正如你所见,NAT路由器将每台计算机的IP地址和端口号都存储在地址转换表中。
As you can see, the NAT router stores the IP address and port number of each computer in the address translation table.
然后它查看地址转换表确定数据包是属于哪一台存根域中的计算机。
It then looks in the address translation table to see which computer on the stub domain the packet belongs to.
路由器将其目的地址换成它保存在地址转换表中的那个,然后将数据包发送到那台计算机。
It changes the destination address to the one saved in the address translation table and sends it to that computer.
路由器然后查看地址转换表,看有没有一个条目是这个内部本地地址对应的内部全局地址。
The router then checks the address translation table to find if there is an entry existing for the inside local address with a corresponding inside global address.
现在,地址转换表就拥有了这台计算的不可路由IP地址到一个唯一 IP地址的匹配映射。
The translation table now has a mapping of the computer's non-routable IP address matched with one of the unique IP addresses.
由于nat路由器现在已经拥有了这台计算机保存在地址转换表中的的源地址和源端口号,它将会在有效期内继续使用同一个端口号进行转换。
Since the NAT router now has the computer's source address and source port saved to the address translation table, it will continue to use that same port number for the duration of the connection.
Pacifica还可以使用宿主和客户内存管理单元(MMU)表来进行地址转换。
Pacifica also amends address translation with host and guest memory management unit (MMU) tables.
操作系统维持着一个虚拟地址到物理地址的转换的表,以便计算机硬件可以正确地响应地址请求。
The operating system maintains a table of virtual address-to-physical address translations so that the computer hardware can respond properly to address requests.
NAT路由器将这个数据包中的内部全局地址 (即其目的地址,译者)转换成内部本地地址后再查看路由表。
The NAT router translates the inside global address of the packet to the inside local address and then checks the routing table before it sends it to the destination computer.
Hypervisor使用全局分区页表将虚拟地址转换为系统范围的物理地址。
The hypervisor converts a virtual address to a system-wide physical address using the global partition page tables.
建立一个页表,把逻辑地址转换为物理地址。
Set up a page table to translate logical to physical addresses.
建立一个页表,把逻辑地址转换为物理地址。
Set up a page table to translate logical to physical addresses.
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