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osblog/risc_v/src/syscall.rs

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2020-03-16 04:18:46 +04:00
// syscall.rs
// System calls
// Stephen Marz
// 3 Jan 2020
use crate::{block::block_op,
cpu::{dump_registers, TrapFrame},
minixfs,
page::{virt_to_phys, Table},
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process::{delete_process, get_by_pid, set_sleeping, set_waiting}};
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/// do_syscall is called from trap.rs to invoke a system call. No discernment is
/// made here whether this is a U-mode, S-mode, or M-mode system call.
/// Since we can't do anything unless we dereference the passed pointer,
/// I went ahead and made the entire function unsafe.
/// If we return 0 from this function, the m_trap function will schedule
/// the next process--consider this a yield. A non-0 is the program counter
/// we want to go back to.
pub unsafe fn do_syscall(mepc: usize, frame: *mut TrapFrame) -> usize {
// Libgloss expects the system call number in A7, so let's follow
// their lead.
// A7 is X17, so it's register number 17.
let syscall_number = (*frame).regs[17];
match syscall_number {
0 | 93 => {
// Exit
delete_process((*frame).pid as u16);
0
},
2 => {
// Easy putchar
print!("{}", (*frame).regs[10] as u8 as char);
mepc + 4
},
8 => {
dump_registers(frame);
mepc + 4
},
10 => {
// Sleep
set_sleeping((*frame).pid as u16, (*frame).regs[10]);
0
},
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<<<<<<< HEAD
11 => {
// Add process to the scheduler. This is obviously insecure and
// we wouldn't do this realistically.
let my_proc = (*frame).regs[10] as *const Process;
if PROCESS_LIST_MUTEX.try_lock() {
if let Some(mut pl) = PROCESS_LIST.take() {
// As soon as we push this process on the list, it'll be
// schedule-able.
pl.push_back(my_proc.read());
PROCESS_LIST.replace(pl);
}
PROCESS_LIST_MUTEX.unlock();
(*frame).regs[10] = 1;
}
else {
(*frame).regs[10] = 0;
}
mepc + 4
},
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=======
>>>>>>> parent of fe5a909... Create a system call to add a process to prevent data race with the process list.
63 => {
// Read system call
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// This is an asynchronous call. This will get the
// process going. We won't hear the answer until
// we an interrupt back.
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// TODO: The buffer is a virtual memory address that
// needs to be translated to a physical memory location.
// This needs to be put into a process and ran.
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// The buffer (regs[12]) needs to be translated when ran
// from a user process using virt_to_phys. If this turns
// out to be a page fault, we need to NOT proceed with
// the read!
let mut physical_buffer = (*frame).regs[12];
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// If the MMU is turned on, we have to translate the
// address. Eventually, I will put this code into a
// convenient function, but for now, it will show how
// translation will be done.
if (*frame).satp != 0 {
let p = get_by_pid((*frame).pid as u16);
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let table = ((*p).get_table_address()
as *mut Table)
.as_ref()
.unwrap();
let paddr =
virt_to_phys(table, (*frame).regs[12]);
if paddr.is_none() {
(*frame).regs[10] = -1isize as usize;
return mepc + 4;
}
physical_buffer = paddr.unwrap();
}
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// TODO: Not only do we need to check the buffer, but it
// is possible that the buffer spans multiple pages. We
// need to check all pages that this might span. We
// can't just do paddr and paddr + size, since there
// could be a missing page somewhere in between.
let _ = minixfs::process_read(
(*frame).pid as u16,
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(*frame).regs[10]
as usize,
(*frame).regs[11] as u32,
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physical_buffer
as *mut u8,
(*frame).regs[13] as u32,
(*frame).regs[14] as u32,
);
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// If we return 0, the trap handler will schedule
// another process.
0
},
180 => {
// println!(
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// "Pid: {}, Dev: {}, Buffer: 0x{:x}, Size: {},
// Offset: {}", (*frame).pid,
// (*frame).regs[10],
// (*frame).regs[11],
// (*frame).regs[12],
// (*frame).regs[13]
// );
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set_waiting((*frame).pid as u16);
let _ = block_op(
(*frame).regs[10],
(*frame).regs[11] as *mut u8,
(*frame).regs[12] as u32,
(*frame).regs[13] as u64,
false,
(*frame).pid as u16,
);
0
},
_ => {
println!("Unknown syscall number {}", syscall_number);
mepc + 4
},
}
}
extern "C" {
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fn make_syscall(sysno: usize,
arg0: usize,
arg1: usize,
arg2: usize,
arg3: usize,
arg4: usize,
arg5: usize)
-> usize;
}
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fn do_make_syscall(sysno: usize,
arg0: usize,
arg1: usize,
arg2: usize,
arg3: usize,
arg4: usize,
arg5: usize)
-> usize
{
unsafe { make_syscall(sysno, arg0, arg1, arg2, arg3, arg4, arg5) }
}
pub fn syscall_exit() {
let _ = do_make_syscall(93, 0, 0, 0, 0, 0, 0);
}
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pub fn syscall_fs_read(dev: usize,
inode: u32,
buffer: *mut u8,
size: u32,
offset: u32)
-> usize
{
do_make_syscall(
63,
dev,
inode as usize,
buffer as usize,
size as usize,
offset as usize,
0,
)
}
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pub fn syscall_block_read(dev: usize,
buffer: *mut u8,
size: u32,
offset: u32)
-> u8
{
do_make_syscall(
180,
dev,
buffer as usize,
size as usize,
offset as usize,
0,
0,
) as u8
}
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pub fn syscall_sleep(duration: usize)
{
let _ = do_make_syscall(10, duration, 0, 0, 0, 0, 0);
}
pub fn syscall_add_process(process: Process) -> bool {
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// Thid doesn't quite work since we move process which causes it to drop :(
1 == do_make_syscall(11, &process as *const Process as usize, 0, 0, 0, 0, 0)
}
// These system call numbers come from libgloss so that we can use newlib
// for our system calls.
// Libgloss wants the system call number in A7 and arguments in A0..A6
// #define SYS_getcwd 17
// #define SYS_dup 23
// #define SYS_fcntl 25
// #define SYS_faccessat 48
// #define SYS_chdir 49
// #define SYS_openat 56
// #define SYS_close 57
// #define SYS_getdents 61
// #define SYS_lseek 62
// #define SYS_read 63
// #define SYS_write 64
// #define SYS_writev 66
// #define SYS_pread 67
// #define SYS_pwrite 68
// #define SYS_fstatat 79
// #define SYS_fstat 80
// #define SYS_exit 93
// #define SYS_exit_group 94
// #define SYS_kill 129
// #define SYS_rt_sigaction 134
// #define SYS_times 153
// #define SYS_uname 160
// #define SYS_gettimeofday 169
// #define SYS_getpid 172
// #define SYS_getuid 174
// #define SYS_geteuid 175
// #define SYS_getgid 176
// #define SYS_getegid 177
// #define SYS_brk 214
// #define SYS_munmap 215
// #define SYS_mremap 216
// #define SYS_mmap 222
// #define SYS_open 1024
// #define SYS_link 1025
// #define SYS_unlink 1026
// #define SYS_mkdir 1030
// #define SYS_access 1033
// #define SYS_stat 1038
// #define SYS_lstat 1039
// #define SYS_time 1062
// #define SYS_getmainvars 2011