M2: System call interface

The aim of this milestone is to design the RPC protocol for the system call interface. You should implement both the client and system side of this interface. This client-side system-call interface must conform to the interface provided in projects/aos/libsosapi/include. You will be adding to the code in projects/aos/libsosapi/src/sos.c that will eventually contain the implementation of the client-side sos.h interface within the library.

musl libc and sos

libsosapi defines two kinds of syscalls. Some are prefixed with sos_sys_ and others are prefixed with just sos_. Syscalls starting with sos_sys_ are called as a result of invoking musl C library functions. Syscalls starting with just sos_ have no C library wrapper and your application code will either invoke them directly, or you can write your own wrappers.

For example, the shell does not call sos_sys_open directly. Instead it uses the standard C library open function (it could also have used fopen), musl libc will translate this into an internal call to a POSIX style open syscall, which is implemented in the sys_open function in projects/aos/libsosapi/src/sys_stdio.c. This function is a small wrapper to extract arguments out of a va_list and call your sos_sys_open function.

Not all syscalls have been implemented through musl libc as in some cases the POSIX semantics are unnecessarily complex. You are free to implement more of the functionality in any of the syscalls defined in projects/aos/libsosapi/src/sys_*.c or implement additional syscalls by initialising them in sosapi_init_syscall_table.

At this stage you will not actually be able to implement most of the SOS (server-side) system calls, however you should be able to partially implement sos_sys_open/sos_sys_close, sos_sys_read/sos_sys_write for the console device. You should also implement sos_sys_usleep and sos_sys_time_stamp. In other words, you need to modify your timer driver to be able to sleep and wake up sosh. This will allow you to run a simple shell on your system, which will allow you to perform interactive testing.

Other system calls defined in sos.h should output system call not implemented.

Console device

When a program opens the file console it should access the console on the serial device. The console is a multiple writer, single reader device, i.e., more than one process can concurrently open the device for writing, but only one process can open the device for reading.

Reading the console is a blocking operation. If a process reads from the console and there is no data available it should block until data becomes available. If a new line character is encountered, the data returned should include all characters up to and including the new line character. Any remaining characters should be returned on the next read.

Be careful not to implement the console device as a 'hack'. You should think about being able to support multiple serial ports and other stream devices in your design (although not necessarily implement them). This means designing a consistent interface for interacting with all devices. You may want to read up on how Linux treats devices.

You may once again find the documentation on libserial handy.

Getting started

You will need to modify the libsosapi library to add implementations of the interface defined in projects/aos/libsosapi/include/sos.h. You should copy the contents of tty_test/ttyout.c to projects/aos/libsosapi/src/sos.c to import your sos_write implementation from M0.

In order to load the sosh app instead of tty_test you should pass "sosh" to start_first_process instead of "tty_test".

Design alternatives

At this stage of the project you will need to decide whether you want to have a simple single-threaded server, or to multi-thread it. A multi-threaded design could be advantageous to deal with the inherent concurrency your system will have (e.g. between paging, system calls, asynchronous I/O and clock interrupts), but it will require careful design of synchronisation in order to avoid race conditions and deadlocks. A single threaded model will require extra attention to ensure liveness.

Another design decision is how to transfer data between the kernel and user processes. Some options you have are:

Whatever you do, remember the basic engineering rule: keep it simple, stupid! (KISS).


This milestone is larger than it seems. The system call interface of an OS determines how user applications receive data they request. You will need to consider how you can move data in various quantities between your root server and clients. Scenarios to consider include:

Recall also that the OS can't rely on applications for correctness. Any system call you add should behave gracefully in the presence of a malicious application - i.e. use error checking on system call arguments, and returns errors when encountering problems.

Later, when you OS is managing multiple concurrent processes, you will need to be able to service operations for processes in various different states. This will involve having one or more processes blocked waiting for responses to system calls (such as timer and file operations) whilst other processes must continue to run. You will also need to be able to stop and remove processes that may either be blocked or running.

It is important to think about how you will represent processes that are blocked and waiting on system calls so that these situations are handled correctly.



For this assessment you should be able to demonstrate sosh running, and SOS outputting system call not implemented for the relevant SOS system calls.

sosh makes use of the SOS system calls in its ls and ps commands. This should be sufficient to demonstrate that your SOS system calls work. Of course, you can also write your own test code, but ensure that your solution also works with an unmodified sosh.

You should also show some sos application-level test code that uses the time_stamp and sleep system calls. sosh also has some sample commands for sleeping and getting the current time via different libc functions. The sleep implementation must use your clock driver.

The code below is the minimum demo to pass the milestone. Note that this code is not comprehensive, for best chances in the final marking you should test your sos_ interface extensively (edge and error cases).

#define SMALL_BUF_SZ 2
#define MEDIUM_BUF_SZ 256

char test_str[] = "Basic test string for read/write";
char small_buf[SMALL_BUF_SZ];

int test_buffers(int console_fd) {
   /* test a small string from the code segment */
   int result = sos_sys_write(console_fd, test_str, strlen(test_str));
   assert(result == strlen(test_str));

   /* test reading to a small buffer */
   result = sos_sys_read(console_fd, small_buf, SMALL_BUF_SZ);
   /* make sure you type in at least SMALL_BUF_SZ */
   assert(result == SMALL_BUF_SZ);

   /* test reading into a large on-stack buffer */
   char stack_buf[MEDIUM_BUF_SZ];
   /* for this test you'll need to paste a lot of data into
      the console, without newlines */

   result = sos_sys_read(console_fd, &stack_buf, MEDIUM_BUF_SZ);
   assert(result == MEDIUM_BUF_SZ);

   result = sos_sys_write(console_fd, &stack_buf, MEDIUM_BUF_SZ);
   assert(result == MEDIUM_BUF_SZ);

   /* try sleeping */
   for (int i = 0; i < 5; i++) {
       time_t prev_seconds = time(NULL);
       time_t next_seconds = time(NULL);
       assert(next_seconds > prev_seconds);

As always, you should be able to explain both the design and your implementation.

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