zephyr/drivers/interrupt_controller/intc_ite_it8xxx2.c

253 lines
6.0 KiB
C

/*
* Copyright (c) 2020 ITE Corporation. All Rights Reserved
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <zephyr/kernel.h>
#include <zephyr/arch/cpu.h>
#include <zephyr/init.h>
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(intc_it8xxx2, LOG_LEVEL_DBG);
#include <zephyr/sys/printk.h>
#include <zephyr/sw_isr_table.h>
#include "intc_ite_it8xxx2.h"
#define MAX_REGISR_IRQ_NUM 8
#define IVECT_OFFSET_WITH_IRQ 0x10
/* Interrupt number of INTC module */
static uint8_t intc_irq;
static volatile uint8_t *const reg_status[] = {
&ISR0, &ISR1, &ISR2, &ISR3,
&ISR4, &ISR5, &ISR6, &ISR7,
&ISR8, &ISR9, &ISR10, &ISR11,
&ISR12, &ISR13, &ISR14, &ISR15,
&ISR16, &ISR17, &ISR18, &ISR19,
&ISR20, &ISR21, &ISR22, &ISR23
};
static volatile uint8_t *const reg_enable[] = {
&IER0, &IER1, &IER2, &IER3,
&IER4, &IER5, &IER6, &IER7,
&IER8, &IER9, &IER10, &IER11,
&IER12, &IER13, &IER14, &IER15,
&IER16, &IER17, &IER18, &IER19,
&IER20, &IER21, &IER22, &IER23
};
/* edge/level trigger register */
static volatile uint8_t *const reg_ielmr[] = {
&IELMR0, &IELMR1, &IELMR2, &IELMR3,
&IELMR4, &IELMR5, &IELMR6, &IELMR7,
&IELMR8, &IELMR9, &IELMR10, &IELMR11,
&IELMR12, &IELMR13, &IELMR14, &IELMR15,
&IELMR16, &IELMR17, &IELMR18, &IELMR19,
&IELMR20, &IELMR21, &IELMR22, &IELMR23,
};
/* high/low trigger register */
static volatile uint8_t *const reg_ipolr[] = {
&IPOLR0, &IPOLR1, &IPOLR2, &IPOLR3,
&IPOLR4, &IPOLR5, &IPOLR6, &IPOLR7,
&IPOLR8, &IPOLR9, &IPOLR10, &IPOLR11,
&IPOLR12, &IPOLR13, &IPOLR14, &IPOLR15,
&IPOLR16, &IPOLR17, &IPOLR18, &IPOLR19,
&IPOLR20, &IPOLR21, &IPOLR22, &IPOLR23
};
#define IT8XXX2_IER_COUNT ARRAY_SIZE(reg_enable)
static uint8_t ier_setting[IT8XXX2_IER_COUNT];
void ite_intc_save_and_disable_interrupts(void)
{
volatile uint8_t _ier __unused;
/* Disable global interrupt for critical section */
unsigned int key = irq_lock();
/* Save and disable interrupts */
for (int i = 0; i < IT8XXX2_IER_COUNT; i++) {
ier_setting[i] = *reg_enable[i];
*reg_enable[i] = 0;
}
/*
* This load operation will guarantee the above modification of
* SOC's register can be seen by any following instructions.
* Note: Barrier instruction can not synchronize chip register,
* so we introduce workaround here.
*/
_ier = *reg_enable[IT8XXX2_IER_COUNT - 1];
irq_unlock(key);
}
void ite_intc_restore_interrupts(void)
{
/*
* Ensure the highest priority interrupt will be the first fired
* interrupt when soc is ready to go.
*/
unsigned int key = irq_lock();
/* Restore interrupt state */
for (int i = 0; i < IT8XXX2_IER_COUNT; i++) {
*reg_enable[i] = ier_setting[i];
}
irq_unlock(key);
}
void ite_intc_isr_clear(unsigned int irq)
{
uint32_t g, i;
volatile uint8_t *isr;
if (irq > CONFIG_NUM_IRQS) {
return;
}
g = irq / MAX_REGISR_IRQ_NUM;
i = irq % MAX_REGISR_IRQ_NUM;
isr = reg_status[g];
*isr = BIT(i);
}
void __soc_ram_code ite_intc_irq_enable(unsigned int irq)
{
uint32_t g, i;
volatile uint8_t *en;
if (irq > CONFIG_NUM_IRQS) {
return;
}
g = irq / MAX_REGISR_IRQ_NUM;
i = irq % MAX_REGISR_IRQ_NUM;
en = reg_enable[g];
/* critical section due to run a bit-wise OR operation */
unsigned int key = irq_lock();
SET_MASK(*en, BIT(i));
irq_unlock(key);
}
void __soc_ram_code ite_intc_irq_disable(unsigned int irq)
{
uint32_t g, i;
volatile uint8_t *en;
volatile uint8_t _ier __unused;
if (irq > CONFIG_NUM_IRQS) {
return;
}
g = irq / MAX_REGISR_IRQ_NUM;
i = irq % MAX_REGISR_IRQ_NUM;
en = reg_enable[g];
/* critical section due to run a bit-wise OR operation */
unsigned int key = irq_lock();
CLEAR_MASK(*en, BIT(i));
/*
* This load operation will guarantee the above modification of
* SOC's register can be seen by any following instructions.
*/
_ier = *en;
irq_unlock(key);
}
void ite_intc_irq_polarity_set(unsigned int irq, unsigned int flags)
{
uint32_t g, i;
volatile uint8_t *tri;
if ((irq > CONFIG_NUM_IRQS) || ((flags&IRQ_TYPE_EDGE_BOTH) == IRQ_TYPE_EDGE_BOTH)) {
return;
}
g = irq / MAX_REGISR_IRQ_NUM;
i = irq % MAX_REGISR_IRQ_NUM;
tri = reg_ipolr[g];
if ((flags&IRQ_TYPE_LEVEL_HIGH) || (flags&IRQ_TYPE_EDGE_RISING)) {
CLEAR_MASK(*tri, BIT(i));
} else {
SET_MASK(*tri, BIT(i));
}
tri = reg_ielmr[g];
if ((flags&IRQ_TYPE_LEVEL_LOW) || (flags&IRQ_TYPE_LEVEL_HIGH)) {
CLEAR_MASK(*tri, BIT(i));
} else {
SET_MASK(*tri, BIT(i));
}
}
int __soc_ram_code ite_intc_irq_is_enable(unsigned int irq)
{
uint32_t g, i;
volatile uint8_t *en;
if (irq > CONFIG_NUM_IRQS) {
return 0;
}
g = irq / MAX_REGISR_IRQ_NUM;
i = irq % MAX_REGISR_IRQ_NUM;
en = reg_enable[g];
return IS_MASK_SET(*en, BIT(i));
}
uint8_t __soc_ram_code ite_intc_get_irq_num(void)
{
return intc_irq;
}
bool __soc_ram_code ite_intc_no_irq(void)
{
return (IVECT == IVECT_OFFSET_WITH_IRQ);
}
uint8_t __soc_ram_code get_irq(void *arg)
{
ARG_UNUSED(arg);
/* wait until two equal interrupt values are read */
do {
/* Read interrupt number from interrupt vector register */
intc_irq = IVECT;
/*
* WORKAROUND: when the interrupt vector register (IVECT)
* isn't latched in a load operation, we read it again to make
* sure the value we got is the correct value.
*/
} while (intc_irq != IVECT);
/* determine interrupt number */
intc_irq -= IVECT_OFFSET_WITH_IRQ;
/*
* Look for pending interrupt if there's interrupt number 0 from
* the AIVECT register.
*/
if (intc_irq == 0) {
uint8_t int_pending;
for (int i = (IT8XXX2_IER_COUNT - 1); i >= 0; i--) {
int_pending = (*reg_status[i] & *reg_enable[i]);
if (int_pending != 0) {
intc_irq = (MAX_REGISR_IRQ_NUM * i) +
find_msb_set(int_pending) - 1;
LOG_DBG("Pending interrupt found: %d",
intc_irq);
LOG_DBG("CPU mepc: 0x%lx", csr_read(mepc));
break;
}
}
}
/* clear interrupt status */
ite_intc_isr_clear(intc_irq);
/* return interrupt number */
return intc_irq;
}
void ite_intc_init(void)
{
/* Ensure interrupts of soc are disabled at default */
for (int i = 0; i < ARRAY_SIZE(reg_enable); i++)
*reg_enable[i] = 0;
/* Enable M-mode external interrupt */
csr_set(mie, MIP_MEIP);
}