rt-thread-official/bsp/gd32vf103v-eval/libraries/n22/drivers/n22_func.c

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2019-07-24 17:03:26 +08:00
// See LICENSE for license details.
#include <gd32vf103.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "riscv_encoding.h"
#include "n22_func.h"
void switch_m2u_mode() {
clear_csr(mstatus, MSTATUS_MPP);
//printf("\nIn the m2u function, the mstatus is 0x%x\n", read_csr(mstatus));
//printf("\nIn the m2u function, the mepc is 0x%x\n", read_csr(mepc));
asm volatile ("la x6, 1f ":::"x6");
asm volatile ("csrw mepc, x6":::);
asm volatile ("mret":::);
asm volatile ("1:":::);
}
uint32_t mtime_lo(void) {
return *(volatile uint32_t *) (TMR_CTRL_ADDR + TMR_MTIME);
}
uint32_t mtime_hi(void) {
return *(volatile uint32_t *) (TMR_CTRL_ADDR + TMR_MTIME + 4);
}
void enable_timer_interrupt(void) {
*(volatile uint32_t *) (TMR_CTRL_ADDR + TMR_MTIME + 0xffc) = 1;
}
void clear_timer_interrupt(void) {
*(volatile uint32_t *) (TMR_CTRL_ADDR + TMR_MTIME + 0xffc) = 0;
}
void close_timer(void) {
*(volatile uint32_t *) (TMR_CTRL_ADDR + TMR_MTIME + 0xff8) = 1;
}
void open_timer(void) {
*(volatile uint32_t *) (TMR_CTRL_ADDR + TMR_MTIME + 0xff8) = 0;
}
uint64_t get_timer_value() {
while (1) {
uint32_t hi = mtime_hi();
uint32_t lo = mtime_lo();
if (hi == mtime_hi())
return ((uint64_t) hi << 32) | lo;
}
}
uint32_t get_timer_freq() {
return TMR_FREQ;
}
uint64_t get_instret_value() {
while (1) {
uint32_t hi = read_csr(minstreth);
uint32_t lo = read_csr(minstret);
if (hi == read_csr(minstreth))
return ((uint64_t) hi << 32) | lo;
}
}
uint64_t get_cycle_value() {
while (1) {
uint32_t hi = read_csr(mcycleh);
uint32_t lo = read_csr(mcycle);
if (hi == read_csr(mcycleh))
return ((uint64_t) hi << 32) | lo;
}
}
// Note that there are no assertions or bounds checking on these
// parameter values.
void eclic_init(uint32_t num_irq) {
typedef volatile uint32_t vuint32_t;
//clear cfg register
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_CFG_OFFSET) = 0;
//clear minthresh register
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_MTH_OFFSET) = 0;
//clear all IP/IE/ATTR/CTRL bits for all interrupt sources
vuint32_t * ptr;
vuint32_t * base = (vuint32_t*) (ECLIC_ADDR_BASE + ECLIC_INT_IP_OFFSET);
vuint32_t * upper = (vuint32_t*) (base + num_irq * 4);
for (ptr = base; ptr < upper; ptr = ptr + 4) {
*ptr = 0;
}
eclic_set_nlbits(ECLIC_GROUP_LEVEL2_PRIO2);
}
void eclic_enable_interrupt(uint32_t source) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_IE_OFFSET + source * 4) =
1;
}
void eclic_disable_interrupt(uint32_t source) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_IE_OFFSET + source * 4) =
0;
}
void eclic_set_pending(uint32_t source) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_IP_OFFSET + source * 4) =
1;
}
void eclic_clear_pending(uint32_t source) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_IP_OFFSET + source * 4) =
0;
}
void eclic_set_intctrl(uint32_t source, uint8_t intctrl) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_CTRL_OFFSET + source * 4) =
intctrl;
}
uint8_t eclic_get_intctrl(uint32_t source) {
return *(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_CTRL_OFFSET
+ source * 4);
}
void eclic_set_intattr(uint32_t source, uint8_t intattr) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_ATTR_OFFSET + source * 4) =
intattr;
}
uint8_t eclic_get_intattr(uint32_t source) {
return *(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_INT_ATTR_OFFSET
+ source * 4);
}
void eclic_set_ecliccfg(uint8_t ecliccfg) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_CFG_OFFSET) = ecliccfg;
}
uint8_t eclic_get_ecliccfg() {
return *(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_CFG_OFFSET);
}
void eclic_set_mth(uint8_t mth) {
*(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_MTH_OFFSET) = mth;
}
uint8_t eclic_get_mth() {
return *(volatile uint8_t*) (ECLIC_ADDR_BASE + ECLIC_MTH_OFFSET);
}
void eclic_set_nlbits(uint8_t nlbits) {
//shift nlbits to correct position
uint8_t nlbits_shifted = nlbits << ECLIC_CFG_NLBITS_LSB;
//read the current ecliccfg
uint8_t old_ecliccfg = eclic_get_ecliccfg();
uint8_t new_ecliccfg = (old_ecliccfg & (~ECLIC_CFG_NLBITS_MASK))
| (ECLIC_CFG_NLBITS_MASK & nlbits_shifted);
eclic_set_ecliccfg(new_ecliccfg);
}
uint8_t eclic_get_nlbits(void) {
//extract nlbits
uint8_t nlbits = eclic_get_ecliccfg();
nlbits = (nlbits & ECLIC_CFG_NLBITS_MASK) >> ECLIC_CFG_NLBITS_LSB;
return nlbits;
}
//sets an interrupt level based encoding of nlbits and ECLICINTCTLBITS
uint8_t eclic_set_int_level(uint32_t source, uint8_t level) {
//extract nlbits
uint8_t nlbits = eclic_get_nlbits();
if (nlbits > ECLICINTCTLBITS) {
nlbits = ECLICINTCTLBITS;
}
//shift level into correct bit position
level = level << (8 - nlbits);
//write to eclicintctrl
uint8_t current_intctrl = eclic_get_intctrl(source);
//shift intctrl left to mask off unused bits
current_intctrl = current_intctrl << nlbits;
//shift intctrl into correct bit position
current_intctrl = current_intctrl >> nlbits;
eclic_set_intctrl(source, (current_intctrl | level));
return level;
}
//gets an interrupt level based encoding of nlbits
uint8_t eclic_get_int_level(uint32_t source) {
//extract nlbits
uint8_t nlbits = eclic_get_nlbits();
if (nlbits > ECLICINTCTLBITS) {
nlbits = ECLICINTCTLBITS;
}
uint8_t intctrl = eclic_get_intctrl(source);
//shift intctrl
intctrl = intctrl >> (8 - nlbits);
//shift intctrl
uint8_t level = intctrl << (8 - nlbits);
return level;
}
//sets an interrupt priority based encoding of nlbits and ECLICINTCTLBITS
uint8_t eclic_set_int_priority(uint32_t source, uint8_t priority) {
//extract nlbits
uint8_t nlbits = eclic_get_nlbits();
if (nlbits >= ECLICINTCTLBITS) {
nlbits = ECLICINTCTLBITS;
return 0;
}
//shift priority into correct bit position
priority = priority << (8 - ECLICINTCTLBITS);
//write to eclicintctrl
uint8_t current_intctrl = eclic_get_intctrl(source);
//shift intctrl right to mask off unused bits
current_intctrl = current_intctrl >> (8 - nlbits);
//shift intctrl into correct bit position
current_intctrl = current_intctrl << (8 - nlbits);
eclic_set_intctrl(source, (current_intctrl | priority));
return priority;
}
//gets an interrupt priority based encoding of nlbits
uint8_t eclic_get_int_priority(uint32_t source) {
//extract nlbits
uint8_t nlbits = eclic_get_nlbits();
if (nlbits > ECLICINTCTLBITS) {
nlbits = ECLICINTCTLBITS;
}
uint8_t intctrl = eclic_get_intctrl(source);
//shift intctrl
intctrl = intctrl << nlbits;
//shift intctrl
uint8_t priority = intctrl >> (nlbits + (8 - ECLICINTCTLBITS));
return priority;
}
void eclic_mode_enable() {
uint32_t mtvec_value = read_csr(mtvec);
mtvec_value = mtvec_value & 0xFFFFFFC0;
mtvec_value = mtvec_value | 0x00000003;
write_csr(mtvec, mtvec_value);
}
void eclic_set_shv(uint32_t source, uint8_t shv) {
uint8_t attr = eclic_get_intattr(source);
if (shv) {
attr |= 0x01;
eclic_set_intattr(source, attr);
}
}
void eclic_set_trig(uint32_t source, uint8_t trig) {
uint8_t attr = eclic_get_intattr(source);
if ((trig & 0x1)) {
attr |= (trig << 1);
eclic_set_intattr(source, attr);
}
}