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TOMOYO Linux Cross Reference
Linux/tools/perf/Documentation/topdown.txt

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Diff markup

Differences between /tools/perf/Documentation/topdown.txt (Version linux-6.12-rc7) and /tools/perf/Documentation/topdown.txt (Version linux-6.7.12)


  1 Using TopDown metrics                               1 Using TopDown metrics
  2 ---------------------                               2 ---------------------
  3                                                     3 
  4 TopDown metrics break apart performance bottle      4 TopDown metrics break apart performance bottlenecks. Starting at level
  5 1 it is typical to get metrics on retiring, ba      5 1 it is typical to get metrics on retiring, bad speculation, frontend
  6 bound, and backend bound. Higher levels provid      6 bound, and backend bound. Higher levels provide more detail in to the
  7 level 1 bottlenecks, such as at level 2: core       7 level 1 bottlenecks, such as at level 2: core bound, memory bound,
  8 heavy operations, light operations, branch mis      8 heavy operations, light operations, branch mispredicts, machine
  9 clears, fetch latency and fetch bandwidth. For      9 clears, fetch latency and fetch bandwidth. For more details see [1][2][3].
 10                                                    10 
 11 perf stat --topdown implements this using avai     11 perf stat --topdown implements this using available metrics that vary
 12 per architecture.                                  12 per architecture.
 13                                                    13 
 14 % perf stat -a --topdown -I1000                    14 % perf stat -a --topdown -I1000
 15 #           time      %  tma_retiring %  tma_b     15 #           time      %  tma_retiring %  tma_backend_bound %  tma_frontend_bound %  tma_bad_speculation
 16      1.001141351                 11.5              16      1.001141351                 11.5                 34.9                  46.9                    6.7
 17      2.006141972                 13.4              17      2.006141972                 13.4                 28.1                  50.4                    8.1
 18      3.010162040                 12.9              18      3.010162040                 12.9                 28.1                  51.1                    8.0
 19      4.014009311                 12.5              19      4.014009311                 12.5                 28.6                  51.8                    7.2
 20      5.017838554                 11.8              20      5.017838554                 11.8                 33.0                  48.0                    7.2
 21      5.704818971                 14.0              21      5.704818971                 14.0                 27.5                  51.3                    7.3
 22 ...                                                22 ...
 23                                                    23 
 24 New Topdown features in Intel Ice Lake             24 New Topdown features in Intel Ice Lake
 25 ======================================             25 ======================================
 26                                                    26 
 27 With Ice Lake CPUs the TopDown metrics are dir     27 With Ice Lake CPUs the TopDown metrics are directly available as
 28 fixed counters and do not require generic coun     28 fixed counters and do not require generic counters. This allows
 29 to collect TopDown always in addition to other     29 to collect TopDown always in addition to other events.
 30                                                    30 
 31 Using TopDown through RDPMC in applications on     31 Using TopDown through RDPMC in applications on Intel Ice Lake
 32 ==============================================     32 =============================================================
 33                                                    33 
 34 For more fine grained measurements it can be u     34 For more fine grained measurements it can be useful to
 35 access the new  directly from user space. This     35 access the new  directly from user space. This is more complicated,
 36 but drastically lowers overhead.                   36 but drastically lowers overhead.
 37                                                    37 
 38 On Ice Lake, there is a new fixed counter 3: S     38 On Ice Lake, there is a new fixed counter 3: SLOTS, which reports
 39 "pipeline SLOTS" (cycles multiplied by core is     39 "pipeline SLOTS" (cycles multiplied by core issue width) and a
 40 metric register that reports slots ratios for      40 metric register that reports slots ratios for the different bottleneck
 41 categories.                                        41 categories.
 42                                                    42 
 43 The metrics counter is CPU model specific and      43 The metrics counter is CPU model specific and is not available on older
 44 CPUs.                                              44 CPUs.
 45                                                    45 
 46 Example code                                       46 Example code
 47 ============                                       47 ============
 48                                                    48 
 49 Library functions to do the functionality desc     49 Library functions to do the functionality described below
 50 is also available in libjevents [4]                50 is also available in libjevents [4]
 51                                                    51 
 52 The application opens a group with fixed count     52 The application opens a group with fixed counter 3 (SLOTS) and any
 53 metric event, and allow user programs to read      53 metric event, and allow user programs to read the performance counters.
 54                                                    54 
 55 Fixed counter 3 is mapped to a pseudo event ev     55 Fixed counter 3 is mapped to a pseudo event event=0x00, umask=04,
 56 so the perf_event_attr structure should be ini     56 so the perf_event_attr structure should be initialized with
 57 { .config = 0x0400, .type = PERF_TYPE_RAW }        57 { .config = 0x0400, .type = PERF_TYPE_RAW }
 58 The metric events are mapped to the pseudo eve     58 The metric events are mapped to the pseudo event event=0x00, umask=0x8X.
 59 For example, the perf_event_attr structure can     59 For example, the perf_event_attr structure can be initialized with
 60 { .config = 0x8000, .type = PERF_TYPE_RAW } fo     60 { .config = 0x8000, .type = PERF_TYPE_RAW } for Retiring metric event
 61 The Fixed counter 3 must be the leader of the      61 The Fixed counter 3 must be the leader of the group.
 62                                                    62 
 63 #include <linux/perf_event.h>                      63 #include <linux/perf_event.h>
 64 #include <sys/mman.h>                              64 #include <sys/mman.h>
 65 #include <sys/syscall.h>                           65 #include <sys/syscall.h>
 66 #include <unistd.h>                                66 #include <unistd.h>
 67                                                    67 
 68 /* Provide own perf_event_open stub because gl     68 /* Provide own perf_event_open stub because glibc doesn't */
 69 __attribute__((weak))                              69 __attribute__((weak))
 70 int perf_event_open(struct perf_event_attr *at     70 int perf_event_open(struct perf_event_attr *attr, pid_t pid,
 71                     int cpu, int group_fd, uns     71                     int cpu, int group_fd, unsigned long flags)
 72 {                                                  72 {
 73         return syscall(__NR_perf_event_open, a     73         return syscall(__NR_perf_event_open, attr, pid, cpu, group_fd, flags);
 74 }                                                  74 }
 75                                                    75 
 76 /* Open slots counter file descriptor for curr     76 /* Open slots counter file descriptor for current task. */
 77 struct perf_event_attr slots = {                   77 struct perf_event_attr slots = {
 78         .type = PERF_TYPE_RAW,                     78         .type = PERF_TYPE_RAW,
 79         .size = sizeof(struct perf_event_attr)     79         .size = sizeof(struct perf_event_attr),
 80         .config = 0x400,                           80         .config = 0x400,
 81         .exclude_kernel = 1,                       81         .exclude_kernel = 1,
 82 };                                                 82 };
 83                                                    83 
 84 int slots_fd = perf_event_open(&slots, 0, -1,      84 int slots_fd = perf_event_open(&slots, 0, -1, -1, 0);
 85 if (slots_fd < 0)                                  85 if (slots_fd < 0)
 86         ... error ...                              86         ... error ...
 87                                                    87 
 88 /* Memory mapping the fd permits _rdpmc calls      88 /* Memory mapping the fd permits _rdpmc calls from userspace */
 89 void *slots_p = mmap(0, getpagesize(), PROT_RE     89 void *slots_p = mmap(0, getpagesize(), PROT_READ, MAP_SHARED, slots_fd, 0);
 90 if (!slot_p)                                       90 if (!slot_p)
 91         .... error ...                             91         .... error ...
 92                                                    92 
 93 /*                                                 93 /*
 94  * Open metrics event file descriptor for curr     94  * Open metrics event file descriptor for current task.
 95  * Set slots event as the leader of the group.     95  * Set slots event as the leader of the group.
 96  */                                                96  */
 97 struct perf_event_attr metrics = {                 97 struct perf_event_attr metrics = {
 98         .type = PERF_TYPE_RAW,                     98         .type = PERF_TYPE_RAW,
 99         .size = sizeof(struct perf_event_attr)     99         .size = sizeof(struct perf_event_attr),
100         .config = 0x8000,                         100         .config = 0x8000,
101         .exclude_kernel = 1,                      101         .exclude_kernel = 1,
102 };                                                102 };
103                                                   103 
104 int metrics_fd = perf_event_open(&metrics, 0,     104 int metrics_fd = perf_event_open(&metrics, 0, -1, slots_fd, 0);
105 if (metrics_fd < 0)                               105 if (metrics_fd < 0)
106         ... error ...                             106         ... error ...
107                                                   107 
108 /* Memory mapping the fd permits _rdpmc calls     108 /* Memory mapping the fd permits _rdpmc calls from userspace */
109 void *metrics_p = mmap(0, getpagesize(), PROT_    109 void *metrics_p = mmap(0, getpagesize(), PROT_READ, MAP_SHARED, metrics_fd, 0);
110 if (!metrics_p)                                   110 if (!metrics_p)
111         ... error ...                             111         ... error ...
112                                                   112 
113 Note: the file descriptors returned by the per    113 Note: the file descriptors returned by the perf_event_open calls must be memory
114 mapped to permit calls to the _rdpmd instructi    114 mapped to permit calls to the _rdpmd instruction. Permission may also be granted
115 by writing the /sys/devices/cpu/rdpmc sysfs no    115 by writing the /sys/devices/cpu/rdpmc sysfs node.
116                                                   116 
117 The RDPMC instruction (or _rdpmc compiler intr    117 The RDPMC instruction (or _rdpmc compiler intrinsic) can now be used
118 to read slots and the topdown metrics at diffe    118 to read slots and the topdown metrics at different points of the program:
119                                                   119 
120 #include <stdint.h>                               120 #include <stdint.h>
121 #include <x86intrin.h>                            121 #include <x86intrin.h>
122                                                   122 
123 #define RDPMC_FIXED     (1 << 30)       /* ret    123 #define RDPMC_FIXED     (1 << 30)       /* return fixed counters */
124 #define RDPMC_METRIC    (1 << 29)       /* ret    124 #define RDPMC_METRIC    (1 << 29)       /* return metric counters */
125                                                   125 
126 #define FIXED_COUNTER_SLOTS             3         126 #define FIXED_COUNTER_SLOTS             3
127 #define METRIC_COUNTER_TOPDOWN_L1_L2    0         127 #define METRIC_COUNTER_TOPDOWN_L1_L2    0
128                                                   128 
129 static inline uint64_t read_slots(void)           129 static inline uint64_t read_slots(void)
130 {                                                 130 {
131         return _rdpmc(RDPMC_FIXED | FIXED_COUN    131         return _rdpmc(RDPMC_FIXED | FIXED_COUNTER_SLOTS);
132 }                                                 132 }
133                                                   133 
134 static inline uint64_t read_metrics(void)         134 static inline uint64_t read_metrics(void)
135 {                                                 135 {
136         return _rdpmc(RDPMC_METRIC | METRIC_CO    136         return _rdpmc(RDPMC_METRIC | METRIC_COUNTER_TOPDOWN_L1_L2);
137 }                                                 137 }
138                                                   138 
139 Then the program can be instrumented to read t    139 Then the program can be instrumented to read these metrics at different
140 points.                                           140 points.
141                                                   141 
142 It's not a good idea to do this with too short    142 It's not a good idea to do this with too short code regions,
143 as the parallelism and overlap in the CPU prog    143 as the parallelism and overlap in the CPU program execution will
144 cause too much measurement inaccuracy. For exa    144 cause too much measurement inaccuracy. For example instrumenting
145 individual basic blocks is definitely too fine    145 individual basic blocks is definitely too fine grained.
146                                                   146 
147 _rdpmc calls should not be mixed with reading     147 _rdpmc calls should not be mixed with reading the metrics and slots counters
148 through system calls, as the kernel will reset    148 through system calls, as the kernel will reset these counters after each system
149 call.                                             149 call.
150                                                   150 
151 Decoding metrics values                           151 Decoding metrics values
152 =======================                           152 =======================
153                                                   153 
154 The value reported by read_metrics() contains     154 The value reported by read_metrics() contains four 8 bit fields
155 that represent a scaled ratio that represent t    155 that represent a scaled ratio that represent the Level 1 bottleneck.
156 All four fields add up to 0xff (= 100%)           156 All four fields add up to 0xff (= 100%)
157                                                   157 
158 The binary ratios in the metric value can be c    158 The binary ratios in the metric value can be converted to float ratios:
159                                                   159 
160 #define GET_METRIC(m, i) (((m) >> (i*8)) & 0xf    160 #define GET_METRIC(m, i) (((m) >> (i*8)) & 0xff)
161                                                   161 
162 /* L1 Topdown metric events */                    162 /* L1 Topdown metric events */
163 #define TOPDOWN_RETIRING(val)   ((float)GET_ME    163 #define TOPDOWN_RETIRING(val)   ((float)GET_METRIC(val, 0) / 0xff)
164 #define TOPDOWN_BAD_SPEC(val)   ((float)GET_ME    164 #define TOPDOWN_BAD_SPEC(val)   ((float)GET_METRIC(val, 1) / 0xff)
165 #define TOPDOWN_FE_BOUND(val)   ((float)GET_ME    165 #define TOPDOWN_FE_BOUND(val)   ((float)GET_METRIC(val, 2) / 0xff)
166 #define TOPDOWN_BE_BOUND(val)   ((float)GET_ME    166 #define TOPDOWN_BE_BOUND(val)   ((float)GET_METRIC(val, 3) / 0xff)
167                                                   167 
168 /*                                                168 /*
169  * L2 Topdown metric events.                      169  * L2 Topdown metric events.
170  * Available on Sapphire Rapids and later plat    170  * Available on Sapphire Rapids and later platforms.
171  */                                               171  */
172 #define TOPDOWN_HEAVY_OPS(val)          ((floa    172 #define TOPDOWN_HEAVY_OPS(val)          ((float)GET_METRIC(val, 4) / 0xff)
173 #define TOPDOWN_BR_MISPREDICT(val)      ((floa    173 #define TOPDOWN_BR_MISPREDICT(val)      ((float)GET_METRIC(val, 5) / 0xff)
174 #define TOPDOWN_FETCH_LAT(val)          ((floa    174 #define TOPDOWN_FETCH_LAT(val)          ((float)GET_METRIC(val, 6) / 0xff)
175 #define TOPDOWN_MEM_BOUND(val)          ((floa    175 #define TOPDOWN_MEM_BOUND(val)          ((float)GET_METRIC(val, 7) / 0xff)
176                                                   176 
177 and then converted to percent for printing.       177 and then converted to percent for printing.
178                                                   178 
179 The ratios in the metric accumulate for the ti    179 The ratios in the metric accumulate for the time when the counter
180 is enabled. For measuring programs it is often    180 is enabled. For measuring programs it is often useful to measure
181 specific sections. For this it is needed to de    181 specific sections. For this it is needed to deltas on metrics.
182                                                   182 
183 This can be done by scaling the metrics with t    183 This can be done by scaling the metrics with the slots counter
184 read at the same time.                            184 read at the same time.
185                                                   185 
186 Then it's possible to take deltas of these slo    186 Then it's possible to take deltas of these slots counts
187 measured at different points, and determine th    187 measured at different points, and determine the metrics
188 for that time period.                             188 for that time period.
189                                                   189 
190         slots_a = read_slots();                   190         slots_a = read_slots();
191         metric_a = read_metrics();                191         metric_a = read_metrics();
192                                                   192 
193         ... larger code region ...                193         ... larger code region ...
194                                                   194 
195         slots_b = read_slots()                    195         slots_b = read_slots()
196         metric_b = read_metrics()                 196         metric_b = read_metrics()
197                                                   197 
198         # compute scaled metrics for measureme    198         # compute scaled metrics for measurement a
199         retiring_slots_a = GET_METRIC(metric_a    199         retiring_slots_a = GET_METRIC(metric_a, 0) * slots_a
200         bad_spec_slots_a = GET_METRIC(metric_a    200         bad_spec_slots_a = GET_METRIC(metric_a, 1) * slots_a
201         fe_bound_slots_a = GET_METRIC(metric_a    201         fe_bound_slots_a = GET_METRIC(metric_a, 2) * slots_a
202         be_bound_slots_a = GET_METRIC(metric_a    202         be_bound_slots_a = GET_METRIC(metric_a, 3) * slots_a
203                                                   203 
204         # compute delta scaled metrics between    204         # compute delta scaled metrics between b and a
205         retiring_slots = GET_METRIC(metric_b,     205         retiring_slots = GET_METRIC(metric_b, 0) * slots_b - retiring_slots_a
206         bad_spec_slots = GET_METRIC(metric_b,     206         bad_spec_slots = GET_METRIC(metric_b, 1) * slots_b - bad_spec_slots_a
207         fe_bound_slots = GET_METRIC(metric_b,     207         fe_bound_slots = GET_METRIC(metric_b, 2) * slots_b - fe_bound_slots_a
208         be_bound_slots = GET_METRIC(metric_b,     208         be_bound_slots = GET_METRIC(metric_b, 3) * slots_b - be_bound_slots_a
209                                                   209 
210 Later the individual ratios of L1 metric event    210 Later the individual ratios of L1 metric events for the measurement period can
211 be recreated from these counts.                   211 be recreated from these counts.
212                                                   212 
213         slots_delta = slots_b - slots_a           213         slots_delta = slots_b - slots_a
214         retiring_ratio = (float)retiring_slots    214         retiring_ratio = (float)retiring_slots / slots_delta
215         bad_spec_ratio = (float)bad_spec_slots    215         bad_spec_ratio = (float)bad_spec_slots / slots_delta
216         fe_bound_ratio = (float)fe_bound_slots    216         fe_bound_ratio = (float)fe_bound_slots / slots_delta
217         be_bound_ratio = (float)be_bound_slots    217         be_bound_ratio = (float)be_bound_slots / slota_delta
218                                                   218 
219         printf("Retiring %.2f%% Bad Speculatio    219         printf("Retiring %.2f%% Bad Speculation %.2f%% FE Bound %.2f%% BE Bound %.2f%%\n",
220                 retiring_ratio * 100.,            220                 retiring_ratio * 100.,
221                 bad_spec_ratio * 100.,            221                 bad_spec_ratio * 100.,
222                 fe_bound_ratio * 100.,            222                 fe_bound_ratio * 100.,
223                 be_bound_ratio * 100.);           223                 be_bound_ratio * 100.);
224                                                   224 
225 The individual ratios of L2 metric events for     225 The individual ratios of L2 metric events for the measurement period can be
226 recreated from L1 and L2 metric counters. (Ava    226 recreated from L1 and L2 metric counters. (Available on Sapphire Rapids and
227 later platforms)                                  227 later platforms)
228                                                   228 
229         # compute scaled metrics for measureme    229         # compute scaled metrics for measurement a
230         heavy_ops_slots_a = GET_METRIC(metric_    230         heavy_ops_slots_a = GET_METRIC(metric_a, 4) * slots_a
231         br_mispredict_slots_a = GET_METRIC(met    231         br_mispredict_slots_a = GET_METRIC(metric_a, 5) * slots_a
232         fetch_lat_slots_a = GET_METRIC(metric_    232         fetch_lat_slots_a = GET_METRIC(metric_a, 6) * slots_a
233         mem_bound_slots_a = GET_METRIC(metric_    233         mem_bound_slots_a = GET_METRIC(metric_a, 7) * slots_a
234                                                   234 
235         # compute delta scaled metrics between    235         # compute delta scaled metrics between b and a
236         heavy_ops_slots = GET_METRIC(metric_b,    236         heavy_ops_slots = GET_METRIC(metric_b, 4) * slots_b - heavy_ops_slots_a
237         br_mispredict_slots = GET_METRIC(metri    237         br_mispredict_slots = GET_METRIC(metric_b, 5) * slots_b - br_mispredict_slots_a
238         fetch_lat_slots = GET_METRIC(metric_b,    238         fetch_lat_slots = GET_METRIC(metric_b, 6) * slots_b - fetch_lat_slots_a
239         mem_bound_slots = GET_METRIC(metric_b,    239         mem_bound_slots = GET_METRIC(metric_b, 7) * slots_b - mem_bound_slots_a
240                                                   240 
241         slots_delta = slots_b - slots_a           241         slots_delta = slots_b - slots_a
242         heavy_ops_ratio = (float)heavy_ops_slo    242         heavy_ops_ratio = (float)heavy_ops_slots / slots_delta
243         light_ops_ratio = retiring_ratio - hea    243         light_ops_ratio = retiring_ratio - heavy_ops_ratio;
244                                                   244 
245         br_mispredict_ratio = (float)br_mispre    245         br_mispredict_ratio = (float)br_mispredict_slots / slots_delta
246         machine_clears_ratio = bad_spec_ratio     246         machine_clears_ratio = bad_spec_ratio - br_mispredict_ratio;
247                                                   247 
248         fetch_lat_ratio = (float)fetch_lat_slo    248         fetch_lat_ratio = (float)fetch_lat_slots / slots_delta
249         fetch_bw_ratio = fe_bound_ratio - fetc    249         fetch_bw_ratio = fe_bound_ratio - fetch_lat_ratio;
250                                                   250 
251         mem_bound_ratio = (float)mem_bound_slo    251         mem_bound_ratio = (float)mem_bound_slots / slota_delta
252         core_bound_ratio = be_bound_ratio - me    252         core_bound_ratio = be_bound_ratio - mem_bound_ratio;
253                                                   253 
254         printf("Heavy Operations %.2f%% Light     254         printf("Heavy Operations %.2f%% Light Operations %.2f%% "
255                "Branch Mispredict %.2f%% Machi    255                "Branch Mispredict %.2f%% Machine Clears %.2f%% "
256                "Fetch Latency %.2f%% Fetch Ban    256                "Fetch Latency %.2f%% Fetch Bandwidth %.2f%% "
257                "Mem Bound %.2f%% Core Bound %.    257                "Mem Bound %.2f%% Core Bound %.2f%%\n",
258                 heavy_ops_ratio * 100.,           258                 heavy_ops_ratio * 100.,
259                 light_ops_ratio * 100.,           259                 light_ops_ratio * 100.,
260                 br_mispredict_ratio * 100.,       260                 br_mispredict_ratio * 100.,
261                 machine_clears_ratio * 100.,      261                 machine_clears_ratio * 100.,
262                 fetch_lat_ratio * 100.,           262                 fetch_lat_ratio * 100.,
263                 fetch_bw_ratio * 100.,            263                 fetch_bw_ratio * 100.,
264                 mem_bound_ratio * 100.,           264                 mem_bound_ratio * 100.,
265                 core_bound_ratio * 100.);         265                 core_bound_ratio * 100.);
266                                                   266 
267 Resetting metrics counters                        267 Resetting metrics counters
268 ==========================                        268 ==========================
269                                                   269 
270 Since the individual metrics are only 8bit the    270 Since the individual metrics are only 8bit they lose precision for
271 short regions over time because the number of     271 short regions over time because the number of cycles covered by each
272 fraction bit shrinks. So the counters need to     272 fraction bit shrinks. So the counters need to be reset regularly.
273                                                   273 
274 When using the kernel perf API the kernel rese    274 When using the kernel perf API the kernel resets on every read.
275 So as long as the reading is at reasonable int    275 So as long as the reading is at reasonable intervals (every few
276 seconds) the precision is good.                   276 seconds) the precision is good.
277                                                   277 
278 When using perf stat it is recommended to alwa    278 When using perf stat it is recommended to always use the -I option,
279 with no longer interval than a few seconds        279 with no longer interval than a few seconds
280                                                   280 
281         perf stat -I 1000 --topdown ...           281         perf stat -I 1000 --topdown ...
282                                                   282 
283 For user programs using RDPMC directly the cou    283 For user programs using RDPMC directly the counter can
284 be reset explicitly using ioctl:                  284 be reset explicitly using ioctl:
285                                                   285 
286         ioctl(perf_fd, PERF_EVENT_IOC_RESET, 0    286         ioctl(perf_fd, PERF_EVENT_IOC_RESET, 0);
287                                                   287 
288 This "opens" a new measurement period.            288 This "opens" a new measurement period.
289                                                   289 
290 A program using RDPMC for TopDown should sched    290 A program using RDPMC for TopDown should schedule such a reset
291 regularly, as in every few seconds.               291 regularly, as in every few seconds.
292                                                   292 
293 Limits on Intel Ice Lake                          293 Limits on Intel Ice Lake
294 ========================                          294 ========================
295                                                   295 
296 Four pseudo TopDown metric events are exposed     296 Four pseudo TopDown metric events are exposed for the end-users,
297 topdown-retiring, topdown-bad-spec, topdown-fe    297 topdown-retiring, topdown-bad-spec, topdown-fe-bound and topdown-be-bound.
298 They can be used to collect the TopDown value     298 They can be used to collect the TopDown value under the following
299 rules:                                            299 rules:
300 - All the TopDown metric events must be in a g    300 - All the TopDown metric events must be in a group with the SLOTS event.
301 - The SLOTS event must be the leader of the gr    301 - The SLOTS event must be the leader of the group.
302 - The PERF_FORMAT_GROUP flag must be applied f    302 - The PERF_FORMAT_GROUP flag must be applied for each TopDown metric
303   events                                          303   events
304                                                   304 
305 The SLOTS event and the TopDown metric events     305 The SLOTS event and the TopDown metric events can be counting members of
306 a sampling read group. Since the SLOTS event m    306 a sampling read group. Since the SLOTS event must be the leader of a TopDown
307 group, the second event of the group is the sa    307 group, the second event of the group is the sampling event.
308 For example, perf record -e '{slots, $sampling    308 For example, perf record -e '{slots, $sampling_event, topdown-retiring}:S'
309                                                   309 
310 Extension on Intel Sapphire Rapids Server         310 Extension on Intel Sapphire Rapids Server
311 =========================================         311 =========================================
312 The metrics counter is extended to support TMA    312 The metrics counter is extended to support TMA method level 2 metrics.
313 The lower half of the register is the TMA leve    313 The lower half of the register is the TMA level 1 metrics (legacy).
314 The upper half is also divided into four 8-bit    314 The upper half is also divided into four 8-bit fields for the new level 2
315 metrics. Four more TopDown metric events are e    315 metrics. Four more TopDown metric events are exposed for the end-users,
316 topdown-heavy-ops, topdown-br-mispredict, topd    316 topdown-heavy-ops, topdown-br-mispredict, topdown-fetch-lat and
317 topdown-mem-bound.                                317 topdown-mem-bound.
318                                                   318 
319 Each of the new level 2 metrics in the upper h    319 Each of the new level 2 metrics in the upper half is a subset of the
320 corresponding level 1 metric in the lower half    320 corresponding level 1 metric in the lower half. Software can deduce the
321 other four level 2 metrics by subtracting corr    321 other four level 2 metrics by subtracting corresponding metrics as below.
322                                                   322 
323     Light_Operations = Retiring - Heavy_Operat    323     Light_Operations = Retiring - Heavy_Operations
324     Machine_Clears = Bad_Speculation - Branch_    324     Machine_Clears = Bad_Speculation - Branch_Mispredicts
325     Fetch_Bandwidth = Frontend_Bound - Fetch_L    325     Fetch_Bandwidth = Frontend_Bound - Fetch_Latency
326     Core_Bound = Backend_Bound - Memory_Bound     326     Core_Bound = Backend_Bound - Memory_Bound
327                                                   327 
328 TPEBS in TopDown                               << 
329 ================                               << 
330                                                << 
331 TPEBS (Timed PEBS) is one of the new Intel PMU << 
332 Rapids microarchitecture. The TPEBS feature ad << 
333 in the Basic Info group of the PEBS record. It << 
334 retirement of the previous instruction to the  << 
335 Please refer to Section 8.4.1 of "Intel® Arch << 
336 Programming Reference" for more details about  << 
337 extends PEBS record, sampling with weight opti << 
338 retire_latency value.                          << 
339                                                << 
340         perf record -e event_name -W ...       << 
341                                                << 
342 In the most recent release of TMA, the metrics << 
343 values in some of the metrics’ formulas on p << 
344 For previous generations that do not support T << 
345 predefined per processor family by the hardwar << 
346 of workloads in execution environments, retire << 
347 time are more accurate. Therefore, new TMA met << 
348 more accurate performance analysis results.    << 
349                                                << 
350 To support TPEBS in TMA metrics, a new modifie << 
351 capture retire_latency value of required event << 
352 with perf record. The retire_latency value wou << 
353 Currently, this feature is supported through p << 
354                                                << 
355         perf stat -M metric_name --record-tpeb << 
356                                                << 
357                                                << 
358                                                   328 
359 [1] https://software.intel.com/en-us/top-down-    329 [1] https://software.intel.com/en-us/top-down-microarchitecture-analysis-method-win
360 [2] https://sites.google.com/site/analysismeth    330 [2] https://sites.google.com/site/analysismethods/yasin-pubs
361 [3] https://perf.wiki.kernel.org/index.php/Top    331 [3] https://perf.wiki.kernel.org/index.php/Top-Down_Analysis
362 [4] https://github.com/andikleen/pmu-tools/tre    332 [4] https://github.com/andikleen/pmu-tools/tree/master/jevents
                                                      

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