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Linux/Documentation/trace/kprobetrace.rst

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Differences between /Documentation/trace/kprobetrace.rst (Version linux-6.11.5) and /Documentation/trace/kprobetrace.rst (Version linux-6.5.13)


  1 ==========================                          1 ==========================
  2 Kprobe-based Event Tracing                          2 Kprobe-based Event Tracing
  3 ==========================                          3 ==========================
  4                                                     4 
  5 :Author: Masami Hiramatsu                           5 :Author: Masami Hiramatsu
  6                                                     6 
  7 Overview                                            7 Overview
  8 --------                                            8 --------
  9 These events are similar to tracepoint-based e      9 These events are similar to tracepoint-based events. Instead of tracepoints,
 10 this is based on kprobes (kprobe and kretprobe     10 this is based on kprobes (kprobe and kretprobe). So it can probe wherever
 11 kprobes can probe (this means, all functions e     11 kprobes can probe (this means, all functions except those with
 12 __kprobes/nokprobe_inline annotation and those     12 __kprobes/nokprobe_inline annotation and those marked NOKPROBE_SYMBOL).
 13 Unlike the tracepoint-based event, this can be     13 Unlike the tracepoint-based event, this can be added and removed
 14 dynamically, on the fly.                           14 dynamically, on the fly.
 15                                                    15 
 16 To enable this feature, build your kernel with     16 To enable this feature, build your kernel with CONFIG_KPROBE_EVENTS=y.
 17                                                    17 
 18 Similar to the event tracer, this doesn't need     18 Similar to the event tracer, this doesn't need to be activated via
 19 current_tracer. Instead of that, add probe poi     19 current_tracer. Instead of that, add probe points via
 20 /sys/kernel/tracing/kprobe_events, and enable      20 /sys/kernel/tracing/kprobe_events, and enable it via
 21 /sys/kernel/tracing/events/kprobes/<EVENT>/ena     21 /sys/kernel/tracing/events/kprobes/<EVENT>/enable.
 22                                                    22 
 23 You can also use /sys/kernel/tracing/dynamic_e     23 You can also use /sys/kernel/tracing/dynamic_events instead of
 24 kprobe_events. That interface will provide uni     24 kprobe_events. That interface will provide unified access to other
 25 dynamic events too.                                25 dynamic events too.
 26                                                    26 
 27 Synopsis of kprobe_events                          27 Synopsis of kprobe_events
 28 -------------------------                          28 -------------------------
 29 ::                                                 29 ::
 30                                                    30 
 31   p[:[GRP/][EVENT]] [MOD:]SYM[+offs]|MEMADDR [     31   p[:[GRP/][EVENT]] [MOD:]SYM[+offs]|MEMADDR [FETCHARGS]        : Set a probe
 32   r[MAXACTIVE][:[GRP/][EVENT]] [MOD:]SYM[+0] [     32   r[MAXACTIVE][:[GRP/][EVENT]] [MOD:]SYM[+0] [FETCHARGS]        : Set a return probe
 33   p[:[GRP/][EVENT]] [MOD:]SYM[+0]%return [FETC     33   p[:[GRP/][EVENT]] [MOD:]SYM[+0]%return [FETCHARGS]    : Set a return probe
 34   -:[GRP/][EVENT]                                  34   -:[GRP/][EVENT]                                               : Clear a probe
 35                                                    35 
 36  GRP            : Group name. If omitted, use      36  GRP            : Group name. If omitted, use "kprobes" for it.
 37  EVENT          : Event name. If omitted, the      37  EVENT          : Event name. If omitted, the event name is generated
 38                   based on SYM+offs or MEMADDR     38                   based on SYM+offs or MEMADDR.
 39  MOD            : Module name which has given      39  MOD            : Module name which has given SYM.
 40  SYM[+offs]     : Symbol+offset where the prob     40  SYM[+offs]     : Symbol+offset where the probe is inserted.
 41  SYM%return     : Return address of the symbol     41  SYM%return     : Return address of the symbol
 42  MEMADDR        : Address where the probe is i     42  MEMADDR        : Address where the probe is inserted.
 43  MAXACTIVE      : Maximum number of instances      43  MAXACTIVE      : Maximum number of instances of the specified function that
 44                   can be probed simultaneously     44                   can be probed simultaneously, or 0 for the default value
 45                   as defined in Documentation/     45                   as defined in Documentation/trace/kprobes.rst section 1.3.1.
 46                                                    46 
 47  FETCHARGS      : Arguments. Each probe can ha     47  FETCHARGS      : Arguments. Each probe can have up to 128 args.
 48   %REG          : Fetch register REG               48   %REG          : Fetch register REG
 49   @ADDR         : Fetch memory at ADDR (ADDR s     49   @ADDR         : Fetch memory at ADDR (ADDR should be in kernel)
 50   @SYM[+|-offs] : Fetch memory at SYM +|- offs     50   @SYM[+|-offs] : Fetch memory at SYM +|- offs (SYM should be a data symbol)
 51   $stackN       : Fetch Nth entry of stack (N      51   $stackN       : Fetch Nth entry of stack (N >= 0)
 52   $stack        : Fetch stack address.             52   $stack        : Fetch stack address.
 53   $argN         : Fetch the Nth function argum     53   $argN         : Fetch the Nth function argument. (N >= 1) (\*1)
 54   $retval       : Fetch return value.(\*2)         54   $retval       : Fetch return value.(\*2)
 55   $comm         : Fetch current task comm.         55   $comm         : Fetch current task comm.
 56   +|-[u]OFFS(FETCHARG) : Fetch memory at FETCH     56   +|-[u]OFFS(FETCHARG) : Fetch memory at FETCHARG +|- OFFS address.(\*3)(\*4)
 57   \IMM          : Store an immediate value to      57   \IMM          : Store an immediate value to the argument.
 58   NAME=FETCHARG : Set NAME as the argument nam     58   NAME=FETCHARG : Set NAME as the argument name of FETCHARG.
 59   FETCHARG:TYPE : Set TYPE as the type of FETC     59   FETCHARG:TYPE : Set TYPE as the type of FETCHARG. Currently, basic types
 60                   (u8/u16/u32/u64/s8/s16/s32/s     60                   (u8/u16/u32/u64/s8/s16/s32/s64), hexadecimal types
 61                   (x8/x16/x32/x64), VFS layer  !!  61                   (x8/x16/x32/x64), "char", "string", "ustring", "symbol", "symstr"
 62                   "string", "ustring", "symbol !!  62                   and bitfield are supported.
 63                   supported.                   !!  63 
 64                                                !!  64   (\*1) only for the probe on function entry (offs == 0).
 65   (\*1) only for the probe on function entry ( !!  65   (\*2) only for return probe.
 66         is best effort, because depending on t << 
 67         the stack. But this only support the a << 
 68   (\*2) only for return probe. Note that this  << 
 69         return value type, it might be passed  << 
 70         accesses one register.                 << 
 71   (\*3) this is useful for fetching a field of     66   (\*3) this is useful for fetching a field of data structures.
 72   (\*4) "u" means user-space dereference. See      67   (\*4) "u" means user-space dereference. See :ref:`user_mem_access`.
 73                                                    68 
 74 Function arguments at kretprobe                << 
 75 -------------------------------                << 
 76 Function arguments can be accessed at kretprob << 
 77 is useful to record the function parameter and << 
 78 trace the difference of structure fields (for  << 
 79 correctly updates the given data structure or  << 
 80 See the :ref:`sample<fprobetrace_exit_args_sam << 
 81 it works.                                      << 
 82                                                << 
 83 .. _kprobetrace_types:                             69 .. _kprobetrace_types:
 84                                                    70 
 85 Types                                              71 Types
 86 -----                                              72 -----
 87 Several types are supported for fetchargs. Kpr     73 Several types are supported for fetchargs. Kprobe tracer will access memory
 88 by given type. Prefix 's' and 'u' means those      74 by given type. Prefix 's' and 'u' means those types are signed and unsigned
 89 respectively. 'x' prefix implies it is unsigne     75 respectively. 'x' prefix implies it is unsigned. Traced arguments are shown
 90 in decimal ('s' and 'u') or hexadecimal ('x').     76 in decimal ('s' and 'u') or hexadecimal ('x'). Without type casting, 'x32'
 91 or 'x64' is used depends on the architecture (     77 or 'x64' is used depends on the architecture (e.g. x86-32 uses x32, and
 92 x86-64 uses x64).                                  78 x86-64 uses x64).
 93                                                    79 
 94 These value types can be an array. To record a     80 These value types can be an array. To record array data, you can add '[N]'
 95 (where N is a fixed number, less than 64) to t     81 (where N is a fixed number, less than 64) to the base type.
 96 E.g. 'x16[4]' means an array of x16 (2-byte he     82 E.g. 'x16[4]' means an array of x16 (2-byte hex) with 4 elements.
 97 Note that the array can be applied to memory t     83 Note that the array can be applied to memory type fetchargs, you can not
 98 apply it to registers/stack-entries etc. (for      84 apply it to registers/stack-entries etc. (for example, '$stack1:x8[8]' is
 99 wrong, but '+8($stack):x8[8]' is OK.)              85 wrong, but '+8($stack):x8[8]' is OK.)
100                                                    86 
101 Char type can be used to show the character va     87 Char type can be used to show the character value of traced arguments.
102                                                    88 
103 String type is a special type, which fetches a     89 String type is a special type, which fetches a "null-terminated" string from
104 kernel space. This means it will fail and stor     90 kernel space. This means it will fail and store NULL if the string container
105 has been paged out. "ustring" type is an alter     91 has been paged out. "ustring" type is an alternative of string for user-space.
106 See :ref:`user_mem_access` for more info.          92 See :ref:`user_mem_access` for more info.
107                                                    93 
108 The string array type is a bit different from      94 The string array type is a bit different from other types. For other base
109 types, <base-type>[1] is equal to <base-type>      95 types, <base-type>[1] is equal to <base-type> (e.g. +0(%di):x32[1] is same
110 as +0(%di):x32.) But string[1] is not equal to     96 as +0(%di):x32.) But string[1] is not equal to string. The string type itself
111 represents "char array", but string array type     97 represents "char array", but string array type represents "char * array".
112 So, for example, +0(%di):string[1] is equal to     98 So, for example, +0(%di):string[1] is equal to +0(+0(%di)):string.
113 Bitfield is another special type, which takes      99 Bitfield is another special type, which takes 3 parameters, bit-width, bit-
114 offset, and container-size (usually 32). The s    100 offset, and container-size (usually 32). The syntax is::
115                                                   101 
116  b<bit-width>@<bit-offset>/<container-size>        102  b<bit-width>@<bit-offset>/<container-size>
117                                                   103 
118 Symbol type('symbol') is an alias of u32 or u6    104 Symbol type('symbol') is an alias of u32 or u64 type (depends on BITS_PER_LONG)
119 which shows given pointer in "symbol+offset" s    105 which shows given pointer in "symbol+offset" style.
120 On the other hand, symbol-string type ('symstr    106 On the other hand, symbol-string type ('symstr') converts the given address to
121 "symbol+offset/symbolsize" style and stores it    107 "symbol+offset/symbolsize" style and stores it as a null-terminated string.
122 With 'symstr' type, you can filter the event w    108 With 'symstr' type, you can filter the event with wildcard pattern of the
123 symbols, and you don't need to solve symbol na    109 symbols, and you don't need to solve symbol name by yourself.
124 For $comm, the default type is "string"; any o    110 For $comm, the default type is "string"; any other type is invalid.
125                                                << 
126 VFS layer common type(%pd/%pD) is a special ty << 
127 file's name from struct dentry's address or st << 
128                                                   111 
129 .. _user_mem_access:                              112 .. _user_mem_access:
130                                                   113 
131 User Memory Access                                114 User Memory Access
132 ------------------                                115 ------------------
133 Kprobe events supports user-space memory acces    116 Kprobe events supports user-space memory access. For that purpose, you can use
134 either user-space dereference syntax or 'ustri    117 either user-space dereference syntax or 'ustring' type.
135                                                   118 
136 The user-space dereference syntax allows you t    119 The user-space dereference syntax allows you to access a field of a data
137 structure in user-space. This is done by addin    120 structure in user-space. This is done by adding the "u" prefix to the
138 dereference syntax. For example, +u4(%si) mean    121 dereference syntax. For example, +u4(%si) means it will read memory from the
139 address in the register %si offset by 4, and t    122 address in the register %si offset by 4, and the memory is expected to be in
140 user-space. You can use this for strings too,     123 user-space. You can use this for strings too, e.g. +u0(%si):string will read
141 a string from the address in the register %si     124 a string from the address in the register %si that is expected to be in user-
142 space. 'ustring' is a shortcut way of performi    125 space. 'ustring' is a shortcut way of performing the same task. That is,
143 +0(%si):ustring is equivalent to +u0(%si):stri    126 +0(%si):ustring is equivalent to +u0(%si):string.
144                                                   127 
145 Note that kprobe-event provides the user-memor    128 Note that kprobe-event provides the user-memory access syntax but it doesn't
146 use it transparently. This means if you use no    129 use it transparently. This means if you use normal dereference or string type
147 for user memory, it might fail, and may always    130 for user memory, it might fail, and may always fail on some architectures. The
148 user has to carefully check if the target data    131 user has to carefully check if the target data is in kernel or user space.
149                                                   132 
150 Per-Probe Event Filtering                         133 Per-Probe Event Filtering
151 -------------------------                         134 -------------------------
152 Per-probe event filtering feature allows you t    135 Per-probe event filtering feature allows you to set different filter on each
153 probe and gives you what arguments will be sho    136 probe and gives you what arguments will be shown in trace buffer. If an event
154 name is specified right after 'p:' or 'r:' in     137 name is specified right after 'p:' or 'r:' in kprobe_events, it adds an event
155 under tracing/events/kprobes/<EVENT>, at the d    138 under tracing/events/kprobes/<EVENT>, at the directory you can see 'id',
156 'enable', 'format', 'filter' and 'trigger'.       139 'enable', 'format', 'filter' and 'trigger'.
157                                                   140 
158 enable:                                           141 enable:
159   You can enable/disable the probe by writing     142   You can enable/disable the probe by writing 1 or 0 on it.
160                                                   143 
161 format:                                           144 format:
162   This shows the format of this probe event.      145   This shows the format of this probe event.
163                                                   146 
164 filter:                                           147 filter:
165   You can write filtering rules of this event.    148   You can write filtering rules of this event.
166                                                   149 
167 id:                                               150 id:
168   This shows the id of this probe event.          151   This shows the id of this probe event.
169                                                   152 
170 trigger:                                          153 trigger:
171   This allows to install trigger commands whic    154   This allows to install trigger commands which are executed when the event is
172   hit (for details, see Documentation/trace/ev    155   hit (for details, see Documentation/trace/events.rst, section 6).
173                                                   156 
174 Event Profiling                                   157 Event Profiling
175 ---------------                                   158 ---------------
176 You can check the total number of probe hits a    159 You can check the total number of probe hits and probe miss-hits via
177 /sys/kernel/tracing/kprobe_profile.               160 /sys/kernel/tracing/kprobe_profile.
178 The first column is event name, the second is     161 The first column is event name, the second is the number of probe hits,
179 the third is the number of probe miss-hits.       162 the third is the number of probe miss-hits.
180                                                   163 
181 Kernel Boot Parameter                             164 Kernel Boot Parameter
182 ---------------------                             165 ---------------------
183 You can add and enable new kprobe events when     166 You can add and enable new kprobe events when booting up the kernel by
184 "kprobe_event=" parameter. The parameter accep    167 "kprobe_event=" parameter. The parameter accepts a semicolon-delimited
185 kprobe events, which format is similar to the     168 kprobe events, which format is similar to the kprobe_events.
186 The difference is that the probe definition pa    169 The difference is that the probe definition parameters are comma-delimited
187 instead of space. For example, adding myprobe     170 instead of space. For example, adding myprobe event on do_sys_open like below::
188                                                   171 
189   p:myprobe do_sys_open dfd=%ax filename=%dx f    172   p:myprobe do_sys_open dfd=%ax filename=%dx flags=%cx mode=+4($stack)
190                                                   173 
191 should be below for kernel boot parameter (jus    174 should be below for kernel boot parameter (just replace spaces with comma)::
192                                                   175 
193   p:myprobe,do_sys_open,dfd=%ax,filename=%dx,f    176   p:myprobe,do_sys_open,dfd=%ax,filename=%dx,flags=%cx,mode=+4($stack)
194                                                   177 
195                                                   178 
196 Usage examples                                    179 Usage examples
197 --------------                                    180 --------------
198 To add a probe as a new event, write a new def    181 To add a probe as a new event, write a new definition to kprobe_events
199 as below::                                        182 as below::
200                                                   183 
201   echo 'p:myprobe do_sys_open dfd=%ax filename    184   echo 'p:myprobe do_sys_open dfd=%ax filename=%dx flags=%cx mode=+4($stack)' > /sys/kernel/tracing/kprobe_events
202                                                   185 
203 This sets a kprobe on the top of do_sys_open()    186 This sets a kprobe on the top of do_sys_open() function with recording
204 1st to 4th arguments as "myprobe" event. Note,    187 1st to 4th arguments as "myprobe" event. Note, which register/stack entry is
205 assigned to each function argument depends on     188 assigned to each function argument depends on arch-specific ABI. If you unsure
206 the ABI, please try to use probe subcommand of    189 the ABI, please try to use probe subcommand of perf-tools (you can find it
207 under tools/perf/).                               190 under tools/perf/).
208 As this example shows, users can choose more f    191 As this example shows, users can choose more familiar names for each arguments.
209 ::                                                192 ::
210                                                   193 
211   echo 'r:myretprobe do_sys_open $retval' >> /    194   echo 'r:myretprobe do_sys_open $retval' >> /sys/kernel/tracing/kprobe_events
212                                                   195 
213 This sets a kretprobe on the return point of d    196 This sets a kretprobe on the return point of do_sys_open() function with
214 recording return value as "myretprobe" event.     197 recording return value as "myretprobe" event.
215 You can see the format of these events via        198 You can see the format of these events via
216 /sys/kernel/tracing/events/kprobes/<EVENT>/for    199 /sys/kernel/tracing/events/kprobes/<EVENT>/format.
217 ::                                                200 ::
218                                                   201 
219   cat /sys/kernel/tracing/events/kprobes/mypro    202   cat /sys/kernel/tracing/events/kprobes/myprobe/format
220   name: myprobe                                   203   name: myprobe
221   ID: 780                                         204   ID: 780
222   format:                                         205   format:
223           field:unsigned short common_type;       206           field:unsigned short common_type;       offset:0;       size:2; signed:0;
224           field:unsigned char common_flags;       207           field:unsigned char common_flags;       offset:2;       size:1; signed:0;
225           field:unsigned char common_preempt_c    208           field:unsigned char common_preempt_count;       offset:3; size:1;signed:0;
226           field:int common_pid;   offset:4;       209           field:int common_pid;   offset:4;       size:4; signed:1;
227                                                   210 
228           field:unsigned long __probe_ip; offs    211           field:unsigned long __probe_ip; offset:12;      size:4; signed:0;
229           field:int __probe_nargs;        offs    212           field:int __probe_nargs;        offset:16;      size:4; signed:1;
230           field:unsigned long dfd;        offs    213           field:unsigned long dfd;        offset:20;      size:4; signed:0;
231           field:unsigned long filename;   offs    214           field:unsigned long filename;   offset:24;      size:4; signed:0;
232           field:unsigned long flags;      offs    215           field:unsigned long flags;      offset:28;      size:4; signed:0;
233           field:unsigned long mode;       offs    216           field:unsigned long mode;       offset:32;      size:4; signed:0;
234                                                   217 
235                                                   218 
236   print fmt: "(%lx) dfd=%lx filename=%lx flags    219   print fmt: "(%lx) dfd=%lx filename=%lx flags=%lx mode=%lx", REC->__probe_ip,
237   REC->dfd, REC->filename, REC->flags, REC->mo    220   REC->dfd, REC->filename, REC->flags, REC->mode
238                                                   221 
239 You can see that the event has 4 arguments as     222 You can see that the event has 4 arguments as in the expressions you specified.
240 ::                                                223 ::
241                                                   224 
242   echo > /sys/kernel/tracing/kprobe_events        225   echo > /sys/kernel/tracing/kprobe_events
243                                                   226 
244 This clears all probe points.                     227 This clears all probe points.
245                                                   228 
246 Or,                                               229 Or,
247 ::                                                230 ::
248                                                   231 
249   echo -:myprobe >> kprobe_events                 232   echo -:myprobe >> kprobe_events
250                                                   233 
251 This clears probe points selectively.             234 This clears probe points selectively.
252                                                   235 
253 Right after definition, each event is disabled    236 Right after definition, each event is disabled by default. For tracing these
254 events, you need to enable it.                    237 events, you need to enable it.
255 ::                                                238 ::
256                                                   239 
257   echo 1 > /sys/kernel/tracing/events/kprobes/    240   echo 1 > /sys/kernel/tracing/events/kprobes/myprobe/enable
258   echo 1 > /sys/kernel/tracing/events/kprobes/    241   echo 1 > /sys/kernel/tracing/events/kprobes/myretprobe/enable
259                                                   242 
260 Use the following command to start tracing in     243 Use the following command to start tracing in an interval.
261 ::                                                244 ::
262                                                   245 
263     # echo 1 > tracing_on                         246     # echo 1 > tracing_on
264     Open something...                             247     Open something...
265     # echo 0 > tracing_on                         248     # echo 0 > tracing_on
266                                                   249 
267 And you can see the traced information via /sy    250 And you can see the traced information via /sys/kernel/tracing/trace.
268 ::                                                251 ::
269                                                   252 
270   cat /sys/kernel/tracing/trace                   253   cat /sys/kernel/tracing/trace
271   # tracer: nop                                   254   # tracer: nop
272   #                                               255   #
273   #           TASK-PID    CPU#    TIMESTAMP  F    256   #           TASK-PID    CPU#    TIMESTAMP  FUNCTION
274   #              | |       |          |           257   #              | |       |          |         |
275              <...>-1447  [001] 1038282.286875:    258              <...>-1447  [001] 1038282.286875: myprobe: (do_sys_open+0x0/0xd6) dfd=3 filename=7fffd1ec4440 flags=8000 mode=0
276              <...>-1447  [001] 1038282.286878:    259              <...>-1447  [001] 1038282.286878: myretprobe: (sys_openat+0xc/0xe <- do_sys_open) $retval=fffffffffffffffe
277              <...>-1447  [001] 1038282.286885:    260              <...>-1447  [001] 1038282.286885: myprobe: (do_sys_open+0x0/0xd6) dfd=ffffff9c filename=40413c flags=8000 mode=1b6
278              <...>-1447  [001] 1038282.286915:    261              <...>-1447  [001] 1038282.286915: myretprobe: (sys_open+0x1b/0x1d <- do_sys_open) $retval=3
279              <...>-1447  [001] 1038282.286969:    262              <...>-1447  [001] 1038282.286969: myprobe: (do_sys_open+0x0/0xd6) dfd=ffffff9c filename=4041c6 flags=98800 mode=10
280              <...>-1447  [001] 1038282.286976:    263              <...>-1447  [001] 1038282.286976: myretprobe: (sys_open+0x1b/0x1d <- do_sys_open) $retval=3
281                                                   264 
282                                                   265 
283 Each line shows when the kernel hits an event,    266 Each line shows when the kernel hits an event, and <- SYMBOL means kernel
284 returns from SYMBOL(e.g. "sys_open+0x1b/0x1d <    267 returns from SYMBOL(e.g. "sys_open+0x1b/0x1d <- do_sys_open" means kernel
285 returns from do_sys_open to sys_open+0x1b).       268 returns from do_sys_open to sys_open+0x1b).
                                                      

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