140314b30SXiaoye Zheng use crate::arch::kvm::vmx::vcpu::VmxVcpu; 24fda81ceSLoGin use crate::arch::MMArch; 340314b30SXiaoye Zheng use crate::libs::mutex::Mutex; 44fda81ceSLoGin use crate::mm::MemoryManagementArch; 540314b30SXiaoye Zheng use crate::{arch::KVMArch, kdebug}; 640314b30SXiaoye Zheng use alloc::sync::Arc; 740314b30SXiaoye Zheng use alloc::vec::Vec; 8*91e9d4abSLoGin use system_error::SystemError; 940314b30SXiaoye Zheng 1040314b30SXiaoye Zheng // use super::HOST_STACK_SIZE; 1140314b30SXiaoye Zheng use super::host_mem::{ 1240314b30SXiaoye Zheng KvmMemoryChange, KvmMemorySlot, KvmMemorySlots, KvmUserspaceMemoryRegion, 1340314b30SXiaoye Zheng KVM_ADDRESS_SPACE_NUM, KVM_MEM_LOG_DIRTY_PAGES, KVM_MEM_MAX_NR_PAGES, KVM_MEM_READONLY, 1440314b30SXiaoye Zheng KVM_MEM_SLOTS_NUM, KVM_USER_MEM_SLOTS, PAGE_SHIFT, 1540314b30SXiaoye Zheng }; 1640314b30SXiaoye Zheng // use crate::kdebug; 1740314b30SXiaoye Zheng 1840314b30SXiaoye Zheng #[derive(Debug, Clone)] 1940314b30SXiaoye Zheng pub struct Vm { 2040314b30SXiaoye Zheng pub id: usize, 2140314b30SXiaoye Zheng // vcpu config 2240314b30SXiaoye Zheng pub nr_vcpus: u32, /* Number of cpus to run */ 2340314b30SXiaoye Zheng pub vcpu: Vec<Arc<Mutex<VmxVcpu>>>, 2440314b30SXiaoye Zheng // memory config 2540314b30SXiaoye Zheng pub nr_mem_slots: u32, /* Number of memory slots in each address space */ 2640314b30SXiaoye Zheng pub memslots: [KvmMemorySlots; KVM_ADDRESS_SPACE_NUM], 2740314b30SXiaoye Zheng // arch related config 2840314b30SXiaoye Zheng pub arch: KVMArch, 2940314b30SXiaoye Zheng } 3040314b30SXiaoye Zheng 3140314b30SXiaoye Zheng impl Vm { 3240314b30SXiaoye Zheng pub fn new(id: usize) -> Result<Self, SystemError> { 3340314b30SXiaoye Zheng let vcpu = Vec::new(); 3440314b30SXiaoye Zheng // Allocate stack for vm-exit handlers and fill it with garbage data 3540314b30SXiaoye Zheng let instance = Self { 3640314b30SXiaoye Zheng id, 3740314b30SXiaoye Zheng nr_vcpus: 0, 3840314b30SXiaoye Zheng vcpu, 3940314b30SXiaoye Zheng nr_mem_slots: KVM_MEM_SLOTS_NUM, 4040314b30SXiaoye Zheng memslots: [KvmMemorySlots::default(); KVM_ADDRESS_SPACE_NUM], 4140314b30SXiaoye Zheng arch: Default::default(), 4240314b30SXiaoye Zheng }; 4340314b30SXiaoye Zheng Ok(instance) 4440314b30SXiaoye Zheng } 4540314b30SXiaoye Zheng 4640314b30SXiaoye Zheng /// Allocate some memory and give it an address in the guest physical address space. 4740314b30SXiaoye Zheng pub fn set_user_memory_region( 4840314b30SXiaoye Zheng &mut self, 4940314b30SXiaoye Zheng mem: &KvmUserspaceMemoryRegion, 5040314b30SXiaoye Zheng ) -> Result<(), SystemError> { 5140314b30SXiaoye Zheng kdebug!("set_user_memory_region"); 5240314b30SXiaoye Zheng let id: u16 = mem.slot as u16; // slot id 5340314b30SXiaoye Zheng let as_id = mem.slot >> 16; // address space id 5440314b30SXiaoye Zheng kdebug!("id={}, as_id={}", id, as_id); 5540314b30SXiaoye Zheng 5640314b30SXiaoye Zheng // 检查slot是否合法 5740314b30SXiaoye Zheng if mem.slot as usize >= self.nr_mem_slots as usize { 5840314b30SXiaoye Zheng return Err(SystemError::EINVAL); 5940314b30SXiaoye Zheng } 6040314b30SXiaoye Zheng // 检查flags是否合法 6140314b30SXiaoye Zheng self.check_memory_region_flag(mem)?; 6240314b30SXiaoye Zheng // 内存大小和地址必须是页对齐的 634fda81ceSLoGin if (mem.memory_size & (MMArch::PAGE_SIZE - 1) as u64) != 0 644fda81ceSLoGin || (mem.guest_phys_addr & (MMArch::PAGE_SIZE - 1) as u64) != 0 6540314b30SXiaoye Zheng { 6640314b30SXiaoye Zheng return Err(SystemError::EINVAL); 6740314b30SXiaoye Zheng } 6840314b30SXiaoye Zheng // 检查地址空间是否合法 6940314b30SXiaoye Zheng if as_id >= (KVM_ADDRESS_SPACE_NUM as u32) || id >= KVM_MEM_SLOTS_NUM as u16 { 7040314b30SXiaoye Zheng return Err(SystemError::EINVAL); 7140314b30SXiaoye Zheng } 7240314b30SXiaoye Zheng // if mem.memory_size < 0 { 7340314b30SXiaoye Zheng // return Err(SystemError::EINVAL); 7440314b30SXiaoye Zheng // } 7540314b30SXiaoye Zheng let slot = &self.memslots[as_id as usize].memslots[id as usize]; 7640314b30SXiaoye Zheng let base_gfn = mem.guest_phys_addr >> PAGE_SHIFT; 7740314b30SXiaoye Zheng let npages = mem.memory_size >> PAGE_SHIFT; 7840314b30SXiaoye Zheng if npages > KVM_MEM_MAX_NR_PAGES as u64 { 7940314b30SXiaoye Zheng return Err(SystemError::EINVAL); 8040314b30SXiaoye Zheng } 8140314b30SXiaoye Zheng let change: KvmMemoryChange; 8240314b30SXiaoye Zheng 8340314b30SXiaoye Zheng let old_slot = slot; 8440314b30SXiaoye Zheng let mut new_slot = KvmMemorySlot { 8540314b30SXiaoye Zheng base_gfn, // 虚机内存区间起始物理页框号 8640314b30SXiaoye Zheng npages, // 虚机内存区间页数,即内存区间的大小 8740314b30SXiaoye Zheng // dirty_bitmap: old_slot.dirty_bitmap, 8840314b30SXiaoye Zheng userspace_addr: mem.userspace_addr, // 虚机内存区间对应的主机虚拟地址 8940314b30SXiaoye Zheng flags: mem.flags, // 虚机内存区间属性 9040314b30SXiaoye Zheng id, // 虚机内存区间id 9140314b30SXiaoye Zheng }; 9240314b30SXiaoye Zheng 9340314b30SXiaoye Zheng // 判断新memoryslot的类型 9440314b30SXiaoye Zheng if npages != 0 { 9540314b30SXiaoye Zheng //映射内存有大小,不是删除内存条 9640314b30SXiaoye Zheng if old_slot.npages == 0 { 9740314b30SXiaoye Zheng //内存槽号没有虚拟内存条,意味内存新创建 9840314b30SXiaoye Zheng change = KvmMemoryChange::Create; 9940314b30SXiaoye Zheng } else { 10040314b30SXiaoye Zheng //修改已存在的内存,表示修改标志或者平移映射地址 10140314b30SXiaoye Zheng // 检查内存条是否可以修改 10240314b30SXiaoye Zheng if mem.userspace_addr != old_slot.userspace_addr 10340314b30SXiaoye Zheng || npages != old_slot.npages 10440314b30SXiaoye Zheng || (new_slot.flags ^ old_slot.flags & KVM_MEM_READONLY) != 0 10540314b30SXiaoye Zheng { 10640314b30SXiaoye Zheng return Err(SystemError::EINVAL); 10740314b30SXiaoye Zheng } 10840314b30SXiaoye Zheng if new_slot.base_gfn != old_slot.base_gfn { 10940314b30SXiaoye Zheng //guest地址不同,内存条平移 11040314b30SXiaoye Zheng change = KvmMemoryChange::Move; 11140314b30SXiaoye Zheng } else if new_slot.flags != old_slot.flags { 11240314b30SXiaoye Zheng //内存条标志不同,修改标志 11340314b30SXiaoye Zheng change = KvmMemoryChange::FlagsOnly; 11440314b30SXiaoye Zheng } else { 11540314b30SXiaoye Zheng return Ok(()); 11640314b30SXiaoye Zheng } 11740314b30SXiaoye Zheng } 11840314b30SXiaoye Zheng } else { 11940314b30SXiaoye Zheng if old_slot.npages == 0 { 12040314b30SXiaoye Zheng //内存槽号没有虚拟内存条,不可以删除 12140314b30SXiaoye Zheng return Err(SystemError::EINVAL); 12240314b30SXiaoye Zheng } 12340314b30SXiaoye Zheng //申请插入的内存为0,而内存槽上有内存,意味删除 12440314b30SXiaoye Zheng change = KvmMemoryChange::Delete; 12540314b30SXiaoye Zheng new_slot.base_gfn = 0; 12640314b30SXiaoye Zheng new_slot.flags = 0; 12740314b30SXiaoye Zheng } 12840314b30SXiaoye Zheng 12940314b30SXiaoye Zheng if change == KvmMemoryChange::Create || change == KvmMemoryChange::Move { 13040314b30SXiaoye Zheng // 检查内存区域是否重叠 13140314b30SXiaoye Zheng for i in 0..KVM_MEM_SLOTS_NUM { 13240314b30SXiaoye Zheng let memslot = &self.memslots[as_id as usize].memslots[i as usize]; 13340314b30SXiaoye Zheng if memslot.id == id || memslot.id as u32 >= KVM_USER_MEM_SLOTS { 13440314b30SXiaoye Zheng continue; 13540314b30SXiaoye Zheng } 13640314b30SXiaoye Zheng // 当前已有的slot与new在guest物理地址上有交集 13740314b30SXiaoye Zheng if !(base_gfn + npages <= memslot.base_gfn 13840314b30SXiaoye Zheng || memslot.base_gfn + memslot.npages <= base_gfn) 13940314b30SXiaoye Zheng { 14040314b30SXiaoye Zheng return Err(SystemError::EEXIST); 14140314b30SXiaoye Zheng } 14240314b30SXiaoye Zheng } 14340314b30SXiaoye Zheng } 14440314b30SXiaoye Zheng 14540314b30SXiaoye Zheng if !(new_slot.flags & KVM_MEM_LOG_DIRTY_PAGES != 0) { 14640314b30SXiaoye Zheng // new_slot.dirty_bitmap = 0; 14740314b30SXiaoye Zheng } 14840314b30SXiaoye Zheng 14940314b30SXiaoye Zheng // 根据flags的值,决定是否创建内存脏页 15040314b30SXiaoye Zheng // if (new_slot.flags & KVM_MEM_LOG_DIRTY_PAGES)!=0 && new_slot.dirty_bitmap == 0 { 15140314b30SXiaoye Zheng // let type_size = core::mem::size_of::<u64>() as u64; 15240314b30SXiaoye Zheng // let dirty_bytes = 2 * ((new_slot.npages+type_size-1) / type_size) / 8; 15340314b30SXiaoye Zheng // new_slot.dirty_bitmap = Box::new(vec![0; dirty_bytes as u8]); 15440314b30SXiaoye Zheng // } 15540314b30SXiaoye Zheng if change == KvmMemoryChange::Create { 15640314b30SXiaoye Zheng new_slot.userspace_addr = mem.userspace_addr; 15740314b30SXiaoye Zheng let mut memslots = self.memslots[as_id as usize].memslots.clone(); 15840314b30SXiaoye Zheng memslots[id as usize] = new_slot; 15940314b30SXiaoye Zheng self.memslots[as_id as usize].memslots = memslots; 16040314b30SXiaoye Zheng self.memslots[as_id as usize].used_slots += 1; 16140314b30SXiaoye Zheng // KVMArch::kvm_arch_create_memslot(&mut new_slot, npages); 16240314b30SXiaoye Zheng // KVMArch::kvm_arch_commit_memory_region(mem, &new_slot, old_slot, change); 16340314b30SXiaoye Zheng } 16440314b30SXiaoye Zheng // TODO--KvmMemoryChange::Delete & Move 16540314b30SXiaoye Zheng Ok(()) 16640314b30SXiaoye Zheng } 16740314b30SXiaoye Zheng 16840314b30SXiaoye Zheng fn check_memory_region_flag(&self, mem: &KvmUserspaceMemoryRegion) -> Result<(), SystemError> { 16940314b30SXiaoye Zheng let valid_flags = KVM_MEM_LOG_DIRTY_PAGES; 17040314b30SXiaoye Zheng // 除了valid_flags之外的flags被置1了,就返回错误 17140314b30SXiaoye Zheng if mem.flags & !valid_flags != 0 { 17240314b30SXiaoye Zheng return Err(SystemError::EINVAL); 17340314b30SXiaoye Zheng } 17440314b30SXiaoye Zheng Ok(()) 17540314b30SXiaoye Zheng } 17640314b30SXiaoye Zheng } 177