1 pub mod barrier; 2 3 use alloc::vec::Vec; 4 use hashbrown::HashSet; 5 use x86::time::rdtsc; 6 use x86_64::registers::model_specific::EferFlags; 7 8 use crate::driver::tty::serial::serial8250::send_to_default_serial8250_port; 9 use crate::include::bindings::bindings::{ 10 multiboot2_get_memory, multiboot2_iter, multiboot_mmap_entry_t, 11 }; 12 use crate::libs::align::page_align_up; 13 use crate::libs::lib_ui::screen_manager::scm_disable_put_to_window; 14 use crate::libs::printk::PrintkWriter; 15 use crate::libs::spinlock::SpinLock; 16 17 use crate::mm::allocator::page_frame::{FrameAllocator, PageFrameCount, PageFrameUsage}; 18 use crate::mm::mmio_buddy::mmio_init; 19 use crate::{ 20 arch::MMArch, 21 mm::allocator::{buddy::BuddyAllocator, bump::BumpAllocator}, 22 }; 23 24 use crate::mm::kernel_mapper::KernelMapper; 25 use crate::mm::page::{PageEntry, PageFlags}; 26 use crate::mm::{MemoryManagementArch, PageTableKind, PhysAddr, PhysMemoryArea, VirtAddr}; 27 use crate::syscall::SystemError; 28 use crate::{kdebug, kinfo}; 29 30 use core::arch::asm; 31 use core::ffi::c_void; 32 use core::fmt::{Debug, Write}; 33 use core::mem::{self}; 34 35 use core::sync::atomic::{compiler_fence, AtomicBool, Ordering}; 36 37 pub type PageMapper = 38 crate::mm::page::PageMapper<crate::arch::x86_64::mm::X86_64MMArch, LockedFrameAllocator>; 39 40 /// @brief 用于存储物理内存区域的数组 41 static mut PHYS_MEMORY_AREAS: [PhysMemoryArea; 512] = [PhysMemoryArea { 42 base: PhysAddr::new(0), 43 size: 0, 44 }; 512]; 45 46 /// 初始的CR3寄存器的值,用于内存管理初始化时,创建的第一个内核页表的位置 47 static mut INITIAL_CR3_VALUE: PhysAddr = PhysAddr::new(0); 48 49 /// 内核的第一个页表在pml4中的索引 50 /// 顶级页表的[256, 512)项是内核的页表 51 static KERNEL_PML4E_NO: usize = (X86_64MMArch::PHYS_OFFSET & ((1 << 48) - 1)) >> 39; 52 53 static INNER_ALLOCATOR: SpinLock<Option<BuddyAllocator<MMArch>>> = SpinLock::new(None); 54 55 #[derive(Clone, Copy)] 56 pub struct X86_64MMBootstrapInfo { 57 kernel_code_start: usize, 58 kernel_code_end: usize, 59 kernel_data_end: usize, 60 kernel_rodata_end: usize, 61 start_brk: usize, 62 } 63 64 impl Debug for X86_64MMBootstrapInfo { 65 fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { 66 write!( 67 f, 68 "kernel_code_start: {:x}, kernel_code_end: {:x}, kernel_data_end: {:x}, kernel_rodata_end: {:x}, start_brk: {:x}", 69 self.kernel_code_start, self.kernel_code_end, self.kernel_data_end, self.kernel_rodata_end, self.start_brk) 70 } 71 } 72 73 pub static mut BOOTSTRAP_MM_INFO: Option<X86_64MMBootstrapInfo> = None; 74 75 /// @brief X86_64的内存管理架构结构体 76 #[derive(Debug, Clone, Copy, Hash)] 77 pub struct X86_64MMArch; 78 79 /// XD标志位是否被保留 80 static XD_RESERVED: AtomicBool = AtomicBool::new(false); 81 82 impl MemoryManagementArch for X86_64MMArch { 83 /// 4K页 84 const PAGE_SHIFT: usize = 12; 85 86 /// 每个页表项占8字节,总共有512个页表项 87 const PAGE_ENTRY_SHIFT: usize = 9; 88 89 /// 四级页表(PML4T、PDPT、PDT、PT) 90 const PAGE_LEVELS: usize = 4; 91 92 /// 页表项的有效位的index。在x86_64中,页表项的第[0, 47]位表示地址和flag, 93 /// 第[48, 51]位表示保留。因此,有效位的index为52。 94 /// 请注意,第63位是XD位,表示是否允许执行。 95 const ENTRY_ADDRESS_SHIFT: usize = 52; 96 97 const ENTRY_FLAG_DEFAULT_PAGE: usize = Self::ENTRY_FLAG_PRESENT; 98 99 const ENTRY_FLAG_DEFAULT_TABLE: usize = Self::ENTRY_FLAG_PRESENT; 100 101 const ENTRY_FLAG_PRESENT: usize = 1 << 0; 102 103 const ENTRY_FLAG_READONLY: usize = 0; 104 105 const ENTRY_FLAG_READWRITE: usize = 1 << 1; 106 107 const ENTRY_FLAG_USER: usize = 1 << 2; 108 109 const ENTRY_FLAG_WRITE_THROUGH: usize = 1 << 3; 110 111 const ENTRY_FLAG_CACHE_DISABLE: usize = 1 << 4; 112 113 const ENTRY_FLAG_NO_EXEC: usize = 1 << 63; 114 /// x86_64不存在EXEC标志位,只有NO_EXEC(XD)标志位 115 const ENTRY_FLAG_EXEC: usize = 0; 116 117 /// 物理地址与虚拟地址的偏移量 118 /// 0xffff_8000_0000_0000 119 const PHYS_OFFSET: usize = Self::PAGE_NEGATIVE_MASK + (Self::PAGE_ADDRESS_SIZE >> 1); 120 121 const USER_END_VADDR: VirtAddr = VirtAddr::new(0x0000_7eff_ffff_ffff); 122 const USER_BRK_START: VirtAddr = VirtAddr::new(0x700000000000); 123 const USER_STACK_START: VirtAddr = VirtAddr::new(0x6ffff0a00000); 124 125 /// @brief 获取物理内存区域 126 unsafe fn init() -> &'static [crate::mm::PhysMemoryArea] { 127 extern "C" { 128 fn _text(); 129 fn _etext(); 130 fn _edata(); 131 fn _erodata(); 132 fn _end(); 133 } 134 135 Self::init_xd_rsvd(); 136 137 let bootstrap_info = X86_64MMBootstrapInfo { 138 kernel_code_start: _text as usize, 139 kernel_code_end: _etext as usize, 140 kernel_data_end: _edata as usize, 141 kernel_rodata_end: _erodata as usize, 142 start_brk: _end as usize, 143 }; 144 unsafe { 145 BOOTSTRAP_MM_INFO = Some(bootstrap_info); 146 } 147 148 // 初始化物理内存区域(从multiboot2中获取) 149 let areas_count = 150 Self::init_memory_area_from_multiboot2().expect("init memory area failed"); 151 send_to_default_serial8250_port("x86 64 init end\n\0".as_bytes()); 152 153 return &PHYS_MEMORY_AREAS[0..areas_count]; 154 } 155 156 /// @brief 刷新TLB中,关于指定虚拟地址的条目 157 unsafe fn invalidate_page(address: VirtAddr) { 158 compiler_fence(Ordering::SeqCst); 159 asm!("invlpg [{0}]", in(reg) address.data(), options(nostack, preserves_flags)); 160 compiler_fence(Ordering::SeqCst); 161 } 162 163 /// @brief 刷新TLB中,所有的条目 164 unsafe fn invalidate_all() { 165 compiler_fence(Ordering::SeqCst); 166 // 通过设置cr3寄存器,来刷新整个TLB 167 Self::set_table(PageTableKind::User, Self::table(PageTableKind::User)); 168 compiler_fence(Ordering::SeqCst); 169 } 170 171 /// @brief 获取顶级页表的物理地址 172 unsafe fn table(_table_kind: PageTableKind) -> PhysAddr { 173 let paddr: usize; 174 compiler_fence(Ordering::SeqCst); 175 asm!("mov {}, cr3", out(reg) paddr, options(nomem, nostack, preserves_flags)); 176 compiler_fence(Ordering::SeqCst); 177 return PhysAddr::new(paddr); 178 } 179 180 /// @brief 设置顶级页表的物理地址到处理器中 181 unsafe fn set_table(_table_kind: PageTableKind, table: PhysAddr) { 182 compiler_fence(Ordering::SeqCst); 183 asm!("mov cr3, {}", in(reg) table.data(), options(nostack, preserves_flags)); 184 compiler_fence(Ordering::SeqCst); 185 } 186 187 /// @brief 判断虚拟地址是否合法 188 fn virt_is_valid(virt: VirtAddr) -> bool { 189 return virt.is_canonical(); 190 } 191 192 /// 获取内存管理初始化时,创建的第一个内核页表的地址 193 fn initial_page_table() -> PhysAddr { 194 unsafe { 195 return INITIAL_CR3_VALUE; 196 } 197 } 198 199 /// @brief 创建新的顶层页表 200 /// 201 /// 该函数会创建页表并复制内核的映射到新的页表中 202 /// 203 /// @return 新的页表 204 fn setup_new_usermapper() -> Result<crate::mm::ucontext::UserMapper, SystemError> { 205 let new_umapper: crate::mm::page::PageMapper<X86_64MMArch, LockedFrameAllocator> = unsafe { 206 PageMapper::create(PageTableKind::User, LockedFrameAllocator) 207 .ok_or(SystemError::ENOMEM)? 208 }; 209 210 let current_ktable: KernelMapper = KernelMapper::lock(); 211 let copy_mapping = |pml4_entry_no| unsafe { 212 let entry: PageEntry<X86_64MMArch> = current_ktable 213 .table() 214 .entry(pml4_entry_no) 215 .unwrap_or_else(|| panic!("entry {} not found", pml4_entry_no)); 216 new_umapper.table().set_entry(pml4_entry_no, entry) 217 }; 218 219 // 复制内核的映射 220 for pml4_entry_no in KERNEL_PML4E_NO..512 { 221 copy_mapping(pml4_entry_no); 222 } 223 224 return Ok(crate::mm::ucontext::UserMapper::new(new_umapper)); 225 } 226 } 227 228 impl X86_64MMArch { 229 unsafe fn init_memory_area_from_multiboot2() -> Result<usize, SystemError> { 230 // 这个数组用来存放内存区域的信息(从C获取) 231 let mut mb2_mem_info: [multiboot_mmap_entry_t; 512] = mem::zeroed(); 232 send_to_default_serial8250_port("init_memory_area_from_multiboot2 begin\n\0".as_bytes()); 233 234 let mut mb2_count: u32 = 0; 235 multiboot2_iter( 236 Some(multiboot2_get_memory), 237 &mut mb2_mem_info as *mut [multiboot_mmap_entry_t; 512] as usize as *mut c_void, 238 &mut mb2_count, 239 ); 240 send_to_default_serial8250_port("init_memory_area_from_multiboot2 2\n\0".as_bytes()); 241 242 let mb2_count = mb2_count as usize; 243 let mut areas_count = 0usize; 244 let mut total_mem_size = 0usize; 245 for i in 0..mb2_count { 246 // Only use the memory area if its type is 1 (RAM) 247 if mb2_mem_info[i].type_ == 1 { 248 // Skip the memory area if its len is 0 249 if mb2_mem_info[i].len == 0 { 250 continue; 251 } 252 total_mem_size += mb2_mem_info[i].len as usize; 253 PHYS_MEMORY_AREAS[areas_count].base = PhysAddr::new(mb2_mem_info[i].addr as usize); 254 PHYS_MEMORY_AREAS[areas_count].size = mb2_mem_info[i].len as usize; 255 areas_count += 1; 256 } 257 } 258 send_to_default_serial8250_port("init_memory_area_from_multiboot2 end\n\0".as_bytes()); 259 kinfo!("Total memory size: {} MB, total areas from multiboot2: {mb2_count}, valid areas: {areas_count}", total_mem_size / 1024 / 1024); 260 261 return Ok(areas_count); 262 } 263 264 fn init_xd_rsvd() { 265 // 读取ia32-EFER寄存器的值 266 let efer: EferFlags = x86_64::registers::model_specific::Efer::read(); 267 if !efer.contains(EferFlags::NO_EXECUTE_ENABLE) { 268 // NO_EXECUTE_ENABLE是false,那么就设置xd_reserved为true 269 kdebug!("NO_EXECUTE_ENABLE is false, set XD_RESERVED to true"); 270 XD_RESERVED.store(true, Ordering::Relaxed); 271 } 272 compiler_fence(Ordering::SeqCst); 273 } 274 275 /// 判断XD标志位是否被保留 276 pub fn is_xd_reserved() -> bool { 277 return XD_RESERVED.load(Ordering::Relaxed); 278 } 279 } 280 281 impl VirtAddr { 282 /// @brief 判断虚拟地址是否合法 283 #[inline(always)] 284 pub fn is_canonical(self) -> bool { 285 let x = self.data() & X86_64MMArch::PHYS_OFFSET; 286 // 如果x为0,说明虚拟地址的高位为0,是合法的用户地址 287 // 如果x为PHYS_OFFSET,说明虚拟地址的高位全为1,是合法的内核地址 288 return x == 0 || x == X86_64MMArch::PHYS_OFFSET; 289 } 290 } 291 292 /// @brief 初始化内存管理模块 293 pub fn mm_init() { 294 send_to_default_serial8250_port("mm_init\n\0".as_bytes()); 295 PrintkWriter 296 .write_fmt(format_args!("mm_init() called\n")) 297 .unwrap(); 298 // printk_color!(GREEN, BLACK, "mm_init() called\n"); 299 static _CALL_ONCE: AtomicBool = AtomicBool::new(false); 300 if _CALL_ONCE 301 .compare_exchange(false, true, Ordering::SeqCst, Ordering::SeqCst) 302 .is_err() 303 { 304 send_to_default_serial8250_port("mm_init err\n\0".as_bytes()); 305 panic!("mm_init() can only be called once"); 306 } 307 308 unsafe { X86_64MMArch::init() }; 309 kdebug!("bootstrap info: {:?}", unsafe { BOOTSTRAP_MM_INFO }); 310 kdebug!("phys[0]=virt[0x{:x}]", unsafe { 311 MMArch::phys_2_virt(PhysAddr::new(0)).unwrap().data() 312 }); 313 314 // 初始化内存管理器 315 unsafe { allocator_init() }; 316 // enable mmio 317 mmio_init(); 318 } 319 320 unsafe fn allocator_init() { 321 let virt_offset = BOOTSTRAP_MM_INFO.unwrap().start_brk; 322 let phy_offset = 323 unsafe { MMArch::virt_2_phys(VirtAddr::new(page_align_up(virt_offset))) }.unwrap(); 324 325 kdebug!("PhysArea[0..10] = {:?}", &PHYS_MEMORY_AREAS[0..10]); 326 let mut bump_allocator = 327 BumpAllocator::<X86_64MMArch>::new(&PHYS_MEMORY_AREAS, phy_offset.data()); 328 kdebug!( 329 "BumpAllocator created, offset={:?}", 330 bump_allocator.offset() 331 ); 332 333 // 暂存初始在head.S中指定的页表的地址,后面再考虑是否需要把它加到buddy的可用空间里面! 334 // 现在不加的原因是,我担心会有安全漏洞问题:这些初始的页表,位于内核的数据段。如果归还到buddy, 335 // 可能会产生一定的安全风险(有的代码可能根据虚拟地址来进行安全校验) 336 let _old_page_table = MMArch::table(PageTableKind::Kernel); 337 338 let new_page_table: PhysAddr; 339 // 使用bump分配器,把所有的内存页都映射到页表 340 { 341 // 用bump allocator创建新的页表 342 let mut mapper: crate::mm::page::PageMapper<MMArch, &mut BumpAllocator<MMArch>> = 343 crate::mm::page::PageMapper::<MMArch, _>::create( 344 PageTableKind::Kernel, 345 &mut bump_allocator, 346 ) 347 .expect("Failed to create page mapper"); 348 new_page_table = mapper.table().phys(); 349 kdebug!("PageMapper created"); 350 351 // 取消最开始时候,在head.S中指定的映射(暂时不刷新TLB) 352 { 353 let table = mapper.table(); 354 let empty_entry = PageEntry::<MMArch>::new(0); 355 for i in 0..MMArch::PAGE_ENTRY_NUM { 356 table 357 .set_entry(i, empty_entry) 358 .expect("Failed to empty page table entry"); 359 } 360 } 361 kdebug!("Successfully emptied page table"); 362 363 for area in PHYS_MEMORY_AREAS.iter() { 364 // kdebug!("area: base={:?}, size={:#x}, end={:?}", area.base, area.size, area.base + area.size); 365 for i in 0..((area.size + MMArch::PAGE_SIZE - 1) / MMArch::PAGE_SIZE) { 366 let paddr = area.base.add(i * MMArch::PAGE_SIZE); 367 let vaddr = unsafe { MMArch::phys_2_virt(paddr) }.unwrap(); 368 let flags = kernel_page_flags::<MMArch>(vaddr); 369 370 let flusher = mapper 371 .map_phys(vaddr, paddr, flags) 372 .expect("Failed to map frame"); 373 // 暂时不刷新TLB 374 flusher.ignore(); 375 } 376 } 377 378 // 添加低地址的映射(在smp完成初始化之前,需要使用低地址的映射.初始化之后需要取消这一段映射) 379 LowAddressRemapping::remap_at_low_address(&mut mapper); 380 } 381 382 unsafe { 383 INITIAL_CR3_VALUE = new_page_table; 384 } 385 kdebug!( 386 "After mapping all physical memory, DragonOS used: {} KB", 387 bump_allocator.offset() / 1024 388 ); 389 390 // 初始化buddy_allocator 391 let buddy_allocator = unsafe { BuddyAllocator::<X86_64MMArch>::new(bump_allocator).unwrap() }; 392 // 设置全局的页帧分配器 393 unsafe { set_inner_allocator(buddy_allocator) }; 394 kinfo!("Successfully initialized buddy allocator"); 395 // 关闭显示输出 396 scm_disable_put_to_window(); 397 398 // make the new page table current 399 { 400 let mut binding = INNER_ALLOCATOR.lock(); 401 let mut allocator_guard = binding.as_mut().unwrap(); 402 kdebug!("To enable new page table."); 403 compiler_fence(Ordering::SeqCst); 404 let mapper = crate::mm::page::PageMapper::<MMArch, _>::new( 405 PageTableKind::Kernel, 406 new_page_table, 407 &mut allocator_guard, 408 ); 409 compiler_fence(Ordering::SeqCst); 410 mapper.make_current(); 411 compiler_fence(Ordering::SeqCst); 412 kdebug!("New page table enabled"); 413 } 414 kdebug!("Successfully enabled new page table"); 415 } 416 417 #[no_mangle] 418 pub extern "C" fn rs_test_buddy() { 419 test_buddy(); 420 } 421 pub fn test_buddy() { 422 // 申请内存然后写入数据然后free掉 423 // 总共申请200MB内存 424 const TOTAL_SIZE: usize = 200 * 1024 * 1024; 425 426 for i in 0..10 { 427 kdebug!("Test buddy, round: {i}"); 428 // 存放申请的内存块 429 let mut v: Vec<(PhysAddr, PageFrameCount)> = Vec::with_capacity(60 * 1024); 430 // 存放已经申请的内存块的地址(用于检查重复) 431 let mut addr_set: HashSet<PhysAddr> = HashSet::new(); 432 433 let mut allocated = 0usize; 434 435 let mut free_count = 0usize; 436 437 while allocated < TOTAL_SIZE { 438 let mut random_size = 0u64; 439 unsafe { x86::random::rdrand64(&mut random_size) }; 440 // 一次最多申请4M 441 random_size = random_size % (1024 * 4096); 442 if random_size == 0 { 443 continue; 444 } 445 let random_size = 446 core::cmp::min(page_align_up(random_size as usize), TOTAL_SIZE - allocated); 447 let random_size = PageFrameCount::from_bytes(random_size.next_power_of_two()).unwrap(); 448 // 获取帧 449 let (paddr, allocated_frame_count) = 450 unsafe { LockedFrameAllocator.allocate(random_size).unwrap() }; 451 assert!(allocated_frame_count.data().is_power_of_two()); 452 assert!(paddr.data() % MMArch::PAGE_SIZE == 0); 453 unsafe { 454 assert!(MMArch::phys_2_virt(paddr) 455 .as_ref() 456 .unwrap() 457 .check_aligned(allocated_frame_count.data() * MMArch::PAGE_SIZE)); 458 } 459 allocated += allocated_frame_count.data() * MMArch::PAGE_SIZE; 460 v.push((paddr, allocated_frame_count)); 461 assert!(addr_set.insert(paddr), "duplicate address: {:?}", paddr); 462 463 // 写入数据 464 let vaddr = unsafe { MMArch::phys_2_virt(paddr).unwrap() }; 465 let slice = unsafe { 466 core::slice::from_raw_parts_mut( 467 vaddr.data() as *mut u8, 468 allocated_frame_count.data() * MMArch::PAGE_SIZE, 469 ) 470 }; 471 for i in 0..slice.len() { 472 slice[i] = ((i + unsafe { rdtsc() } as usize) % 256) as u8; 473 } 474 475 // 随机释放一个内存块 476 if v.len() > 0 { 477 let mut random_index = 0u64; 478 unsafe { x86::random::rdrand64(&mut random_index) }; 479 // 70%概率释放 480 if random_index % 10 > 7 { 481 continue; 482 } 483 random_index = random_index % v.len() as u64; 484 let random_index = random_index as usize; 485 let (paddr, allocated_frame_count) = v.remove(random_index); 486 assert!(addr_set.remove(&paddr)); 487 unsafe { LockedFrameAllocator.free(paddr, allocated_frame_count) }; 488 free_count += allocated_frame_count.data() * MMArch::PAGE_SIZE; 489 } 490 } 491 492 kdebug!( 493 "Allocated {} MB memory, release: {} MB, no release: {} bytes", 494 allocated / 1024 / 1024, 495 free_count / 1024 / 1024, 496 (allocated - free_count) 497 ); 498 499 kdebug!("Now, to release buddy memory"); 500 // 释放所有的内存 501 for (paddr, allocated_frame_count) in v { 502 unsafe { LockedFrameAllocator.free(paddr, allocated_frame_count) }; 503 assert!(addr_set.remove(&paddr)); 504 free_count += allocated_frame_count.data() * MMArch::PAGE_SIZE; 505 } 506 507 kdebug!("release done!, allocated: {allocated}, free_count: {free_count}"); 508 } 509 } 510 /// 全局的页帧分配器 511 #[derive(Debug, Clone, Copy, Hash)] 512 pub struct LockedFrameAllocator; 513 514 impl FrameAllocator for LockedFrameAllocator { 515 unsafe fn allocate(&mut self, count: PageFrameCount) -> Option<(PhysAddr, PageFrameCount)> { 516 if let Some(ref mut allocator) = *INNER_ALLOCATOR.lock_irqsave() { 517 return allocator.allocate(count); 518 } else { 519 return None; 520 } 521 } 522 523 unsafe fn free(&mut self, address: crate::mm::PhysAddr, count: PageFrameCount) { 524 assert!(count.data().is_power_of_two()); 525 if let Some(ref mut allocator) = *INNER_ALLOCATOR.lock_irqsave() { 526 return allocator.free(address, count); 527 } 528 } 529 530 unsafe fn usage(&self) -> PageFrameUsage { 531 if let Some(ref mut allocator) = *INNER_ALLOCATOR.lock_irqsave() { 532 return allocator.usage(); 533 } else { 534 panic!("usage error"); 535 } 536 } 537 } 538 539 impl LockedFrameAllocator { 540 pub fn get_usage(&self) -> PageFrameUsage { 541 unsafe { self.usage() } 542 } 543 } 544 545 /// 获取内核地址默认的页面标志 546 pub unsafe fn kernel_page_flags<A: MemoryManagementArch>(virt: VirtAddr) -> PageFlags<A> { 547 let info: X86_64MMBootstrapInfo = BOOTSTRAP_MM_INFO.clone().unwrap(); 548 549 if virt.data() >= info.kernel_code_start && virt.data() < info.kernel_code_end { 550 // Remap kernel code execute 551 return PageFlags::new().set_execute(true).set_write(true); 552 } else if virt.data() >= info.kernel_data_end && virt.data() < info.kernel_rodata_end { 553 // Remap kernel rodata read only 554 return PageFlags::new().set_execute(true); 555 } else { 556 return PageFlags::new().set_write(true).set_execute(true); 557 } 558 } 559 560 unsafe fn set_inner_allocator(allocator: BuddyAllocator<MMArch>) { 561 static FLAG: AtomicBool = AtomicBool::new(false); 562 if FLAG 563 .compare_exchange(false, true, Ordering::SeqCst, Ordering::SeqCst) 564 .is_err() 565 { 566 panic!("Cannot set inner allocator twice!"); 567 } 568 *INNER_ALLOCATOR.lock() = Some(allocator); 569 } 570 571 /// 低地址重映射的管理器 572 /// 573 /// 低地址重映射的管理器,在smp初始化完成之前,需要使用低地址的映射,因此需要在smp初始化完成之后,取消这一段映射 574 pub struct LowAddressRemapping; 575 576 impl LowAddressRemapping { 577 // 映射32M 578 const REMAP_SIZE: usize = 32 * 1024 * 1024; 579 580 pub unsafe fn remap_at_low_address( 581 mapper: &mut crate::mm::page::PageMapper<MMArch, &mut BumpAllocator<MMArch>>, 582 ) { 583 for i in 0..(Self::REMAP_SIZE / MMArch::PAGE_SIZE) { 584 let paddr = PhysAddr::new(i * MMArch::PAGE_SIZE); 585 let vaddr = VirtAddr::new(i * MMArch::PAGE_SIZE); 586 let flags = kernel_page_flags::<MMArch>(vaddr); 587 588 let flusher = mapper 589 .map_phys(vaddr, paddr, flags) 590 .expect("Failed to map frame"); 591 // 暂时不刷新TLB 592 flusher.ignore(); 593 } 594 } 595 596 /// 取消低地址的映射 597 pub unsafe fn unmap_at_low_address(flush: bool) { 598 let mut mapper = KernelMapper::lock(); 599 assert!(mapper.as_mut().is_some()); 600 for i in 0..(Self::REMAP_SIZE / MMArch::PAGE_SIZE) { 601 let vaddr = VirtAddr::new(i * MMArch::PAGE_SIZE); 602 let (_, _, flusher) = mapper 603 .as_mut() 604 .unwrap() 605 .unmap_phys(vaddr, true) 606 .expect("Failed to unmap frame"); 607 if flush == false { 608 flusher.ignore(); 609 } 610 } 611 } 612 } 613 #[no_mangle] 614 pub extern "C" fn rs_mm_init() { 615 mm_init(); 616 } 617