Difference between revisions of "The TinyOS printf Library"
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The entire <code>printf</code> library consists of only 4 files located in the <code>tos/lib/printf/2_0_2</code> directory: one module, one configuration, one interface file, and one header file. | The entire <code>printf</code> library consists of only 4 files located in the <code>tos/lib/printf/2_0_2</code> directory: one module, one configuration, one interface file, and one header file. | ||
+ | * '''MainC.nc''' -- A shadowed version of the MainC system component that wires in and automatically powers up the printf subsystem | ||
* '''PrintfC.nc''' -- Configuration file providing printf functionality to TinyOS applications | * '''PrintfC.nc''' -- Configuration file providing printf functionality to TinyOS applications | ||
* '''PrintfP.nc''' -- Module implementing the printf functionality | * '''PrintfP.nc''' -- Module implementing the printf functionality | ||
− | |||
* '''printf.h''' -- Header file specifying the printf message format and size of the flush buffer | * '''printf.h''' -- Header file specifying the printf message format and size of the flush buffer | ||
+ | <br> | ||
− | + | Printf functionality can be added to any application by simply #including the 'printf.h' header file. After this header file has been included, <code>printf</code> commands can be invoked by calling <code>printf()</code>, and flush commands can be invoked by calling <code>printfflush</code>. | |
+ | <br> | ||
− | < | + | Below is a graph of the <code>MainC</code> and <code>PrintfC</code> configurations that make this all possible. The <code>MainC</code> component redirects the <code>Boot.booted()</code> event through the <code>PrintfC</code> component so that it can power up the serial port and get the printf buffer initialized for printing: |
− | '''Figure 1: The component graph of the PrintfC | + | <center>[[Image:mainc_printf_components.png| 350px]] [[Image:printf_components_2.1.png | 550px]] |
+ | |||
+ | '''Figure 1: The component graph of the MaincC and PrintfC configurations.''' | ||
</center> | </center> | ||
− | Conceptually, the operation of the TinyOS <code>printf</code> library is very simple. Developers supply strings to <code>printf()</code> commands in a distributed fashion throughout any of the components that make up a complete TinyOS application. These strings are buffered in a central location inside the <code>PrintfP</code> component and flushed out to a PC in the form of TinyOS SerialMessages upon calling | + | Conceptually, the operation of the TinyOS <code>printf</code> library is very simple. Developers supply strings to <code>printf()</code> commands in a distributed fashion throughout any of the components that make up a complete TinyOS application. These strings are buffered in a central location inside the <code>PrintfP</code> component and flushed out to a PC in the form of TinyOS SerialMessages upon calling a <code>printfflush()</code> command. No nesC interfaces are required, and both the <code>printf()</code> and <code>printfflush()</code> commands can be called in c-fashion by simply including the 'printf.h' header file. |
− | |||
− | |||
− | + | By encapsulating the strings produced by calls to <code>printf()</code> inside standard TinyOS SerialMessages, applications that use the serial stack for other purposes can share the use of the serial port. Alternate implementations were considered in which <code>printf</code> would have had exclusive access to the serial port. In the end, we felt it was better to give developers the freedom to decide exactly when messages should be printed, as well as allow them to send multiple types of SerialMessages in a single application. | |
− | + | A circular buffer is used to store the strings supplied to <code>printf()</code> before flushing them. This means that while the buffer is being flushed, calls to <code>printf</code> will still continue to succeed. The default buffer size is 250 bytes, and flushing is automatically performed whenever this buffer becomes more than half full. Explicit flushing is also possible by making calls to <code>printfflush()</code>. Most applications can get away with the automatic flushing capabilities, but explicit flushing is still recommended in applications where the sections of code under examinatation are very timing sensitive (e.g. inside the CC2420 radio stack). | |
=Using the TinyOS <code>printf</code> Library= | =Using the TinyOS <code>printf</code> Library= |
Revision as of 14:25, 23 June 2008
This lesson demonstrates how to use the newest version of the printf
library located in tos/lib/printf
to debug TinyOS applications by printing messages over the serial port.
This tutorial replaces older versions of the tutorial written for previous versions of TinyOS.
Legacy versions are listed below:
Overview
Anyone familiar with TinyOS knows that debugging applications has traditionally been a very arduous, if not stressful process. While simulators like TOSSIM can be used to help verify the logical correctness of a program, unforseen problems inevitably arise once that program is deployed on real hardware. Debugging such a program typically involves flashing the three available LEDs in some intricate sequence or resorting to line by line analysis of a running program through the use of a JTAG.
It is common practice when developing desktop applications to print output to the terminal screen for debugging purposes. While tools such as gdb
provide means of stepping though a program line by line, often times developers simply want to quickly print something to the screen to verify that the value of a variable has been set correctly, or determine that some sequence of events is being run in the proper order. It would be absurd to suggest that they only be allowed three bits of information in order to do so.
The TinyOS printf
library provides this terminal printing functionality to TinyOS applications through motes connected to a pc via their serial interface. Messages are printed by calling printf
commands using a familiar syntax borrowed from the C programming language. In order to use this functionality, developers simply need to include a single component in their top level configuration file (PrintfC
), and include a "printf.h"
header file in any components that actually call printf()
.
Currently, the printf
library is only supported on msp430 and atmega128x based platforms (e.g. mica2, micaZ, telos, eyesIFX). In the future we hope to add support for other platforms as well.
The TinyOS printf
Library
This section provides a basic overview of the TinyOS printf
library, including the components that make it up and the interfaces they provide. In the following section we walk you through the process of actually using these components to print messages from a mote to your pc. If you dont care how printf
works and only want to know how to use it, feel free to skip ahead to the next section.
The entire printf
library consists of only 4 files located in the tos/lib/printf/2_0_2
directory: one module, one configuration, one interface file, and one header file.
- MainC.nc -- A shadowed version of the MainC system component that wires in and automatically powers up the printf subsystem
- PrintfC.nc -- Configuration file providing printf functionality to TinyOS applications
- PrintfP.nc -- Module implementing the printf functionality
- printf.h -- Header file specifying the printf message format and size of the flush buffer
Printf functionality can be added to any application by simply #including the 'printf.h' header file. After this header file has been included, printf
commands can be invoked by calling printf()
, and flush commands can be invoked by calling printfflush
.
Below is a graph of the MainC
and PrintfC
configurations that make this all possible. The MainC
component redirects the Boot.booted()
event through the PrintfC
component so that it can power up the serial port and get the printf buffer initialized for printing:
Figure 1: The component graph of the MaincC and PrintfC configurations.
Conceptually, the operation of the TinyOS printf
library is very simple. Developers supply strings to printf()
commands in a distributed fashion throughout any of the components that make up a complete TinyOS application. These strings are buffered in a central location inside the PrintfP
component and flushed out to a PC in the form of TinyOS SerialMessages upon calling a printfflush()
command. No nesC interfaces are required, and both the printf()
and printfflush()
commands can be called in c-fashion by simply including the 'printf.h' header file.
By encapsulating the strings produced by calls to printf()
inside standard TinyOS SerialMessages, applications that use the serial stack for other purposes can share the use of the serial port. Alternate implementations were considered in which printf
would have had exclusive access to the serial port. In the end, we felt it was better to give developers the freedom to decide exactly when messages should be printed, as well as allow them to send multiple types of SerialMessages in a single application.
A circular buffer is used to store the strings supplied to printf()
before flushing them. This means that while the buffer is being flushed, calls to printf
will still continue to succeed. The default buffer size is 250 bytes, and flushing is automatically performed whenever this buffer becomes more than half full. Explicit flushing is also possible by making calls to printfflush()
. Most applications can get away with the automatic flushing capabilities, but explicit flushing is still recommended in applications where the sections of code under examinatation are very timing sensitive (e.g. inside the CC2420 radio stack).
Using the TinyOS printf
Library
To help guide the process of using the printf
library, a TestPrintf
application has been created. At present, this application is not included in the official TinyOS distribution (<= 2.0.2). If you are using TinyOS from a cvs checkout, you will find it located under apps/tutorials/Printf
. Otherwise, you can obtain it from cvs by running the following set of commands from a terminal window:
cd $TOSROOT/apps/tutorials cvs -d:pserver:anonymous@tinyos.cvs.sourceforge.net:/cvsroot/tinyos login cvs -z3 -d:pserver:anonymous@tinyos.cvs.sourceforge.net:/cvsroot/tinyos co -P -d Printf tinyos-2.x/apps/tutorials/Printf
Just hit enter when prompted for a CVS password. You do not need to enter one.
If you are not using cvs, you will also have to apply the patch found here in order to allow the printf
library to compile correctly for atmega128x based platforms (i.e. mica2, micaz):
cp tinyos-2.0-printf.patch $TOSROOT/.. cd $TOSROOT/.. patch -p0 < tinyos-2.0-printf.patch
Note that you may have to use 'sudo' when applying the patch if you run into permission problems.
The TestPrintf
application demonstrates everything necessary to use the printf
library. Go ahead and open the TestPrintfAppC
configuration to see how the various interfaces provided by the PrintfC
component have been wired in. You will want to do something similar in your own applications.
configuration TestPrintfAppC{ } implementation { components MainC, TestPrintfC, LedsC; components PrintfC; TestPrintfC.Boot -> MainC; TestPrintfC.Leds -> LedsC; TestPrintfC.PrintfControl -> PrintfC; TestPrintfC.PrintfFlush -> PrintfC; }
First, the PrintfControl
interface has been wired in to enable turning on and off the service providing printf
functionality. Turning on the Printf
service implicity turns on the serial port for sending messages. Second, the PrintfFlush
interface has been wired in to allow the application to control when printf
messages should be flushed out over the serial line. In this application, all printf()
commands are called directly within the TestPrintfC
component. In general, printf()
commands can be called from any component as long as they have included the "printf.h"
header file.
Before examining the TestPrintfC
component, first install the application on a mote and see what kind of output it produces. Note that the instructions here are only valid for installation on a telosb mote on a linux based TinyOS distribution. For installation on other systems or for other mote platforms, please refer to lesson 1 for detailed instructions.
To install the application on the mote, run the following set of commands.
cd $TOSROOT\apps\tests\TestPrintf make telosb install bsl,/dev/ttyUSBXXX
You will notice during the installation process that a pair of java files are compiled along with the TinyOS application. The first java file, PrintfMsg.java
, is generated by mig
to encapsulate a TinyOS printf
message received over the serial line (for more information on mig and how it generates these files, please refer to the section entitled "MIG: generating packet objects" in lesson 4). The second file, PrintfClient.java
is used to read printf
messages received from a mote and print them to your screen.
To see the output generated by TestPrintf
you need to start the PrintfClient
by running the following command:
cd $TOSROOT\apps\tests\TestPrintf java PrintfClient -comm serial@/dev/ttyUSBXXX:telosb
After resetting the mote, the following output should be printed to your screen:
Hi I am writing to you from my TinyOS application!! Here is a uint8: 123 Here is a uint16: 12345 Here is a uint32: 1234567890 I am now iterating: 0 I am now iterating: 1 I am now iterating: 2 I am now iterating: 3 I am now iterating: 4 This is a really short string... I am generating this string to have just less than 250 characters since that is the limit of the size I put on my maximum buffer when I instantiated the PrintfC component. Only part of this line should get printed bec
Note that the 'tty' device (i.e. COM port) specified when starting the PrintfClient MUST be the one used for communicating with a mote over the serial line. On telos and mica motes this is the same port that the mote is programmed from. Other motes, such as eyesIFX, have one port dedicated to programming and another for communication. Just make sure you use the correct one.
If for some reason you do not receive the output shown above, please refer to lesson 4 to verify you have done everything necessary to allow serial communication between your pc and the mote. Remember that when using the MIB510 programming board that the switch on the very front of the board must be set to the OFF position in order to send messages from the mote to the pc.
Go ahead and open up TestPrintfC
to see how this output is being generated.
Upon receiving the booted event, the Printf
service is started via a call to PrintfControl.start()
event void Boot.booted() { call PrintfControl.start(); }
Once the Printf
service has been started, a PrintfControl.startDone()
event is generated. In the body of this event the first four lines of output are generated by making successive calls to printf
and then flushing the buffer they are stored in.
event void PrintfControl.startDone(error_t error) { printf("Hi I am writing to you from my TinyOS application!!\n"); printf("Here is a uint8: %u\n", dummyVar1); printf("Here is a uint16: %u\n", dummyVar2); printf("Here is a uint32: %ld\n", dummyVar3); call PrintfFlush.flush(); }
Once these first four lines have been flushed out, the PrintfFlush.flushDone()
event is signaled. The body of this event first prints the next 5 lines in a loop, followed by the last five lines. Finally, once all lines have been printed, the Printf
service is stopped via a call to PrintfControl.stop()
.
event void PrintfFlush.flushDone(error_t error) { if(counter < NUM_TIMES_TO_PRINT) { printf("I am now iterating: %d\n", counter); call PrintfFlush.flush(); } else if(counter == NUM_TIMES_TO_PRINT) { printf("This is a really short string...\n"); printf("I am generating this string to have just less ... printf("Only part of this line should get printed bec ... call PrintfFlush.flush(); } else call PrintfControl.stop(); counter++; }
Notice that the last line of output is cut short before being fully printed. If you actually read the line printed above it you can see why. The buffer used to store TinyOS printf
messages before they are flushed is by default limited to 250 bytes. If you try and print more characters than this before flushing, then only the first 250 characters will actually be printed. This buffer size is configurable, however, by specifying the proper CFLAGS option in your Makefile.
CFLAGS += -DPRINTF_BUFFER_SIZE=XXX
Once the the Printf
service has been stopped, the PrintfControl.stopDone()
event is signaled and Led 2 is turned on to signify that the application has terminated.
event void PrintfControl.stopDone(error_t error) { counter = 0; call Leds.led2Toggle(); printf("This should not be printed..."); call PrintfFlush.flush(); }
Notice that the call to printf()
inside the body of the PrintfControl.stopDone()
event never produces any output. This is because the Printf
service has been stopped before this command is called.
Conclusion
A few points are worthy of note before jumping in and writing your own applications that use the functionality provided by the printf
library.
- In order to use the
printf
library, thetos/lib/printf/2_0_2
directory must be in your include path. The easiest way to include it is by adding the following line directly within the Makefile of your top level application: - Remember that changing the
printf
buffer size is done similarly: - You MUST be sure to #include
"printf.h"
header file in every component in which you would like to call theprintf()
command. Failure to do so will result in obscure error messages making it difficult to identify the problem.
CFLAGS += -I$(TOSDIR)/lib/printf/2_0_2
CFLAGS += -DPRINTF_BUFFER_SIZE=XXX
Hopefully you now have everything you need to get going with the TinyOS printf
library. All questions (or comments) about the use of this library should be directed to tinyos-help mailing list.
Enjoy!!
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