WSL2-Linux-Kernel/Documentation/trace/user_events.rst

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user_events: User-based Event Tracing
=========================================
:Author: Beau Belgrave
Overview
--------
User based trace events allow user processes to create events and trace data
that can be viewed via existing tools, such as ftrace and perf.
To enable this feature, build your kernel with CONFIG_USER_EVENTS=y.
Programs can view status of the events via
/sys/kernel/debug/tracing/user_events_status and can both register and write
data out via /sys/kernel/debug/tracing/user_events_data.
Programs can also use /sys/kernel/debug/tracing/dynamic_events to register and
delete user based events via the u: prefix. The format of the command to
dynamic_events is the same as the ioctl with the u: prefix applied.
Typically programs will register a set of events that they wish to expose to
tools that can read trace_events (such as ftrace and perf). The registration
process gives back two ints to the program for each event. The first int is
the status bit. This describes which bit in little-endian format in the
/sys/kernel/debug/tracing/user_events_status file represents this event. The
second int is the write index which describes the data when a write() or
writev() is called on the /sys/kernel/debug/tracing/user_events_data file.
The structures referenced in this document are contained within the
/include/uapi/linux/user_events.h file in the source tree.
**NOTE:** *Both user_events_status and user_events_data are under the tracefs
filesystem and may be mounted at different paths than above.*
Registering
-----------
Registering within a user process is done via ioctl() out to the
/sys/kernel/debug/tracing/user_events_data file. The command to issue is
DIAG_IOCSREG.
This command takes a packed struct user_reg as an argument::
struct user_reg {
u32 size;
u64 name_args;
u32 status_bit;
u32 write_index;
};
The struct user_reg requires two inputs, the first is the size of the structure
to ensure forward and backward compatibility. The second is the command string
to issue for registering. Upon success two outputs are set, the status bit
and the write index.
User based events show up under tracefs like any other event under the
subsystem named "user_events". This means tools that wish to attach to the
events need to use /sys/kernel/debug/tracing/events/user_events/[name]/enable
or perf record -e user_events:[name] when attaching/recording.
**NOTE:** *The write_index returned is only valid for the FD that was used*
Command Format
^^^^^^^^^^^^^^
The command string format is as follows::
name[:FLAG1[,FLAG2...]] [Field1[;Field2...]]
Supported Flags
^^^^^^^^^^^^^^^
None yet
Field Format
^^^^^^^^^^^^
::
type name [size]
Basic types are supported (__data_loc, u32, u64, int, char, char[20], etc).
User programs are encouraged to use clearly sized types like u32.
**NOTE:** *Long is not supported since size can vary between user and kernel.*
The size is only valid for types that start with a struct prefix.
This allows user programs to describe custom structs out to tools, if required.
For example, a struct in C that looks like this::
struct mytype {
char data[20];
};
Would be represented by the following field::
struct mytype myname 20
Deleting
-----------
Deleting an event from within a user process is done via ioctl() out to the
/sys/kernel/debug/tracing/user_events_data file. The command to issue is
DIAG_IOCSDEL.
This command only requires a single string specifying the event to delete by
its name. Delete will only succeed if there are no references left to the
event (in both user and kernel space). User programs should use a separate file
to request deletes than the one used for registration due to this.
Status
------
When tools attach/record user based events the status of the event is updated
in realtime. This allows user programs to only incur the cost of the write() or
writev() calls when something is actively attached to the event.
User programs call mmap() on /sys/kernel/debug/tracing/user_events_status to
check the status for each event that is registered. The bit to check in the
file is given back after the register ioctl() via user_reg.status_bit. The bit
is always in little-endian format. Programs can check if the bit is set either
using a byte-wise index with a mask or a long-wise index with a little-endian
mask.
Currently the size of user_events_status is a single page, however, custom
kernel configurations can change this size to allow more user based events. In
all cases the size of the file is a multiple of a page size.
For example, if the register ioctl() gives back a status_bit of 3 you would
check byte 0 (3 / 8) of the returned mmap data and then AND the result with 8
(1 << (3 % 8)) to see if anything is attached to that event.
A byte-wise index check is performed as follows::
int index, mask;
char *status_page;
index = status_bit / 8;
mask = 1 << (status_bit % 8);
...
if (status_page[index] & mask) {
/* Enabled */
}
A long-wise index check is performed as follows::
#include <asm/bitsperlong.h>
#include <endian.h>
#if __BITS_PER_LONG == 64
#define endian_swap(x) htole64(x)
#else
#define endian_swap(x) htole32(x)
#endif
long index, mask, *status_page;
index = status_bit / __BITS_PER_LONG;
mask = 1L << (status_bit % __BITS_PER_LONG);
mask = endian_swap(mask);
...
if (status_page[index] & mask) {
/* Enabled */
}
Administrators can easily check the status of all registered events by reading
the user_events_status file directly via a terminal. The output is as follows::
Byte:Name [# Comments]
...
Active: ActiveCount
Busy: BusyCount
Max: MaxCount
For example, on a system that has a single event the output looks like this::
1:test
Active: 1
Busy: 0
Max: 32768
If a user enables the user event via ftrace, the output would change to this::
1:test # Used by ftrace
Active: 1
Busy: 1
Max: 32768
**NOTE:** *A status bit of 0 will never be returned. This allows user programs
to have a bit that can be used on error cases.*
Writing Data
------------
After registering an event the same fd that was used to register can be used
to write an entry for that event. The write_index returned must be at the start
of the data, then the remaining data is treated as the payload of the event.
For example, if write_index returned was 1 and I wanted to write out an int
payload of the event. Then the data would have to be 8 bytes (2 ints) in size,
with the first 4 bytes being equal to 1 and the last 4 bytes being equal to the
value I want as the payload.
In memory this would look like this::
int index;
int payload;
User programs might have well known structs that they wish to use to emit out
as payloads. In those cases writev() can be used, with the first vector being
the index and the following vector(s) being the actual event payload.
For example, if I have a struct like this::
struct payload {
int src;
int dst;
int flags;
};
It's advised for user programs to do the following::
struct iovec io[2];
struct payload e;
io[0].iov_base = &write_index;
io[0].iov_len = sizeof(write_index);
io[1].iov_base = &e;
io[1].iov_len = sizeof(e);
writev(fd, (const struct iovec*)io, 2);
**NOTE:** *The write_index is not emitted out into the trace being recorded.*
Example Code
------------
See sample code in samples/user_events.