/* * Copyright (c) 2006-2023, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2012-01-10 bernard porting to AM1808 * 2021-11-28 GuEe-GUI first version * 2022-12-10 WangXiaoyao porting to MM */ #define DBG_TAG "hw.mmu" #define DBG_LVL DBG_LOG #include #include #include #include #include #include #define __MMU_INTERNAL #include "mm_aspace.h" #include "mm_page.h" #include "mmu.h" #include "tlb.h" #include "ioremap.h" #ifdef RT_USING_SMART #include #endif #define TCR_CONFIG_TBI0 rt_hw_mmu_config_tbi(0) #define TCR_CONFIG_TBI1 rt_hw_mmu_config_tbi(1) #define MMU_LEVEL_MASK 0x1ffUL #define MMU_LEVEL_SHIFT 9 #define MMU_ADDRESS_BITS 39 #define MMU_ADDRESS_MASK 0x0000fffffffff000UL #define MMU_ATTRIB_MASK 0xfff0000000000ffcUL #define MMU_TYPE_MASK 3UL #define MMU_TYPE_USED 1UL #define MMU_TYPE_BLOCK 1UL #define MMU_TYPE_TABLE 3UL #define MMU_TYPE_PAGE 3UL #define MMU_TBL_BLOCK_2M_LEVEL 2 #define MMU_TBL_PAGE_4k_LEVEL 3 #define MMU_TBL_LEVEL_NR 4 /* restrict virtual address on usage of RT_NULL */ #ifndef KERNEL_VADDR_START #define KERNEL_VADDR_START 0x1000 #endif volatile unsigned long MMUTable[512] __attribute__((aligned(4 * 1024))); struct mmu_level_info { unsigned long *pos; void *page; }; static void _kenrel_unmap_4K(unsigned long *lv0_tbl, void *v_addr) { int level; unsigned long va = (unsigned long)v_addr; unsigned long *cur_lv_tbl = lv0_tbl; unsigned long page; unsigned long off; struct mmu_level_info level_info[4]; int ref; int level_shift = MMU_ADDRESS_BITS; unsigned long *pos; rt_memset(level_info, 0, sizeof level_info); for (level = 0; level < MMU_TBL_LEVEL_NR; level++) { off = (va >> level_shift); off &= MMU_LEVEL_MASK; page = cur_lv_tbl[off]; if (!(page & MMU_TYPE_USED)) { break; } if ((page & MMU_TYPE_MASK) == MMU_TYPE_BLOCK) { break; } /* next table entry in current level */ level_info[level].pos = cur_lv_tbl + off; cur_lv_tbl = (unsigned long *)(page & MMU_ADDRESS_MASK); cur_lv_tbl = (unsigned long *)((unsigned long)cur_lv_tbl - PV_OFFSET); level_info[level].page = cur_lv_tbl; level_shift -= MMU_LEVEL_SHIFT; } level = MMU_TBL_PAGE_4k_LEVEL; pos = level_info[level].pos; if (pos) { *pos = (unsigned long)RT_NULL; rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, pos, sizeof(void *)); } level--; while (level >= 0) { pos = level_info[level].pos; if (pos) { void *cur_page = level_info[level].page; ref = rt_page_ref_get(cur_page, 0); if (ref == 1) { *pos = (unsigned long)RT_NULL; rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, pos, sizeof(void *)); } rt_pages_free(cur_page, 0); } else { break; } level--; } return; } static int _kernel_map_4K(unsigned long *lv0_tbl, void *vaddr, void *paddr, unsigned long attr) { int ret = 0; int level; unsigned long *cur_lv_tbl = lv0_tbl; unsigned long page; unsigned long off; intptr_t va = (intptr_t)vaddr; intptr_t pa = (intptr_t)paddr; int level_shift = MMU_ADDRESS_BITS; if (va & ARCH_PAGE_MASK) { return MMU_MAP_ERROR_VANOTALIGN; } if (pa & ARCH_PAGE_MASK) { return MMU_MAP_ERROR_PANOTALIGN; } for (level = 0; level < MMU_TBL_PAGE_4k_LEVEL; level++) { off = (va >> level_shift); off &= MMU_LEVEL_MASK; if (!(cur_lv_tbl[off] & MMU_TYPE_USED)) { page = (unsigned long)rt_pages_alloc_ext(0, PAGE_ANY_AVAILABLE); if (!page) { ret = MMU_MAP_ERROR_NOPAGE; goto err; } rt_memset((void *)page, 0, ARCH_PAGE_SIZE); rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, (void *)page, ARCH_PAGE_SIZE); cur_lv_tbl[off] = (page + PV_OFFSET) | MMU_TYPE_TABLE; rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, cur_lv_tbl + off, sizeof(void *)); } else { page = cur_lv_tbl[off]; page &= MMU_ADDRESS_MASK; /* page to va */ page -= PV_OFFSET; rt_page_ref_inc((void *)page, 0); } page = cur_lv_tbl[off]; if ((page & MMU_TYPE_MASK) == MMU_TYPE_BLOCK) { /* is block! error! */ ret = MMU_MAP_ERROR_CONFLICT; goto err; } cur_lv_tbl = (unsigned long *)(page & MMU_ADDRESS_MASK); cur_lv_tbl = (unsigned long *)((unsigned long)cur_lv_tbl - PV_OFFSET); level_shift -= MMU_LEVEL_SHIFT; } /* now is level page */ attr &= MMU_ATTRIB_MASK; pa |= (attr | MMU_TYPE_PAGE); /* page */ off = (va >> ARCH_PAGE_SHIFT); off &= MMU_LEVEL_MASK; cur_lv_tbl[off] = pa; /* page */ rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, cur_lv_tbl + off, sizeof(void *)); return ret; err: _kenrel_unmap_4K(lv0_tbl, (void *)va); return ret; } static int _kernel_map_2M(unsigned long *lv0_tbl, void *vaddr, void *paddr, unsigned long attr) { int ret = 0; int level; unsigned long *cur_lv_tbl = lv0_tbl; unsigned long page; unsigned long off; unsigned long va = (unsigned long)vaddr; unsigned long pa = (unsigned long)paddr; int level_shift = MMU_ADDRESS_BITS; if (va & ARCH_SECTION_MASK) { return MMU_MAP_ERROR_VANOTALIGN; } if (pa & ARCH_PAGE_MASK) { return MMU_MAP_ERROR_PANOTALIGN; } for (level = 0; level < MMU_TBL_BLOCK_2M_LEVEL; level++) { off = (va >> level_shift); off &= MMU_LEVEL_MASK; if (!(cur_lv_tbl[off] & MMU_TYPE_USED)) { page = (unsigned long)rt_pages_alloc_ext(0, PAGE_ANY_AVAILABLE); if (!page) { ret = MMU_MAP_ERROR_NOPAGE; goto err; } rt_memset((char *)page, 0, ARCH_PAGE_SIZE); rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, (void *)page, ARCH_PAGE_SIZE); cur_lv_tbl[off] = (page + PV_OFFSET) | MMU_TYPE_TABLE; rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, cur_lv_tbl + off, sizeof(void *)); } else { page = cur_lv_tbl[off]; page &= MMU_ADDRESS_MASK; /* page to va */ page -= PV_OFFSET; rt_page_ref_inc((void *)page, 0); } page = cur_lv_tbl[off]; if ((page & MMU_TYPE_MASK) == MMU_TYPE_BLOCK) { /* is block! error! */ ret = MMU_MAP_ERROR_CONFLICT; goto err; } cur_lv_tbl = (unsigned long *)(page & MMU_ADDRESS_MASK); cur_lv_tbl = (unsigned long *)((unsigned long)cur_lv_tbl - PV_OFFSET); level_shift -= MMU_LEVEL_SHIFT; } /* now is level page */ attr &= MMU_ATTRIB_MASK; pa |= (attr | MMU_TYPE_BLOCK); /* block */ off = (va >> ARCH_SECTION_SHIFT); off &= MMU_LEVEL_MASK; cur_lv_tbl[off] = pa; rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, cur_lv_tbl + off, sizeof(void *)); return ret; err: _kenrel_unmap_4K(lv0_tbl, (void *)va); return ret; } void *rt_hw_mmu_map(rt_aspace_t aspace, void *v_addr, void *p_addr, size_t size, size_t attr) { int ret = -1; void *unmap_va = v_addr; size_t npages; size_t stride; int (*mapper)(unsigned long *lv0_tbl, void *vaddr, void *paddr, unsigned long attr); if (((rt_ubase_t)v_addr & ARCH_SECTION_MASK) || (size & ARCH_SECTION_MASK)) { /* legacy 4k mapping */ npages = size >> ARCH_PAGE_SHIFT; stride = ARCH_PAGE_SIZE; mapper = _kernel_map_4K; } else { /* 2m huge page */ npages = size >> ARCH_SECTION_SHIFT; stride = ARCH_SECTION_SIZE; mapper = _kernel_map_2M; } while (npages--) { MM_PGTBL_LOCK(aspace); ret = mapper(aspace->page_table, v_addr, p_addr, attr); MM_PGTBL_UNLOCK(aspace); if (ret != 0) { /* other types of return value are taken as programming error */ RT_ASSERT(ret == MMU_MAP_ERROR_NOPAGE); /* error, undo map */ while (unmap_va != v_addr) { MM_PGTBL_LOCK(aspace); _kenrel_unmap_4K(aspace->page_table, (void *)unmap_va); MM_PGTBL_UNLOCK(aspace); unmap_va = (char *)unmap_va + stride; } break; } v_addr = (char *)v_addr + stride; p_addr = (char *)p_addr + stride; } if (ret == 0) { return unmap_va; } return NULL; } void rt_hw_mmu_unmap(rt_aspace_t aspace, void *v_addr, size_t size) { // caller guarantee that v_addr & size are page aligned size_t npages = size >> ARCH_PAGE_SHIFT; if (!aspace->page_table) { return; } while (npages--) { MM_PGTBL_LOCK(aspace); if (rt_hw_mmu_v2p(aspace, v_addr) != ARCH_MAP_FAILED) _kenrel_unmap_4K(aspace->page_table, v_addr); MM_PGTBL_UNLOCK(aspace); v_addr = (char *)v_addr + ARCH_PAGE_SIZE; } } void rt_hw_aspace_switch(rt_aspace_t aspace) { if (aspace != &rt_kernel_space) { void *pgtbl = aspace->page_table; pgtbl = rt_kmem_v2p(pgtbl); rt_ubase_t tcr; __asm__ volatile("msr ttbr0_el1, %0" ::"r"(pgtbl) : "memory"); __asm__ volatile("mrs %0, tcr_el1" : "=r"(tcr)); tcr &= ~(1ul << 7); __asm__ volatile("msr tcr_el1, %0\n" "isb" ::"r"(tcr) : "memory"); rt_hw_tlb_invalidate_all_local(); } } void rt_hw_mmu_ktbl_set(unsigned long tbl) { #ifdef RT_USING_SMART tbl += PV_OFFSET; __asm__ volatile("msr TTBR1_EL1, %0\n dsb sy\nisb" ::"r"(tbl) : "memory"); #else __asm__ volatile("msr TTBR0_EL1, %0\n dsb sy\nisb" ::"r"(tbl) : "memory"); #endif __asm__ volatile("tlbi vmalle1\n dsb sy\nisb" ::: "memory"); __asm__ volatile("ic ialluis\n dsb sy\nisb" ::: "memory"); } /** * @brief setup Page Table for kernel space. It's a fixed map * and all mappings cannot be changed after initialization. * * Memory region in struct mem_desc must be page aligned, * otherwise is a failure and no report will be * returned. * * @param mmu_info * @param mdesc * @param desc_nr */ void rt_hw_mmu_setup(rt_aspace_t aspace, struct mem_desc *mdesc, int desc_nr) { void *err; for (size_t i = 0; i < desc_nr; i++) { size_t attr; switch (mdesc->attr) { case NORMAL_MEM: attr = MMU_MAP_K_RWCB; break; case NORMAL_NOCACHE_MEM: attr = MMU_MAP_K_RWCB; break; case DEVICE_MEM: attr = MMU_MAP_K_DEVICE; break; default: attr = MMU_MAP_K_DEVICE; } struct rt_mm_va_hint hint = {.flags = MMF_MAP_FIXED, .limit_start = aspace->start, .limit_range_size = aspace->size, .map_size = mdesc->vaddr_end - mdesc->vaddr_start + 1, .prefer = (void *)mdesc->vaddr_start}; if (mdesc->paddr_start == (rt_size_t)ARCH_MAP_FAILED) mdesc->paddr_start = mdesc->vaddr_start + PV_OFFSET; int retval; retval = rt_aspace_map_phy_static(aspace, &mdesc->varea, &hint, attr, mdesc->paddr_start >> MM_PAGE_SHIFT, &err); if (retval) { LOG_E("%s: map failed with code %d", retval); RT_ASSERT(0); } mdesc++; } rt_hw_mmu_ktbl_set((unsigned long)rt_kernel_space.page_table); rt_page_cleanup(); } static void _init_region(void *vaddr, size_t size) { rt_ioremap_start = vaddr; rt_ioremap_size = size; rt_mpr_start = (char *)rt_ioremap_start - rt_mpr_size; } /** * This function will initialize rt_mmu_info structure. * * @param mmu_info rt_mmu_info structure * @param v_address virtual address * @param size map size * @param vtable mmu table * @param pv_off pv offset in kernel space * * @return 0 on successful and -1 for fail */ int rt_hw_mmu_map_init(rt_aspace_t aspace, void *v_address, size_t size, size_t *vtable, size_t pv_off) { size_t va_s, va_e; if (!aspace || !vtable) { return -1; } va_s = (size_t)v_address; va_e = (size_t)v_address + size - 1; if (va_e < va_s) { return -1; } va_s >>= ARCH_SECTION_SHIFT; va_e >>= ARCH_SECTION_SHIFT; if (va_s == 0) { return -1; } rt_aspace_init(aspace, (void *)KERNEL_VADDR_START, 0 - KERNEL_VADDR_START, vtable); _init_region(v_address, size); return 0; } rt_weak long rt_hw_mmu_config_tbi(int tbi_index) { return 0; } /************ setting el1 mmu register************** MAIR_EL1 index 0 : memory outer writeback, write/read alloc index 1 : memory nocache index 2 : device nGnRnE *****************************************************/ void mmu_tcr_init(void) { unsigned long val64; unsigned long pa_range; val64 = 0x00447fUL; __asm__ volatile("msr MAIR_EL1, %0\n dsb sy\n" ::"r"(val64)); __asm__ volatile ("mrs %0, ID_AA64MMFR0_EL1":"=r"(val64)); pa_range = val64 & 0xf; /* PARange */ /* TCR_EL1 */ val64 = (16UL << 0) /* t0sz 48bit */ | (0x0UL << 6) /* reserved */ | (0x0UL << 7) /* epd0 */ | (0x3UL << 8) /* t0 wb cacheable */ | (0x3UL << 10) /* inner shareable */ | (0x2UL << 12) /* t0 outer shareable */ | (0x0UL << 14) /* t0 4K */ | (16UL << 16) /* t1sz 48bit */ | (0x0UL << 22) /* define asid use ttbr0.asid */ | (0x0UL << 23) /* epd1 */ | (0x3UL << 24) /* t1 inner wb cacheable */ | (0x3UL << 26) /* t1 outer wb cacheable */ | (0x2UL << 28) /* t1 outer shareable */ | (0x2UL << 30) /* t1 4k */ | (pa_range << 32) /* PA range */ | (0x0UL << 35) /* reserved */ | (0x1UL << 36) /* as: 0:8bit 1:16bit */ | (TCR_CONFIG_TBI0 << 37) /* tbi0 */ | (TCR_CONFIG_TBI1 << 38); /* tbi1 */ __asm__ volatile("msr TCR_EL1, %0\n" ::"r"(val64)); } struct page_table { unsigned long page[512]; }; /* */ static struct page_table* __init_page_array; static unsigned long __page_off = 0UL; unsigned long get_ttbrn_base(void) { return (unsigned long) __init_page_array; } void set_free_page(void *page_array) { __init_page_array = page_array; } unsigned long get_free_page(void) { return (unsigned long) (__init_page_array[__page_off++].page); } static int _map_single_page_2M(unsigned long *lv0_tbl, unsigned long va, unsigned long pa, unsigned long attr) { int level; unsigned long *cur_lv_tbl = lv0_tbl; unsigned long page; unsigned long off; int level_shift = MMU_ADDRESS_BITS; if (va & ARCH_SECTION_MASK) { return MMU_MAP_ERROR_VANOTALIGN; } if (pa & ARCH_PAGE_MASK) { return MMU_MAP_ERROR_PANOTALIGN; } for (level = 0; level < MMU_TBL_BLOCK_2M_LEVEL; level++) { off = (va >> level_shift); off &= MMU_LEVEL_MASK; if (!(cur_lv_tbl[off] & MMU_TYPE_USED)) { page = get_free_page(); if (!page) { return MMU_MAP_ERROR_NOPAGE; } rt_memset((char *)page, 0, ARCH_PAGE_SIZE); cur_lv_tbl[off] = page | MMU_TYPE_TABLE; } page = cur_lv_tbl[off]; if ((page & MMU_TYPE_MASK) == MMU_TYPE_BLOCK) { /* is block! error! */ return MMU_MAP_ERROR_CONFLICT; } cur_lv_tbl = (unsigned long *)(page & MMU_ADDRESS_MASK); level_shift -= MMU_LEVEL_SHIFT; } attr &= MMU_ATTRIB_MASK; pa |= (attr | MMU_TYPE_BLOCK); /* block */ off = (va >> ARCH_SECTION_SHIFT); off &= MMU_LEVEL_MASK; cur_lv_tbl[off] = pa; return 0; } void *rt_hw_mmu_tbl_get(void) { uintptr_t tbl; __asm__ volatile("MRS %0, TTBR0_EL1" : "=r"(tbl)); return rt_kmem_p2v((void *)(tbl & ((1ul << 48) - 2))); } void *rt_ioremap_early(void *paddr, size_t size) { volatile size_t count; rt_ubase_t base; static void *tbl = RT_NULL; if (!size) { return RT_NULL; } if (!tbl) { tbl = rt_hw_mmu_tbl_get(); } /* get the total size required including overhead for alignment */ count = (size + ((rt_ubase_t)paddr & ARCH_SECTION_MASK) + ARCH_SECTION_MASK) >> ARCH_SECTION_SHIFT; base = (rt_ubase_t)paddr & (~ARCH_SECTION_MASK); while (count --> 0) { if (_map_single_page_2M(tbl, base, base, MMU_MAP_K_DEVICE)) { return RT_NULL; } base += ARCH_SECTION_SIZE; } return paddr; } static int _init_map_2M(unsigned long *lv0_tbl, unsigned long va, unsigned long pa, unsigned long count, unsigned long attr) { unsigned long i; int ret; if (va & ARCH_SECTION_MASK) { return -1; } if (pa & ARCH_SECTION_MASK) { return -1; } for (i = 0; i < count; i++) { ret = _map_single_page_2M(lv0_tbl, va, pa, attr); va += ARCH_SECTION_SIZE; pa += ARCH_SECTION_SIZE; if (ret != 0) { return ret; } } return 0; } static unsigned long *_query(rt_aspace_t aspace, void *vaddr, int *plvl_shf) { int level; unsigned long va = (unsigned long)vaddr; unsigned long *cur_lv_tbl; unsigned long page; unsigned long off; int level_shift = MMU_ADDRESS_BITS; cur_lv_tbl = aspace->page_table; RT_ASSERT(cur_lv_tbl); for (level = 0; level < MMU_TBL_PAGE_4k_LEVEL; level++) { off = (va >> level_shift); off &= MMU_LEVEL_MASK; if (!(cur_lv_tbl[off] & MMU_TYPE_USED)) { *plvl_shf = level_shift; return (void *)0; } page = cur_lv_tbl[off]; if ((page & MMU_TYPE_MASK) == MMU_TYPE_BLOCK) { *plvl_shf = level_shift; return &cur_lv_tbl[off]; } cur_lv_tbl = (unsigned long *)(page & MMU_ADDRESS_MASK); cur_lv_tbl = (unsigned long *)((unsigned long)cur_lv_tbl - PV_OFFSET); level_shift -= MMU_LEVEL_SHIFT; } /* now is level MMU_TBL_PAGE_4k_LEVEL */ off = (va >> ARCH_PAGE_SHIFT); off &= MMU_LEVEL_MASK; page = cur_lv_tbl[off]; *plvl_shf = level_shift; if (!(page & MMU_TYPE_USED)) { return (void *)0; } return &cur_lv_tbl[off]; } void *rt_hw_mmu_v2p(rt_aspace_t aspace, void *v_addr) { int level_shift; unsigned long paddr; if (aspace == &rt_kernel_space) { paddr = (unsigned long)rt_hw_mmu_kernel_v2p(v_addr); } else { unsigned long *pte = _query(aspace, v_addr, &level_shift); if (pte) { paddr = *pte & MMU_ADDRESS_MASK; paddr |= (rt_ubase_t)v_addr & ((1ul << level_shift) - 1); } else { paddr = (unsigned long)ARCH_MAP_FAILED; } } return (void *)paddr; } static int _noncache(rt_ubase_t *pte) { int err = 0; const rt_ubase_t idx_shift = 2; const rt_ubase_t idx_mask = 0x7 << idx_shift; rt_ubase_t entry = *pte; if ((entry & idx_mask) == (NORMAL_MEM << idx_shift)) { *pte = (entry & ~idx_mask) | (NORMAL_NOCACHE_MEM << idx_shift); } else { // do not support other type to be noncache err = -RT_ENOSYS; } return err; } static int _cache(rt_ubase_t *pte) { int err = 0; const rt_ubase_t idx_shift = 2; const rt_ubase_t idx_mask = 0x7 << idx_shift; rt_ubase_t entry = *pte; if ((entry & idx_mask) == (NORMAL_NOCACHE_MEM << idx_shift)) { *pte = (entry & ~idx_mask) | (NORMAL_MEM << idx_shift); } else { // do not support other type to be cache err = -RT_ENOSYS; } return err; } static int (*control_handler[MMU_CNTL_DUMMY_END])(rt_ubase_t *pte) = { [MMU_CNTL_CACHE] = _cache, [MMU_CNTL_NONCACHE] = _noncache, }; int rt_hw_mmu_control(struct rt_aspace *aspace, void *vaddr, size_t size, enum rt_mmu_cntl cmd) { int level_shift; int err = -RT_EINVAL; rt_ubase_t vstart = (rt_ubase_t)vaddr; rt_ubase_t vend = vstart + size; int (*handler)(rt_ubase_t * pte); if (cmd >= 0 && cmd < MMU_CNTL_DUMMY_END) { handler = control_handler[cmd]; while (vstart < vend) { rt_ubase_t *pte = _query(aspace, (void *)vstart, &level_shift); rt_ubase_t range_end = vstart + (1ul << level_shift); RT_ASSERT(range_end <= vend); if (pte) { err = handler(pte); RT_ASSERT(err == RT_EOK); } vstart = range_end; } } else { err = -RT_ENOSYS; } return err; } void rt_hw_mem_setup_early(unsigned long *tbl0, unsigned long *tbl1, unsigned long size, unsigned long pv_off) { int ret; unsigned long count = (size + ARCH_SECTION_MASK) >> ARCH_SECTION_SHIFT; unsigned long normal_attr = MMU_MAP_CUSTOM(MMU_AP_KAUN, NORMAL_MEM); #ifdef RT_USING_SMART unsigned long va = KERNEL_VADDR_START; #else extern unsigned char _start; unsigned long va = (unsigned long) &_start; va = RT_ALIGN_DOWN(va, 0x200000); #endif /* setup pv off */ rt_kmem_pvoff_set(pv_off); /* clean the first two pages */ rt_memset((char *)tbl0, 0, ARCH_PAGE_SIZE); rt_memset((char *)tbl1, 0, ARCH_PAGE_SIZE); ret = _init_map_2M(tbl1, va, va + pv_off, count, normal_attr); if (ret != 0) { while (1); } ret = _init_map_2M(tbl0, va + pv_off, va + pv_off, count, normal_attr); if (ret != 0) { while (1); } } void *rt_hw_mmu_pgtbl_create(void) { size_t *mmu_table; mmu_table = (size_t *)rt_pages_alloc_ext(0, PAGE_ANY_AVAILABLE); if (!mmu_table) { return RT_NULL; } memset(mmu_table, 0, ARCH_PAGE_SIZE); rt_hw_cpu_dcache_ops(RT_HW_CACHE_FLUSH, mmu_table, ARCH_PAGE_SIZE); return mmu_table; } void rt_hw_mmu_pgtbl_delete(void *pgtbl) { rt_pages_free(pgtbl, 0); }