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Solaris Dynamic Tracing Guide
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Document Information


1.  Introduction

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

Principal Buffers

Principal Buffer Policies

switch Policy

fill Policy

fill Policy and END Probes

ring Policy

Other Buffers

Buffer Sizes

Buffer Resizing Policy

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



Principal Buffer Policies

DTrace permits tracing in highly constrained contexts in the kernel. In particular, DTrace permits tracing in contexts in which kernel software may not reliably allocate memory. The consequence of this flexibility of context is that there always exists a possibility that DTrace will attempt to trace data when there isn't space available. DTrace must have a policy to deal with such situations when they arise, but you might wish to tune the policy based on the needs of a given experiment. Sometimes the appropriate policy might be to discard the new data. Other times it might be desirable to reuse the space containing the oldest recorded data to trace new data. Most often, the desired policy is to minimize the likelihood of running out of available space in the first place. To accommodate these varying demands, DTrace supports several different buffer policies. This support is implemented with the bufpolicy option, and can be set on a per-consumer basis. See Chapter 16, Options and Tunables for more details on setting options.

switch Policy

By default, the principal buffer has a switch buffer policy. Under this policy, per-CPU buffers are allocated in pairs: one buffer is active and the other buffer is inactive. When a DTrace consumer attempts to read a buffer, the kernel firsts switches the inactive and active buffers. Buffer switching is done in such a manner that there is no window in which tracing data may be lost. Once the buffers are switched, the newly inactive buffer is copied out to the DTrace consumer. This policy assures that the consumer always sees a self-consistent buffer: a buffer is never simultaneously traced to and copied out. This technique also avoids introducing a window in which tracing is paused or otherwise prevented. The rate at which the buffer is switched and read out is controlled by the consumer with the switchrate option. As with any rate option, switchrate may be specified with any time suffix, but defaults to rate-per-second. For more details on switchrate and other options, see Chapter 16, Options and Tunables.

Note - To process the principal buffer at user-level at a rate faster than the default of once per second, tune the value of switchrate. The system processes actions that induce user-level activity (such as printa() and system()) when the corresponding record in the principal buffer is processed. The value of switchrate dictates the rate at which the system processes such actions.

Under the switch policy, if a given enabled probe would trace more data than there is space available in the active principal buffer, the data is dropped and a per-CPU drop count is incremented. In the event of one or more drops, dtrace(1M) displays a message similar to the following example:

dtrace: 11 drops on CPU 0

If a given record is larger than the total buffer size, the record will be dropped regardless of buffer policy. You can reduce or eliminate drops by either increasing the size of the principal buffer with the bufsize option or by increasing the switching rate with the switchrate option.

Under the switch policy, scratch space for copyin(), copyinstr(), and alloca() is allocated out of the active buffer.

fill Policy

For some problems, you might wish to use a single in-kernel buffer. While this approach can be implemented with the switch policy and appropriate D constructs by incrementing a variable in D and predicating an exit() action appropriately, such an implementation does not eliminate the possibility of drops. To request a single, large in-kernel buffer, and continue tracing until one or more of the per-CPU buffers has filled, use the fill buffer policy. Under this policy, tracing continues until an enabled probe attempts to trace more data than can fit in the remaining principal buffer space. When insufficient space remains, the buffer is marked as filled and the consumer is notified that at least one of its per-CPU buffers has filled. Once dtrace(1M) detects a single filled buffer, tracing is stopped, all buffers are processed and dtrace exits. No further data will be traced to a filled buffer even if the data would fit in the buffer.

To use the fill policy, set the bufpolicy option to fill. For example, the following command traces every system call entry into a per-CPU 2K buffer with the buffer policy set to fill:

# dtrace -n syscall:::entry -b 2k -x bufpolicy=fill
fill Policy and END Probes

END probes normally do not fire until tracing has been explicitly stopped by the DTrace consumer. END probes are guaranteed to only fire on one CPU, but the CPU on which the probe fires is undefined. With fill buffers, tracing is explicitly stopped when at least one of the per-CPU principal buffers has been marked as filled. If the fill policy is selected, the END probe may fire on a CPU that has a filled buffer. To accommodate END tracing in fill buffers, DTrace calculates the amount of space potentially consumed by END probes and subtracts this space from the size of the principal buffer. If the net size is negative, DTrace will refuse to start, and dtrace(1M) will output a corresponding error message:

dtrace: END enablings exceed size of principal buffer

The reservation mechanism ensures that a full buffer always has sufficient space for any END probes.

ring Policy

The DTrace ring buffer policy helps you trace the events leading up to a failure. If reproducing the failure takes hours or days, you might wish to keep only the most recent data. Once a principal buffer has filled, tracing wraps around to the first entry, thereby overwriting older tracing data. You establish the ring buffer by setting the bufpolicy option to the string ring:

# dtrace -s foo.d -x bufpolicy=ring

When used to create a ring buffer, dtrace(1M) will not display any output until the process is terminated. At that time, the ring buffer is consumed and processed. dtrace processes each ring buffer in CPU order. Within a CPU's buffer, trace records will be displayed in order from oldest to youngest. Just as with the switch buffering policy, no ordering exists between records from different CPUs are made. If such an ordering is required, you should trace the timestamp variable as part of your tracing request.

The following example demonstrates the use of a #pragma option directive to enable ring buffering:

#pragma D option bufpolicy=ring
#pragma D option bufsize=16k

/execname == $1/