Friendly Apps Share Data

This tutorial covers how to use Tock's IPC mechanism to allow applications to communicate and share memory.

Tock IPC Basics

IPC in Tock uses a client-server model. Applications can provide a service by telling the Tock kernel that they provide a service. Each application can only provide a single service, and that service's name is set to the name of the application. Other applications can then discover that service and explicitly share a buffer with the server. Once a client shares a buffer, it can then notify the server to instruct the server to somehow interact with the shared buffer. The protocol for what the server should do with the buffer is service specific and not specified by Tock. Servers can also notify clients, but when and why servers notify clients is service specific.

Example Application

To provide an overview of IPC, we will build an example system consisting of three apps: a random number service, a LED control service, and a main application that uses the two services. While simple, this example both demonstrates the core aspects of the IPC mechanism and should run on any hardware platform.

LED Service

Lets start with the LED service. The goal of this service is to allow other applications to use the shared buffer as a command message to instruct the LED service on how to turn on or off the system's LEDs.

1. We must tell the kernel that our app wishes to provide a service. All that we have to do is call ipc_register_svc().

   #include "ipc.h"
   
   int main(void) {
     ipc_register_svc(ipc_callback, NULL);
     return 0;
   }
   

2. We also need that callback (ipc_callback) to handle IPC requests from other applications. This callback will be called when the client app notifies the service.

   static void ipc_callback(int pid, int len, int buf, void* ud) {
     // pid: An identifier for the app that notified us.
     // len: How long the buffer is that the client shared with us.
     // buf: Pointer to the shared buffer.
   }
   

3. Now lets fill in the callback for the LED application. This is a simplified version for illustration. The full example can be found in the examples/tutorials folder.

   #include "led.h"
   
   static void ipc_callback(int pid, int len, int buf, void* ud) {
     uint8_t* buffer = (uint8_t*) buf;
   
     // First byte is the command, second byte is the LED index to set,
     // and the third byte is whether the LED should be on or off.
     uint8_t command = buffer[0];
     if (command == 1) {
         uint8_t led_id = buffer[1];
         uint8_t led_state = buffer[2] > 0;
   
         if (led_state == 0) {
           led_off(led_id);
         } else {
           led_on(led_id);
         }
   
         // Tell the client that we have finished setting the specified LED.
         ipc_notify_client(pid);
         break;
     }
   }
   

RNG Service

The RNG service returns the requested number of random bytes in the shared folder.

1. Again, register that this service exists.

   int main(void) {
     ipc_register_svc(ipc_callback, NULL);
     return 0;
   }
   

2. Also need a callback function for when the client signals the service. The client specifies how many random bytes it wants by setting the first byte of the shared buffer before calling notify.

   #include <rng.h>
   
   static void ipc_callback(int pid, int len, int buf, void* ud) {
     uint8_t* buffer = (uint8_t*) buf;
     uint8_t rng[len];
   
     uint8_t number_of_bytes = buffer[0];
   
     // Fill the buffer with random bytes.
     int number_of_bytes_received = rng_sync(rng, len, number_of_bytes);
     memcpy(buffer, rng, number_of_bytes_received);
   
     // Signal the client that we have the number of random bytes requested.
     ipc_notify_client(pid);
   }
   

   This is again not a complete example but illustrates the key aspects.

Main Logic Client Application

The third application uses the two services to randomly control the LEDs on the board. This application is not a server but instead is a client of the two service applications.

1. When using an IPC service, the first step is to discover the service and record its identifier. This will allow the application to share memory with it and notify it. Services are discovered by the name of the application that provides them. Currently these are set in the application Makefile or by default based on the folder name of the application. The examples in Tock commonly use a Java style naming format.

   int main(void) {
     int led_service = ipc_discover("org.tockos.tutorials.ipc.led");
     int rng_service = ipc_discover("org.tockos.tutorials.ipc.rng");
   
     return 0;
   }
   

   If the services requested are valid and exist the return value from ipc_discover is the identifier of the found service. If the service cannot be found an error is returned.

2. Next we must share a buffer with each service (the buffer is the only way to share between processes), and setup a callback that is called when the server notifies us as a client. Once shared, the kernel will permit both applications to read/modify that memory.

   char led_buf[64] __attribute__((aligned(64)));
   char rng_buf[64] __attribute__((aligned(64)));
   
   int main(void) {
     int led_service = ipc_discover("org.tockos.tutorials.ipc.led");
     int rng_service = ipc_discover("org.tockos.tutorials.ipc.rng");
   
     // Setup IPC for LED service
     ipc_register_client_cb(led_service, ipc_callback, NULL);
     ipc_share(led_service, led_buf, 64);
   
     // Setup IPC for RNG service
     ipc_register_client_cb(rng_service, ipc_callback, NULL);
     ipc_share(rng_service, rng_buf, 64);
   
     return 0;
   }
   

3. We of course need the callback too. For this app we use the yield_for function to implement the logical synchronously, so all the callback needs to do is set a flag to signal the end of the yield_for.

   bool done = false;
   
   static void ipc_callback(int pid, int len, int arg2, void* ud) {
     done = true;
   }
   

4. Now we use the two services to implement our application.

   #include <timer.h>
   
   void app() {
     while (1) {
       // Get two random bytes from the RNG service
       done = false;
       rng_buf[0] = 2; // Request two bytes.
       ipc_notify_svc(rng_service);
       yield_for(&done);
   
       // Control the LEDs based on those two bytes.
       done = false;
       led_buf[0] = 1;                     // Control LED command.
       led_buf[1] = rng_buf[0] % NUM_LEDS; // Choose the LED index.
       led_buf[2] = rng_buf[1] & 0x01;     // On or off.
       ipc_notify_svc(led_service);        // Notify to signal LED service.
       yield_for(&done);
   
       delay_ms(500);
     }
   }
   

Try It Out

To test this out, see the complete apps in the IPC tutorial example folder.

To install all of the apps on a board:

$ cd examples/tutorials/05_ipc
$ tockloader erase-apps
$ pushd led && make && tockloader install && popd
$ pushd rng && make && tockloader install && popd
$ pushd logic && make && tockloader install && popd

You should see the LEDs randomly turning on and off!