SDT(9) | Kernel Developer's Manual | SDT(9) |
NAME¶
SDT
— a DTrace
framework for adding statically-defined tracing probes
SYNOPSIS¶
#include
<sys/param.h>
#include <sys/queue.h>
#include <sys/sdt.h>
SDT_PROVIDER_DECLARE
(prov);
SDT_PROVIDER_DEFINE
(prov);
SDT_PROBE_DECLARE
(prov,
mod,
func,
name);
SDT_PROBE_DEFINE
(prov,
mod,
func,
name);
SDT_PROBE_DEFINE0
(prov,
mod,
func,
name);
SDT_PROBE_DEFINE1
(prov,
mod,
func,
name,
arg0);
SDT_PROBE_DEFINE2
(prov,
mod,
func,
name,
arg0,
arg1);
SDT_PROBE_DEFINE3
(prov,
mod,
func,
name,
arg0,
arg1,
arg2);
SDT_PROBE_DEFINE4
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3);
SDT_PROBE_DEFINE5
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3,
arg4);
SDT_PROBE_DEFINE6
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3,
arg4,
arg5);
SDT_PROBE_DEFINE7
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3,
arg4,
arg5,
arg6);
SDT_PROBE_DEFINE0_XLATE
(prov,
mod,
func,
name);
SDT_PROBE_DEFINE1_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0);
SDT_PROBE_DEFINE2_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0,
arg1,
xarg1);
SDT_PROBE_DEFINE3_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0,
arg1,
xarg1,
arg2,
xarg2);
SDT_PROBE_DEFINE4_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0,
arg1,
xarg1,
arg2,
xarg2,
arg3,
xarg3);
SDT_PROBE_DEFINE5_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0,
arg1,
xarg1,
arg2,
xarg2,
arg3,
xarg3,
arg4,
xarg4);
SDT_PROBE_DEFINE6_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0,
arg1,
xarg1,
arg2,
xarg2,
arg3,
xarg3,
arg4,
xarg4,
arg5,
xarg5);
SDT_PROBE_DEFINE7_XLATE
(prov,
mod,
func,
name,
arg0,
xarg0,
arg1,
xarg1,
arg2,
xarg2,
arg3,
xarg3,
arg4,
xarg4,
arg5,
xarg5,
arg6,
xarg6);
SDT_PROBE0
(prov,
mod,
func,
name);
SDT_PROBE1
(prov,
mod,
func,
name,
arg0);
SDT_PROBE2
(prov,
mod,
func,
name,
arg0,
arg1);
SDT_PROBE3
(prov,
mod,
func,
name,
arg0,
arg1,
arg2);
SDT_PROBE4
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3);
SDT_PROBE5
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3,
arg4);
SDT_PROBE6
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3,
arg4,
arg5);
SDT_PROBE7
(prov,
mod,
func,
name,
arg0,
arg1,
arg2,
arg3,
arg4,
arg5,
arg6);
DESCRIPTION¶
The SDT
macros allow programmers to define
static trace points in kernel code. These trace points are used by the
SDT
framework to create DTrace probes, allowing the
code to be instrumented using dtrace(1). By default,
SDT
trace points are disabled and have no effect on
the surrounding code. When a DTrace probe corresponding to a given trace
point is enabled, threads that execute the trace point will call a handler
and cause the probe to fire. Moreover, trace points can take arguments,
making it possible to pass data to the DTrace framework when an enabled
probe fires.
Multiple trace points may correspond to a single DTrace probe,
allowing programmers to create DTrace probes that correspond to logical
system events rather than tying probes to specific code execution paths. For
instance, a DTrace probe corresponding to the arrival of an IP packet into
the network stack may be defined using two SDT
trace
points: one for IPv4 packets and one for IPv6 packets.
In addition to defining DTrace probes, the
SDT
macros allow programmers to define new DTrace
providers, making it possible to namespace logically-related probes. An
example is FreeBSD's sctp provider, which contains
SDT
probes for FreeBSD's sctp(4)
implementation.
The
SDT_PROVIDER_DECLARE
()
and
SDT_PROVIDER_DEFINE
()
macros are used respectively to declare and define a DTrace provider named
prov with the SDT
framework. A
provider need only be defined once; however, the provider must be declared
before defining any SDT
probes belonging to that
provider.
Similarly, the
SDT_PROBE_DECLARE
()
and SDT_PROBE_DEFINE*
() macros are used to declare
and define DTrace probes using the SDT
framework.
Once a probe has been defined, trace points for that probe may be added to
kernel code. DTrace probe identifiers consist of a provider, module,
function and name, all of which may be specified in the
SDT
probe definition. Note that probes should not
specify a module name: the module name of a probe is used to determine
whether or not it should be destroyed when a kernel module is unloaded. See
the BUGS section. Note in particular that
probes must not be defined across multiple kernel modules.
If ‘-
’ character
(dash) is wanted in a probe name, then it should be represented as
‘__
’ (double underscore) in the probe
name parameter passed to various
SDT_*
()
macros, because of technical reasons (a dash is not valid in C
identifiers).
The
SDT_PROBE_DEFINE*
()
macros also allow programmers to declare the types of the arguments that are
passed to probes. This is optional; if the argument types are omitted
(through use of the
SDT_PROBE_DEFINE
()
macro), users wishing to make use of the arguments will have to manually
cast them to the correct types in their D scripts. It is strongly
recommended that probe definitions include a declaration of their argument
types.
The
SDT_PROBE_DEFINE*_XLATE
()
macros are used for probes whose argument types are to be dynamically
translated to the types specified by the corresponding
xarg arguments. This is mainly useful when porting
probe definitions from other operating systems. As seen by
dtrace(1), the arguments of a probe defined using these
macros will have types which match the xarg types in
the probe definition. However, the arguments passed in at the trace point
will have types matching the native argument types in the probe definition,
and thus the native type is dynamically translated to the translated type.
So long as an appropriate translator is defined in
/usr/lib/dtrace, scripts making use of the probe
need not concern themselves with the underlying type of a given
SDT
probe argument.
The
SDT_PROBE*
()
macros are used to create SDT
trace points. They are
meant to be added to executable code and can be used to instrument the code
in which they are called.
PROVIDERS¶
A number of kernel DTrace providers are available. In general,
these providers define stable interfaces and should be treated as such:
existing D scripts may be broken if a probe is renamed or its arguments are
modified. However, it is often useful to define ad-hoc
SDT
probes for debugging a subsystem or driver.
Similarly, a developer may wish to provide a group of
SDT
probes without committing to their future
stability. Such probes should be added to the
‘sdt
’ provider instead of defining a
new provider.
EXAMPLES¶
The DTrace providers available on the current system can be listed with
dtrace -l | sed 1d | awk '{print $2}' | sort -u
A detailed list of the probes offered by a given provider can be
obtained by specifying the provider using the -P
flag. For example, to view the probes and argument types for the
‘sched
’ provider, run
dtrace -lv -P sched
The following probe definition will create a DTrace probe called
‘icmp:::receive-unreachable
’, which
would hypothetically be triggered when the kernel receives an ICMP packet of
type Destination Unreachable:
SDT_PROVIDER_DECLARE(icmp); SDT_PROBE_DEFINE1(icmp, , , receive__unreachable, "struct icmp *");
Consider a DTrace probe which fires when the network stack receives an IP packet. Such a probe would be defined by multiple tracepoints:
SDT_PROBE_DEFINE3(ip, , , receive, "struct ifnet *", "struct ip *", "struct ip6_hdr *"); int ip_input(struct mbuf *m) { struct ip *ip; ... ip = mtod(m, struct ip *); SDT_PROBE3(ip, , , receive, m->m_pkthdr.rcvif, ip, NULL); ... } int ip6_input(struct mbuf *m) { struct ip6_hdr *ip6; ... ip6 = mtod(m, struct ip6_hdr *); SDT_PROBE3(ip, , , receive, m->m_pkthdr.rcvif, NULL, ip6); ... }
Consider the ICMP probe discussed above. We note that its second
argument is of type struct icmp, which is a type
defined in the FreeBSD kernel to represent the ICMP header of an ICMP
packet, defined in RFC 792. Linux has a corresponding type,
struct icmphdr, for the same purpose, but its field
names differ from FreeBSD's struct icmp. Similarly,
illumos defines the icmph_t type, again with different
field names. Even with the
‘icmp:::pkt-receive
’ probes defined in
all three operating systems, one would still have to write OS-specific
scripts to extract a given field out of the ICMP header argument.
Dynamically-translated types solve this problem: one can define an
OS-independent c(7) struct to represent an ICMP header,
say struct icmp_hdr_dt, and define translators from
each of the three OS-specific types to struct
icmp_hdr_dt, all in the dtrace(1) library path. Then
the FreeBSD probe above can be defined with:
SDT_PROBE_DEFINE1_XLATE(ip, , , receive, "struct icmp *", "struct icmp_hdr_dt *");
SEE ALSO¶
dtrace(1), dtrace_io(4), dtrace_ip(4), dtrace_proc(4), dtrace_sched(4), dtrace_tcp(4), dtrace_udp(4)
AUTHORS¶
DTrace and the SDT
framework were
originally ported to FreeBSD from Solaris by John
Birrell
<jb@FreeBSD.org>. This
manual page was written by Mark Johnston
<markj@FreeBSD.org>.
BUGS¶
The SDT
macros allow the module and
function names of a probe to be specified as part of a probe definition. The
DTrace framework uses the module name of probes to determine which probes
should be destroyed when a kernel module is unloaded, so the module name of
a probe should match the name of the module in which its defined.
SDT
will set the module name properly if it is left
unspecified in the probe definition; see the
EXAMPLES section.
One of the goals of the original SDT
implementation (and by extension, of FreeBSD's port) is that inactive
SDT
probes should have no performance impact. This
is unfortunately not the case; SDT
trace points will
add a small but non-zero amount of latency to the code in which they are
defined. A more sophisticated implementation of the probes will help
alleviate this problem.
April 18, 2015 | Debian |