMER_CS & SYS_TIMER_SC_M0 && irqs[SYS_TIMER_0_IRQ].handler != 0) {
volatile unsigned long* timer_cs = (volatile unsigned long*)SYS_TIMER_CS;
volatile unsigned long* timer_chi = (volatile unsigned long*)SYS_TIMER_CHI;
volatile unsigned long* nexttime = (volatile unsigned long*)SYS_TIMER_C0;
struct SysTimerInfo* stinfo = irqs[SYS_TIMER_0_IRQ].handler_info;
add_thread(irqs[SYS_TIMER_0_IRQ].handler, stinfo->arg, stinfo->priority);
*nexttime = *timer_chi + stinfo->tick_rate;
*timer_cs = SYS_TIMER_SC_M0;
return 1;
}
// Check if System Time Compare 1 Triggered the Interrupt
if (*(volatile unsigned long*)SYS_TIMER_CS & SYS_TIMER_SC_M1 && irqs[SYS_TIMER_1_IRQ].handler != 0) {
volatile unsigned long* timer_cs = (volatile unsigned long*)SYS_TIMER_CS;
volatile unsigned long* timer_chi = (volatile unsigned long*)SYS_TIMER_CHI;
volatile unsigned long* nexttime = (volatile unsigned long*)SYS_TIMER_C1;
struct SysTimerInfo* stinfo = irqs[SYS_TIMER_1_IRQ].handler_info;
add_thread(irqs[SYS_TIMER_1_IRQ].handler, stinfo->arg, stinfo->priority);
*nexttime = *timer_chi + stinfo->tick_rate;
*timer_cs = SYS_TIMER_SC_M1;
return 1;
}
// Check if System Time Compare 2 Triggered the Interrupt
if (*(volatile unsigned long*)SYS_TIMER_CS & SYS_TIMER_SC_M2 && irqs[SYS_TIMER_2_IRQ].handler != 0) {
volatile unsigned long* timer_cs = (volatile unsigned long*)SYS_TIMER_CS;
volatile unsigned long* timer_chi = (volatile unsigned long*)SYS_TIMER_CHI;
volatile unsigned long* nexttime = (volatile unsigned long*)SYS_TIMER_C2;
struct SysTimerInfo* stinfo = irqs[SYS_TIMER_2_IRQ].handler_info;
add_thread(irqs[SYS_TIMER_2_IRQ].handler, stinfo->arg, stinfo->priority);
*nexttime = *timer_chi + stinfo->tick_rate;
*timer_cs = SYS_TIMER_SC_M2;
return 1;
}
// Check if System Time Compare 3 Triggered the Interrupt
if (*(volatile unsigned long*)SYS_TIMER_CS & SYS_TIMER_SC_M3 && irqs[SYS_TIMER_3_IRQ].handler != 0) {
volatile unsigned long* timer_cs = (volatile unsigned long*)SYS_TIMER_CS;
volatile unsigned long* timer_chi = (volatile unsigned long*)SYS_TIMER_CHI;
volatile unsigned long* nexttime = (volatile unsigned long*)SYS_TIMER_C3;
struct SysTimerInfo* stinfo = irqs[SYS_TIMER_3_IRQ].handler_info;
add_thread(irqs[SYS_TIMER_3_IRQ].handler, stinfo->arg, stinfo->priority);
*nexttime = *timer_chi + stinfo->tick_rate;
*timer_cs = SYS_TIMER_SC_M3;
return 1;
}
}
// Check if CNTV triggered the interrupt
else if (source & (1 << 3)) {
// Reset the counter
write_cntv_tval(cntfrq);
counter++;
if (counter % 0x6000 == 0)
counter = 0;
}
return 0;
}
unsigned long c_fiq_handler(void)
{
unsigned long source = load32(CORE0_FIQ_SOURCE);
// Check if CNTV triggered the interrupt
if (source & (1 << 3) && irqs[LOCAL_TIMER_IRQ].handler != 0) {
add_thread(irqs[LOCAL_TIMER_IRQ].handler, 0, 1);
write_cntv_tval(cntfrq);
}
return 0;
}
void subscribe_irq(unsigned long irq_num, void* handler, void* handler_info)
{
if (irq_num >= MAX_IRQS)
return;
irqs[irq_num].handler = handler;
irqs[irq_num].handler_info = handler_info;
switch (irq_num) {
case UART_IRQ:
store32(1<<4, UART0_IMSC);
store32(1<<25, IRQ_ENABLE2);
break;
case SYS_TIMER_0_IRQ:
store32(SYS_TIMER_SC_M0, IRQ_ENABLE1);
*(volatile unsigned long*)SYS_TIMER_C0 = *(volatile unsigned long*)SYS_TIMER_CHI + *(unsigned long*)handler_info;
break;
case SYS_TIMER_1_IRQ:
store32(SYS_TIMER_SC_M1, IRQ_ENABLE1);
*(volatile unsigned long*)SYS_TIMER_C1 = *(volatile unsigned long*)SYS_TIMER_CHI + *(unsigned long*)handler_info;
break;
case SYS_TIMER_2_IRQ:
store32(SYS_TIMER_SC_M2, IRQ_ENABLE1);
*(volatile unsigned long*)SYS_TIMER_C2 = *(volatile unsigned long*)SYS_TIMER_CHI + *(unsigned long*)handler_info;
break;
case SYS_TIMER_3_IRQ:
store32(SYS_TIMER_SC_M3, IRQ_ENABLE1);
*(volatile unsigned long*)SYS_TIMER_C3 = *(volatile unsigned long*)SYS_TIMER_CHI + *(unsigned long*)handler_info;
break;
}
}
void unsubscribe_irq(unsigned long irq_num)
{
if (irq_num >= MAX_IRQS)
return;
irqs[irq_num].handler = 0;
irqs[irq_num].handler_info = 0;
switch (irq_num) {
case UART_IRQ:
store32(1<<25, IRQ_DISABLE2);
break;
case SYS_TIMER_0_IRQ:
store32(SYS_TIMER_SC_M0, IRQ_DISABLE1);
break;
case SYS_TIMER_1_IRQ:
store32(SYS_TIMER_SC_M1, IRQ_DISABLE1);
break;
case SYS_TIMER_2_IRQ:
store32(SYS_TIMER_SC_M2, IRQ_DISABLE1);
break;
case SYS_TIMER_3_IRQ:
store32(SYS_TIMER_SC_M3, IRQ_DISABLE1);
break;
}
}
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