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Solaris Dynamic Tracing Guide
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Document Information

Preface

1.  Introduction

Getting Started

Providers and Probes

Compilation and Instrumentation

Variables and Arithmetic Expressions

Predicates

Output Formatting

Arrays

External Symbols and Types

2.  Types, Operators, and Expressions

3.  Variables

4.  D Program Structure

5.  Pointers and Arrays

6.  Strings

7.  Structs and Unions

8.  Type and Constant Definitions

9.  Aggregations

10.  Actions and Subroutines

11.  Buffers and Buffering

12.  Output Formatting

13.  Speculative Tracing

14.  dtrace(1M) Utility

15.  Scripting

16.  Options and Tunables

17.  dtrace Provider

18.  lockstat Provider

19.  profile Provider

20.  fbt Provider

21.  syscall Provider

22.  sdt Provider

23.  sysinfo Provider

24.  vminfo Provider

25.  proc Provider

26.  sched Provider

27.  io Provider

28.  mib Provider

29.  fpuinfo Provider

30.  pid Provider

31.  plockstat Provider

32.  fasttrap Provider

33.  User Process Tracing

34.  Statically Defined Tracing for User Applications

35.  Security

36.  Anonymous Tracing

37.  Postmortem Tracing

38.  Performance Considerations

39.  Stability

40.  Translators

41.  Versioning

Glossary

Index

Predicates

One major difference between D and other programming languages such as C, C++, and the Java programming language is the absence of control-flow constructs such as if-statements and loops. D program clauses are written as single straight-line statement lists that trace an optional, fixed amount of data. D does provide the ability to conditionally trace data and modify control flow using logical expressions called predicates that can be used to prefix program clauses. A predicate expression is evaluated at probe firing time prior to executing any of the statements associated with the corresponding clause. If the predicate evaluates to true, represented by any non-zero value, the statement list is executed. If the predicate is false, represented by a zero value, none of the statements are executed and the probe firing is ignored.

Type the following source code for the next example and save it in a file named countdown.d:

dtrace:::BEGIN
{
    i = 10;
}

profile:::tick-1sec
/i > 0/
{
    trace(i--);
}

profile:::tick-1sec
/i == 0/
{
    trace("blastoff!");
    exit(0);
}

This D program implements a 10-second countdown timer using predicates. When executed, countdown.d counts down from 10 and then prints a message and exits:

# dtrace -s countdown.d
dtrace: script 'countdown.d' matched 3 probes
CPU     ID                    FUNCTION:NAME
    0  25499                       :tick-1sec        10
    0  25499                       :tick-1sec         9
    0  25499                       :tick-1sec         8
    0  25499                       :tick-1sec         7
    0  25499                       :tick-1sec         6
    0  25499                       :tick-1sec         5
    0  25499                       :tick-1sec         4
    0  25499                       :tick-1sec         3
    0  25499                       :tick-1sec         2
    0  25499                       :tick-1sec         1
    0  25499                       :tick-1sec   blastoff!
# 

This example uses the BEGIN probe to initialize an integer i to 10 to begin the countdown. Next, as in the previous example, the program uses the tick-1sec probe to implement a timer that fires once per second. Notice that in countdown.d, the tick-1sec probe description is used in two different clauses, each with a different predicate and action list. The predicate is a logical expression surrounded by enclosing slashes / / that appears after the probe name and before the braces { } that surround the clause statement list.

The first predicate tests whether i is greater than zero, indicating that the timer is still running:

profile:::tick-1sec
/i > 0/
{
    trace(i--);
}

The relational operator > means greater than and returns the integer value zero for false and one for true. All of the C relational operators are supported in D; the complete list is found in Chapter 2, Types, Operators, and Expressions. If i is not yet zero, the script traces i and then decrements it by one using the -- operator.

The second predicate uses the == operator to return true when i is exactly equal to zero, indicating that the countdown is complete:

profile:::tick-1sec
/i == 0/
{
    trace("blastoff!");
    exit(0);
}

Similar to the first example, hello.d, countdown.d uses a sequence of characters enclosed in double quotes, called a string constant, to print a final message when the countdown is complete. The exit() function is then used to exit dtrace and return to the shell prompt.

If you look back at the structure of countdown.d, you will see that by creating two clauses with the same probe description but different predicates and actions, we effectively created the logical flow:

i = 10 once per second, if i is greater than zero trace(i--); otherwise if i is equal to zero trace("blastoff!"); exit(0);

When you wish to write complex programs using predicates, try to first visualize your algorithm in this manner, and then transform each path of your conditional constructs into a separate clause and predicate.

Now let's combine predicates with a new provider, the syscall provider, and create our first real D tracing program. The syscall provider permits you to enable probes on entry to or return from any Solaris system call. The next example uses DTrace to observe every time your shell performs a read(2) or write(2) system call. First, open two terminal windows, one to use for DTrace and the other containing the shell process you're going to watch. In the second window, type the following command to obtain the process ID of this shell:

# echo $$
12345

Now go back to your first terminal window and type the following D program and save it in a file named rw.d. As you type in the program, replace 12345 with the process ID of the shell that was printed in response to your echo command.

syscall::read:entry,
syscall::write:entry
/pid == 12345/
{

}

Notice that the body of rw.d's probe clause is left empty because the program is only intended to trace notification of probe firings and not to trace any additional data. Once you're done typing in rw.d, use dtrace to start your experiment and then go to your second shell window and type a few commands, pressing return after each command. As you type, you should see dtrace report probe firings in your first window, similar to the following example:

# dtrace -s rw.d
dtrace: script 'rw.d' matched 2 probes
CPU     ID                    FUNCTION:NAME
    0     34                      write:entry 
    0     32                       read:entry 
    0     34                      write:entry 
    0     32                       read:entry 
    0     34                      write:entry 
    0     32                       read:entry 
    0     34                      write:entry 
    0     32                       read:entry 
...

You are now watching your shell perform read(2) and write(2) system calls to read a character from your terminal window and echo back the result! This example includes many of the concepts described so far and a few new ones as well. First, to instrument read(2) and write(2) in the same manner, the script uses a single probe clause with multiple probe descriptions by separating the descriptions with commas like this:

syscall::read:entry,
syscall::write:entry

For readability, each probe description appears on its own line. This arrangement is not strictly required, but it makes for a more readable script. Next the script defines a predicate that matches only those system calls that are executed by your shell process:

/pid == 12345/

The predicate uses the predefined DTrace variable pid, which always evaluates to the process ID associated with the thread that fired the corresponding probe. DTrace provides many built-in variable definitions for useful things like the process ID. Here is a list of a few DTrace variables you can use to write your first D programs:

Variable Name
Data Type
Meaning
errno
int
Current errno value for system calls
execname
string
Name of the current process's executable file
pid
pid_t
Process ID of the current process
tid
id_t
Thread ID of the current thread
probeprov
string
Current probe description's provider field
probemod
string
Current probe description's module field
probefunc
string
Current probe description's function field
probename
string
Current probe description's name field

Now that you've written a real instrumentation program, try experimenting with it on different processes running on your system by changing the process ID and the system call probes that are instrumented. Then, you can make one more simple change and turn rw.d into a very simple version of a system call tracing tool like truss(1). An empty probe description field acts as a wildcard, matching any probe, so change your program to the following new source code to trace any system call executed by your shell:

syscall:::entry
/pid == 12345/
{

}

Try typing a few commands in the shell such as cd, ls, and date and see what your DTrace program reports.