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mirror of https://github.com/rcore-os/rCore.git synced 2024-11-27 02:03:29 +04:00
rCore/kernel/src/process/context.rs
2018-10-30 12:45:09 +08:00

231 lines
7.3 KiB
Rust

use arch::interrupt::{TrapFrame, Context as ArchContext};
use memory::{MemoryArea, MemoryAttr, MemorySet, active_table_swap, alloc_frame};
use xmas_elf::{ElfFile, header, program::{Flags, ProgramHeader, Type}};
use core::fmt::{Debug, Error, Formatter};
use ucore_memory::{Page};
use ::memory::{InactivePageTable0};
pub struct Context {
arch: ArchContext,
memory_set: MemorySet,
}
impl ::ucore_process::processor::Context for Context {
/*
* @param:
* target: the target process context
* @brief:
* switch to the target process context
*/
unsafe fn switch(&mut self, target: &mut Self) {
super::PROCESSOR.try().unwrap().force_unlock();
self.arch.switch(&mut target.arch);
use core::mem::forget;
// don't run the distructor of processor()
forget(super::processor());
}
/*
* @param:
* entry: the program entry for the process
* arg: a0 (a parameter)
* @brief:
* new a kernel thread Context
* @retval:
* the new kernel thread Context
*/
fn new_kernel(entry: extern fn(usize) -> !, arg: usize) -> Self {
let ms = MemorySet::new();
Context {
arch: unsafe { ArchContext::new_kernel_thread(entry, arg, ms.kstack_top(), ms.token()) },
memory_set: ms,
}
}
}
impl Context {
pub unsafe fn new_init() -> Self {
Context {
arch: ArchContext::null(),
memory_set: MemorySet::new(),
}
}
/// Make a new user thread from ELF data
/*
* @param:
* data: the ELF data stream
* @brief:
* make a new thread from ELF data
* @retval:
* the new user thread Context
*/
pub fn new_user(data: &[u8]) -> Self {
// Parse elf
let elf = ElfFile::new(data).expect("failed to read elf");
let is32 = match elf.header.pt2 {
header::HeaderPt2::Header32(_) => true,
header::HeaderPt2::Header64(_) => false,
};
assert_eq!(elf.header.pt2.type_().as_type(), header::Type::Executable, "ELF is not executable");
// User stack
use consts::{USER_STACK_OFFSET, USER_STACK_SIZE, USER32_STACK_OFFSET};
let (user_stack_buttom, user_stack_top) = match is32 {
true => (USER32_STACK_OFFSET, USER32_STACK_OFFSET + USER_STACK_SIZE),
false => (USER_STACK_OFFSET, USER_STACK_OFFSET + USER_STACK_SIZE),
};
// Make page table
let mut memory_set = memory_set_from(&elf);
memory_set.push(MemoryArea::new(user_stack_buttom, user_stack_top, MemoryAttr::default().user(), "user_stack"));
trace!("{:#x?}", memory_set);
let entry_addr = elf.header.pt2.entry_point() as usize;
// Temporary switch to it, in order to copy data
unsafe {
memory_set.with(|| {
for ph in elf.program_iter() {
let virt_addr = ph.virtual_addr() as usize;
let offset = ph.offset() as usize;
let file_size = ph.file_size() as usize;
if file_size == 0 {
return;
}
use core::slice;
let target = unsafe { slice::from_raw_parts_mut(virt_addr as *mut u8, file_size) };
target.copy_from_slice(&data[offset..offset + file_size]);
}
if is32 {
unsafe {
// TODO: full argc & argv
*(user_stack_top as *mut u32).offset(-1) = 0; // argv
*(user_stack_top as *mut u32).offset(-2) = 0; // argc
}
}
});
}
//set the user Memory pages in the memory set swappable
memory_set_map_swappable(&mut memory_set);
Context {
arch: unsafe {
ArchContext::new_user_thread(
entry_addr, user_stack_top - 8, memory_set.kstack_top(), is32, memory_set.token())
},
memory_set,
}
}
/// Fork
pub fn fork(&self, tf: &TrapFrame) -> Self {
// Clone memory set, make a new page table
let mut memory_set = self.memory_set.clone();
// Copy data to temp space
use alloc::vec::Vec;
let datas: Vec<Vec<u8>> = memory_set.iter().map(|area| {
Vec::from(unsafe { area.as_slice() })
}).collect();
// Temporary switch to it, in order to copy data
unsafe {
memory_set.with(|| {
for (area, data) in memory_set.iter().zip(datas.iter()) {
unsafe { area.as_slice_mut() }.copy_from_slice(data.as_slice())
}
});
}
// map the memory set swappable
memory_set_map_swappable(&mut memory_set);
Context {
arch: unsafe { ArchContext::new_fork(tf, memory_set.kstack_top(), memory_set.token()) },
memory_set,
}
}
pub fn get_memory_set_mut(&mut self) -> &mut MemorySet {
&mut self.memory_set
}
}
impl Drop for Context{
fn drop(&mut self){
//set the user Memory pages in the memory set unswappable
let Self {ref mut arch, ref mut memory_set} = self;
let pt = {
memory_set.get_page_table_mut() as *mut InactivePageTable0
};
for area in memory_set.iter(){
for page in Page::range_of(area.get_start_addr(), area.get_end_addr()) {
let addr = page.start_address();
unsafe {
active_table_swap().remove_from_swappable(pt, addr, || alloc_frame().unwrap());
}
}
}
info!("Finishing setting pages unswappable");
}
}
impl Debug for Context {
fn fmt(&self, f: &mut Formatter) -> Result<(), Error> {
write!(f, "{:x?}", self.arch)
}
}
/*
* @param:
* elf: the source ELF file
* @brief:
* generate a memory set according to the elf file
* @retval:
* the new memory set
*/
fn memory_set_from<'a>(elf: &'a ElfFile<'a>) -> MemorySet {
let mut set = MemorySet::new();
for ph in elf.program_iter() {
if ph.get_type() != Ok(Type::Load) {
continue;
}
let (virt_addr, mem_size, flags) = match ph {
ProgramHeader::Ph32(ph) => (ph.virtual_addr as usize, ph.mem_size as usize, ph.flags),
ProgramHeader::Ph64(ph) => (ph.virtual_addr as usize, ph.mem_size as usize, ph.flags),//???
};
set.push(MemoryArea::new(virt_addr, virt_addr + mem_size, memory_attr_from(flags), ""));
}
set
}
fn memory_attr_from(elf_flags: Flags) -> MemoryAttr {
let mut flags = MemoryAttr::default().user();
// TODO: handle readonly
if elf_flags.is_execute() { flags = flags.execute(); }
flags
}
/*
* @param:
* memory_set: the target MemorySet to set swappable
* @brief:
* map the memory area in the memory_set swappalbe, specially for the user process
*/
fn memory_set_map_swappable(memory_set: &mut MemorySet){
let pt = unsafe {
memory_set.get_page_table_mut() as *mut InactivePageTable0
};
for area in memory_set.iter(){
for page in Page::range_of(area.get_start_addr(), area.get_end_addr()) {
let addr = page.start_address();
active_table_swap().set_swappable(pt, addr);
}
}
info!("Finishing setting pages swappable");
}