#include #include #include #include #include #include #include #define PT_SIZE ((uint64_t)0x1000) typedef uint64_t pt_entry_t; // Maps level indexes to the page size for that level. _Static_assert(VMM_MAX_LEVEL <= 5, "6-level paging not supported"); static uint64_t page_sizes[5] = { 0x1000, 0x200000, 0x40000000, 0x8000000000, 0x1000000000000, }; static pt_entry_t *get_next_level(pagemap_t pagemap, pt_entry_t *current_level, uint64_t virt, enum page_size desired_sz, size_t level_idx, size_t entry); #if defined (__x86_64__) || defined (__i386__) #define PT_FLAG_VALID ((uint64_t)1 << 0) #define PT_FLAG_WRITE ((uint64_t)1 << 1) #define PT_FLAG_USER ((uint64_t)1 << 2) #define PT_FLAG_LARGE ((uint64_t)1 << 7) #define PT_FLAG_NX ((uint64_t)1 << 63) #define PT_PADDR_MASK ((uint64_t)0x0000FFFFFFFFF000) #define PT_TABLE_FLAGS (PT_FLAG_VALID | PT_FLAG_WRITE | PT_FLAG_USER) #define PT_IS_TABLE(x) (((x) & (PT_FLAG_VALID | PT_FLAG_LARGE)) == PT_FLAG_VALID) #define PT_IS_LARGE(x) (((x) & (PT_FLAG_VALID | PT_FLAG_LARGE)) == (PT_FLAG_VALID | PT_FLAG_LARGE)) #define PT_TO_VMM_FLAGS(x) ((x) & (PT_FLAG_WRITE | PT_FLAG_NX)) #define pte_new(addr, flags) ((pt_entry_t)(addr) | (flags)) #define pte_addr(pte) ((pte) & PT_PADDR_MASK) pagemap_t new_pagemap(int paging_mode) { pagemap_t pagemap; pagemap.levels = paging_mode == PAGING_MODE_X86_64_5LVL ? 5 : 4; pagemap.top_level = ext_mem_alloc(PT_SIZE); return pagemap; } static bool is_1gib_page_supported(void) { // Cache the cpuid result :^) static bool CACHE_INIT = false; static bool CACHE = false; if (!CACHE_INIT) { // Check if 1GiB pages are supported: uint32_t eax, ebx, ecx, edx; CACHE = cpuid(0x80000001, 0, &eax, &ebx, &ecx, &edx) && ((edx & 1 << 26) == 1 << 26); CACHE_INIT = true; printv("paging: 1GiB pages are %s!\n", CACHE ? "supported" : "not supported"); } return CACHE; } void map_page(pagemap_t pagemap, uint64_t virt_addr, uint64_t phys_addr, uint64_t flags, enum page_size pg_size) { // Calculate the indices in the various tables using the virtual address size_t pml5_entry = (virt_addr & ((uint64_t)0x1ff << 48)) >> 48; size_t pml4_entry = (virt_addr & ((uint64_t)0x1ff << 39)) >> 39; size_t pml3_entry = (virt_addr & ((uint64_t)0x1ff << 30)) >> 30; size_t pml2_entry = (virt_addr & ((uint64_t)0x1ff << 21)) >> 21; size_t pml1_entry = (virt_addr & ((uint64_t)0x1ff << 12)) >> 12; pt_entry_t *pml5, *pml4, *pml3, *pml2, *pml1; flags |= PT_FLAG_VALID; // Always present // Paging levels switch (pagemap.levels) { case 5: pml5 = pagemap.top_level; goto level5; case 4: pml4 = pagemap.top_level; goto level4; default: __builtin_unreachable(); } level5: pml4 = get_next_level(pagemap, pml5, virt_addr, pg_size, 4, pml5_entry); level4: pml3 = get_next_level(pagemap, pml4, virt_addr, pg_size, 3, pml4_entry); if (pg_size == Size1GiB) { // Check if 1GiB pages are avaliable. if (is_1gib_page_supported()) { pml3[pml3_entry] = (pt_entry_t)(phys_addr | flags | PT_FLAG_LARGE); } else { // If 1GiB pages are not supported then emulate it by splitting them into // 2MiB pages. for (uint64_t i = 0; i < 0x40000000; i += 0x200000) { map_page(pagemap, virt_addr + i, phys_addr + i, flags, Size2MiB); } } return; } pml2 = get_next_level(pagemap, pml3, virt_addr, pg_size, 2, pml3_entry); if (pg_size == Size2MiB) { pml2[pml2_entry] = (pt_entry_t)(phys_addr | flags | PT_FLAG_LARGE); return; } pml1 = get_next_level(pagemap, pml2, virt_addr, pg_size, 1, pml2_entry); pml1[pml1_entry] = (pt_entry_t)(phys_addr | flags); } #elif defined (__aarch64__) // Here we operate under the assumption that 4K pages are supported by the CPU. // This appears to be guaranteed by UEFI, as section 2.3.6 "AArch64 Platforms" // states that the primary processor core configuration includes 4K translation // granules (TCR_EL1.TG0 = 0). // Support for 4K pages also implies 2M, 1G and 512G blocks. // Sanity check that 4K pages are supported. void vmm_assert_4k_pages(void) { uint64_t aa64mmfr0; asm volatile ("mrs %0, id_aa64mmfr0_el1" : "=r"(aa64mmfr0)); if (((aa64mmfr0 >> 28) & 0b1111) == 0b1111) { panic(false, "vmm: CPU does not support 4K pages, please make a bug report about this."); } } #define PT_FLAG_VALID ((uint64_t)1 << 0) #define PT_FLAG_TABLE ((uint64_t)1 << 1) #define PT_FLAG_4K_PAGE ((uint64_t)1 << 1) #define PT_FLAG_BLOCK ((uint64_t)0 << 1) #define PT_FLAG_USER ((uint64_t)1 << 6) #define PT_FLAG_READONLY ((uint64_t)1 << 7) #define PT_FLAG_INNER_SH ((uint64_t)3 << 8) #define PT_FLAG_ACCESS ((uint64_t)1 << 10) #define PT_FLAG_XN ((uint64_t)1 << 54) #define PT_FLAG_WB ((uint64_t)0 << 2) #define PT_FLAG_FB ((uint64_t)1 << 2) #define PT_PADDR_MASK ((uint64_t)0x0000FFFFFFFFF000) #define PT_TABLE_FLAGS (PT_FLAG_VALID | PT_FLAG_TABLE) #define PT_IS_TABLE(x) (((x) & (PT_FLAG_VALID | PT_FLAG_TABLE)) == (PT_FLAG_VALID | PT_FLAG_TABLE)) #define PT_IS_LARGE(x) (((x) & (PT_FLAG_VALID | PT_FLAG_TABLE)) == PT_FLAG_VALID) #define PT_TO_VMM_FLAGS(x) (pt_to_vmm_flags_internal(x)) #define pte_new(addr, flags) ((pt_entry_t)(addr) | (flags)) #define pte_addr(pte) ((pte) & PT_PADDR_MASK) static uint64_t pt_to_vmm_flags_internal(pt_entry_t entry) { uint64_t flags = 0; if (!(entry & PT_FLAG_READONLY)) flags |= VMM_FLAG_WRITE; if (entry & PT_FLAG_XN) flags |= VMM_FLAG_NOEXEC; if (entry & PT_FLAG_FB) flags |= VMM_FLAG_FB; return flags; } pagemap_t new_pagemap(int paging_mode) { pagemap_t pagemap; pagemap.levels = paging_mode == PAGING_MODE_AARCH64_5LVL ? 5 : 4; pagemap.top_level[0] = ext_mem_alloc(PT_SIZE); pagemap.top_level[1] = ext_mem_alloc(PT_SIZE); return pagemap; } void map_page(pagemap_t pagemap, uint64_t virt_addr, uint64_t phys_addr, uint64_t flags, enum page_size pg_size) { // Calculate the indices in the various tables using the virtual address size_t pml5_entry = (virt_addr & ((uint64_t)0xf << 48)) >> 48; size_t pml4_entry = (virt_addr & ((uint64_t)0x1ff << 39)) >> 39; size_t pml3_entry = (virt_addr & ((uint64_t)0x1ff << 30)) >> 30; size_t pml2_entry = (virt_addr & ((uint64_t)0x1ff << 21)) >> 21; size_t pml1_entry = (virt_addr & ((uint64_t)0x1ff << 12)) >> 12; pt_entry_t *pml5, *pml4, *pml3, *pml2, *pml1; bool is_higher_half = virt_addr & ((uint64_t)1 << 63); uint64_t real_flags = PT_FLAG_VALID | PT_FLAG_INNER_SH | PT_FLAG_ACCESS | PT_FLAG_WB; if (!(flags & VMM_FLAG_WRITE)) real_flags |= PT_FLAG_READONLY; if (flags & VMM_FLAG_NOEXEC) real_flags |= PT_FLAG_XN; if (flags & VMM_FLAG_FB) real_flags |= PT_FLAG_FB; // Paging levels switch (pagemap.levels) { case 5: pml5 = pagemap.top_level[is_higher_half]; goto level5; case 4: pml4 = pagemap.top_level[is_higher_half]; goto level4; default: __builtin_unreachable(); } level5: pml4 = get_next_level(pagemap, pml5, virt_addr, pg_size, 4, pml5_entry); level4: pml3 = get_next_level(pagemap, pml4, virt_addr, pg_size, 3, pml4_entry); if (pg_size == Size1GiB) { pml3[pml3_entry] = (pt_entry_t)(phys_addr | real_flags | PT_FLAG_BLOCK); return; } pml2 = get_next_level(pagemap, pml3, virt_addr, pg_size, 2, pml3_entry); if (pg_size == Size2MiB) { pml2[pml2_entry] = (pt_entry_t)(phys_addr | real_flags | PT_FLAG_BLOCK); return; } pml1 = get_next_level(pagemap, pml2, virt_addr, pg_size, 1, pml2_entry); pml1[pml1_entry] = (pt_entry_t)(phys_addr | real_flags | PT_FLAG_4K_PAGE); } #elif defined (__riscv64) #define PT_FLAG_VALID ((uint64_t)1 << 0) #define PT_FLAG_READ ((uint64_t)1 << 1) #define PT_FLAG_WRITE ((uint64_t)1 << 2) #define PT_FLAG_EXEC ((uint64_t)1 << 3) #define PT_FLAG_USER ((uint64_t)1 << 4) #define PT_FLAG_ACCESSED ((uint64_t)1 << 6) #define PT_FLAG_DIRTY ((uint64_t)1 << 7) #define PT_PADDR_MASK ((uint64_t)0x003ffffffffffc00) #define PT_FLAG_RWX (PT_FLAG_READ | PT_FLAG_WRITE | PT_FLAG_EXEC) #define PT_TABLE_FLAGS PT_FLAG_VALID #define PT_IS_TABLE(x) (((x) & (PT_FLAG_VALID | PT_FLAG_RWX)) == PT_FLAG_VALID) #define PT_IS_LARGE(x) (((x) & (PT_FLAG_VALID | PT_FLAG_RWX)) > PT_FLAG_VALID) #define PT_TO_VMM_FLAGS(x) (pt_to_vmm_flags_internal(x)) #define pte_new(addr, flags) (((pt_entry_t)(addr) >> 2) | (flags)) #define pte_addr(pte) (((pte) & PT_PADDR_MASK) << 2) static uint64_t pt_to_vmm_flags_internal(pt_entry_t entry) { uint64_t flags = 0; if (entry & PT_FLAG_WRITE) flags |= VMM_FLAG_WRITE; if (!(entry & PT_FLAG_EXEC)) flags |= VMM_FLAG_NOEXEC; return flags; } uint64_t paging_mode_higher_half(int paging_mode) { switch (paging_mode) { case PAGING_MODE_RISCV_SV39: return 0xffffffc000000000; case PAGING_MODE_RISCV_SV48: return 0xffff800000000000; case PAGING_MODE_RISCV_SV57: return 0xff00000000000000; default: panic(false, "paging_mode_higher_half: invalid mode"); } } int paging_mode_va_bits(int paging_mode) { switch (paging_mode) { case PAGING_MODE_RISCV_SV39: return 39; case PAGING_MODE_RISCV_SV48: return 48; case PAGING_MODE_RISCV_SV57: return 57; default: panic(false, "paging_mode_va_bits: invalid mode"); } } int vmm_max_paging_mode(void) { static int max_level; if (max_level > 0) goto done; pt_entry_t *table = ext_mem_alloc(PT_SIZE); // Test each paging mode starting with Sv57. // Since writes to `satp` with an invalid MODE have no effect, and pages can be mapped at // any level, we can identity map the entire lower half (very likely guaranteeing everything // this code needs will be mapped) and check if enabling the paging mode succeeds. int lvl = 4; for (; lvl >= 2; lvl--) { pt_entry_t entry = PT_FLAG_ACCESSED | PT_FLAG_DIRTY | PT_FLAG_RWX | PT_FLAG_VALID; for (int i = 0; i < 256; i++) { table[i] = entry; entry += page_sizes[lvl] >> 2; } uint64_t satp = ((uint64_t)(6 + lvl) << 60) | ((uint64_t)table >> 12); csr_write("satp", satp); if (csr_read("satp") == satp) { max_level = lvl; break; } } csr_write("satp", 0); pmm_free(table, PT_SIZE); if (max_level == 0) panic(false, "vmm: paging is not supported"); done: return 6 + max_level; } pagemap_t new_pagemap(int paging_mode) { pagemap_t pagemap; pagemap.paging_mode = paging_mode; pagemap.max_page_size = paging_mode - 6; pagemap.top_level = ext_mem_alloc(PT_SIZE); return pagemap; } void map_page(pagemap_t pagemap, uint64_t virt_addr, uint64_t phys_addr, uint64_t flags, enum page_size page_size) { // Truncate the requested page size to the maximum supported. if (page_size > pagemap.max_page_size) page_size = pagemap.max_page_size; // Convert VMM_FLAG_* into PT_FLAG_*. // Set the ACCESSED and DIRTY flags to avoid faults. pt_entry_t ptflags = PT_FLAG_VALID | PT_FLAG_READ | PT_FLAG_ACCESSED | PT_FLAG_DIRTY; if (flags & VMM_FLAG_WRITE) ptflags |= PT_FLAG_WRITE; if (!(flags & VMM_FLAG_NOEXEC)) ptflags |= PT_FLAG_EXEC; // Start at the highest level. // The values of `enum page_size` map to the level index at which that size is mapped. int level = pagemap.max_page_size; pt_entry_t *table = pagemap.top_level; for (;;) { int index = (virt_addr >> (12 + 9 * level)) & 0x1ff; // Stop when we reach the level for the requested page size. if (level == (int)page_size) { table[index] = pte_new(phys_addr, ptflags); break; } table = get_next_level(pagemap, table, virt_addr, page_size, level, index); level--; } } #else #error Unknown architecture #endif static pt_entry_t *get_next_level(pagemap_t pagemap, pt_entry_t *current_level, uint64_t virt, enum page_size desired_sz, size_t level_idx, size_t entry) { pt_entry_t *ret; if (PT_IS_TABLE(current_level[entry])) { ret = (pt_entry_t *)(size_t)pte_addr(current_level[entry]); } else { if (PT_IS_LARGE(current_level[entry])) { // We are replacing an existing large page with a smaller page. // Split the previous mapping into mappings of the newly requested size // before performing the requested map operation. if ((level_idx >= VMM_MAX_LEVEL) || (level_idx == 0)) panic(false, "Unexpected level in get_next_level"); if (desired_sz >= VMM_MAX_LEVEL) panic(false, "Unexpected page size in get_next_level"); uint64_t old_page_size = page_sizes[level_idx]; uint64_t new_page_size = page_sizes[desired_sz]; // Save all the information from the old entry at this level uint64_t old_flags = PT_TO_VMM_FLAGS(current_level[entry]); uint64_t old_phys = pte_addr(current_level[entry]); uint64_t old_virt = virt & ~(old_page_size - 1); if (old_phys & (old_page_size - 1)) panic(false, "Unexpected page table entry address in get_next_level"); // Allocate a table for the next level ret = ext_mem_alloc(PT_SIZE); current_level[entry] = pte_new((size_t)ret, PT_TABLE_FLAGS); // Recreate the old mapping with smaller pages for (uint64_t i = 0; i < old_page_size; i += new_page_size) { map_page(pagemap, old_virt + i, old_phys + i, old_flags, desired_sz); } } else { // Allocate a table for the next level ret = ext_mem_alloc(PT_SIZE); current_level[entry] = pte_new((size_t)ret, PT_TABLE_FLAGS); } } return ret; }