arch/mips/arch.c

/*
 * Copyright (c) 2015 Travis Geiselbrecht
 *
 * Use of this source code is governed by a MIT-style
 * license that can be found in the LICENSE file or at
 * https://opensource.org/licenses/MIT
 */
#include <lk/trace.h>
#include <lk/debug.h>
#include <stdint.h>
#include <lk/bits.h>
#include <arch.h>
#include <arch/mips.h>
#include <platform.h>

#define LOCAL_TRACE 0

void arch_early_init(void) {
    LTRACE;

    /* configure the vector table */
    uint32_t temp = mips_read_c0_status();
    temp &= ~(1<<22); /* unset BEV, which moves vectors to 0x80000000 */
    temp &= ~(1<<2);  /* clear ERL */

    /* mask all of the irq handlers */
    temp &= ~(1<<8); // IM0
    temp &= ~(1<<9); // IM1
    temp &= ~(1<<10); // IM2
    temp &= ~(1<<11); // IM3
    temp &= ~(1<<12); // IM4
    temp &= ~(1<<13); // IM5
    temp &= ~(1<<14); // IM6
    temp &= ~(1<<15); // IM7
    temp &= ~(1<<16); // IM8
    temp &= ~(1<<18); // IM9 (note the bit gap)

    mips_write_c0_status(temp);

    /* set ebase */
    mips_write_c0_ebase(MEMBASE);

    /* make sure we take exceptions in 32bit mips mode */
    mips_write_c0_config3(mips_read_c0_config3() & ~(1<<16));

    /* set vectored mode */
    temp = mips_read_c0_intctl();
    temp &= ~(0b1111 << 5);
    temp |= 1 << 5; /* 32 byte spacing */
    STATIC_ASSERT(VECTORED_OFFSET_SHIFT == 32);

    mips_write_c0_intctl(temp);

    temp = mips_read_c0_cause();
    temp |= (1<<23); /* IV vectored mode */
    mips_write_c0_cause(temp);
}

void arch_init(void) {
    LTRACE;

    printf("MIPS registers:\n");
    printf("\tPRId 0x%x\n", mips_read_c0_prid());
    printf("\tconfig  0x%x\n", mips_read_c0_config());
    printf("\tconfig1 0x%x\n", mips_read_c0_config1());
    printf("\tconfig2 0x%x\n", mips_read_c0_config2());
    printf("\tconfig3 0x%x\n", mips_read_c0_config3());
    printf("\tconfig4 0x%x\n", mips_read_c0_config4());
    printf("\tconfig5 0x%x\n", mips_read_c0_config5());
    printf("\tconfig6 0x%x\n", mips_read_c0_config6());
    printf("\tconfig7 0x%x\n", mips_read_c0_config7());
    printf("\tstatus  0x%x\n", mips_read_c0_status());
    uint32_t intctl = mips_read_c0_intctl();
    printf("\tintctl  0x%x\n", intctl);
    printf("\t\tIPTI  0x%lx\n", BITS_SHIFT(intctl, 31, 29));
    printf("\t\tIPPCI 0x%lx\n", BITS_SHIFT(intctl, 28, 26));
    printf("\t\tIPFDC 0x%lx\n", BITS_SHIFT(intctl, 25, 23));
    printf("\tsrsctl  0x%x\n", mips_read_c0_srsctl());
    printf("\tebase   0x%x\n", mips_read_c0_ebase());
    printf("\tcount   0x%x\n", mips_read_c0_count());
    printf("\tcompare 0x%x\n", mips_read_c0_compare());

    __asm__ volatile("syscall");

    LTRACE_EXIT;
}

void arch_idle(void) {
    asm volatile("wait");
}

void arch_chain_load(void *entry, ulong arg0, ulong arg1, ulong arg2, ulong arg3) {
    PANIC_UNIMPLEMENTED;
}

void mips_enable_irq(uint num) {
    uint32_t temp = mips_read_c0_status();
    if (num < 9) {
        temp |= (1 << (num + 8));
    } else if (num == 9) {
        temp |= (1 << 18);
    }
    mips_write_c0_status(temp);
}

void mips_disable_irq(uint num) {
    uint32_t temp = mips_read_c0_status();
    if (num < 9) {
        temp &= ~(1 << (num + 8));
    } else if (num == 9) {
        temp &= ~(1 << 18);
    }
    mips_write_c0_status(temp);
}

/* unimplemented cache operations */
void arch_disable_cache(uint flags) { PANIC_UNIMPLEMENTED; }
void arch_enable_cache(uint flags) { PANIC_UNIMPLEMENTED; }

void arch_clean_cache_range(addr_t start, size_t len) { PANIC_UNIMPLEMENTED; }
void arch_clean_invalidate_cache_range(addr_t start, size_t len) { PANIC_UNIMPLEMENTED; }
void arch_invalidate_cache_range(addr_t start, size_t len) { PANIC_UNIMPLEMENTED; }
void arch_sync_cache_range(addr_t start, size_t len) { PANIC_UNIMPLEMENTED; }