1 files changed, 327 insertions, 0 deletions
diff --git a/Documentation/trace/tracepoint-analysis.txt b/Documentation/trace/tracepoint-analysis.txt
new file mode 100644
index 000000000000..5eb4e487e667
--- /dev/null
+++ b/Documentation/trace/tracepoint-analysis.txt
@@ -0,0 +1,327 @@
+                Notes on Analysing Behaviour Using Events and Tracepoints
+                        Documentation written by Mel Gorman
+                PCL information heavily based on email from Ingo Molnar
+1. Introduction
+===============
+Tracepoints (see Documentation/trace/tracepoints.txt) can be used without
+creating custom kernel modules to register probe functions using the event
+tracing infrastructure.
+Simplistically, tracepoints will represent an important event that when can
+be taken in conjunction with other tracepoints to build a "Big Picture" of
+what is going on within the system. There are a large number of methods for
+gathering and interpreting these events. Lacking any current Best Practises,
+this document describes some of the methods that can be used.
+This document assumes that debugfs is mounted on /sys/kernel/debug and that
+the appropriate tracing options have been configured into the kernel. It is
+assumed that the PCL tool tools/perf has been installed and is in your path.
+2. Listing Available Events
+===========================
+2.1 Standard Utilities
+----------------------
+All possible events are visible from /sys/kernel/debug/tracing/events. Simply
+calling
+  $ find /sys/kernel/debug/tracing/events -type d
+will give a fair indication of the number of events available.
+2.2 PCL
+-------
+Discovery and enumeration of all counters and events, including tracepoints
+are available with the perf tool. Getting a list of available events is a
+simple case of
+  $ perf list 2>&1 | grep Tracepoint
+  ext4:ext4_free_inode                     [Tracepoint event]
+  ext4:ext4_request_inode                  [Tracepoint event]
+  ext4:ext4_allocate_inode                 [Tracepoint event]
+  ext4:ext4_write_begin                    [Tracepoint event]
+  ext4:ext4_ordered_write_end              [Tracepoint event]
+  [ .... remaining output snipped .... ]
+2. Enabling Events
+==================
+2.1 System-Wide Event Enabling
+------------------------------
+See Documentation/trace/events.txt for a proper description on how events
+can be enabled system-wide. A short example of enabling all events related
+to page allocation would look something like
+  $ for i in `find /sys/kernel/debug/tracing/events -name "enable" | grep mm_`; do echo 1 > $i; done
+2.2 System-Wide Event Enabling with SystemTap
+---------------------------------------------
+In SystemTap, tracepoints are accessible using the kernel.trace() function
+call. The following is an example that reports every 5 seconds what processes
+were allocating the pages.
+  global page_allocs
+  probe kernel.trace("mm_page_alloc") {
+        page_allocs[execname()]++
+  }
+  function print_count() {
+        printf ("%-25s %-s\n", "#Pages Allocated", "Process Name")
+        foreach (proc in page_allocs-)
+                printf("%-25d %s\n", page_allocs[proc], proc)
+        printf ("\n")
+        delete page_allocs
+  }
+  probe timer.s(5) {
+          print_count()
+  }
+2.3 System-Wide Event Enabling with PCL
+---------------------------------------
+By specifying the -a switch and analysing sleep, the system-wide events
+for a duration of time can be examined.
+ $ perf stat -a \
+        -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
+        -e kmem:mm_pagevec_free \
+        sleep 10
+ Performance counter stats for 'sleep 10':
+           9630  kmem:mm_page_alloc
+           2143  kmem:mm_page_free_direct
+           7424  kmem:mm_pagevec_free
+   10.002577764  seconds time elapsed
+Similarly, one could execute a shell and exit it as desired to get a report
+at that point.
+2.4 Local Event Enabling
+------------------------
+Documentation/trace/ftrace.txt describes how to enable events on a per-thread
+basis using set_ftrace_pid.
+2.5 Local Event Enablement with PCL
+-----------------------------------
+Events can be activate and tracked for the duration of a process on a local
+basis using PCL such as follows.
+  $ perf stat -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
+                 -e kmem:mm_pagevec_free ./hackbench 10
+  Time: 0.909
+    Performance counter stats for './hackbench 10':
+          17803  kmem:mm_page_alloc
+          12398  kmem:mm_page_free_direct
+           4827  kmem:mm_pagevec_free
+    0.973913387  seconds time elapsed
+3. Event Filtering
+==================
+Documentation/trace/ftrace.txt covers in-depth how to filter events in
+ftrace.  Obviously using grep and awk of trace_pipe is an option as well
+as any script reading trace_pipe.
+4. Analysing Event Variances with PCL
+=====================================
+Any workload can exhibit variances between runs and it can be important
+to know what the standard deviation in. By and large, this is left to the
+performance analyst to do it by hand. In the event that the discrete event
+occurrences are useful to the performance analyst, then perf can be used.
+  $ perf stat --repeat 5 -e kmem:mm_page_alloc -e kmem:mm_page_free_direct
+                        -e kmem:mm_pagevec_free ./hackbench 10
+  Time: 0.890
+  Time: 0.895
+  Time: 0.915
+  Time: 1.001
+  Time: 0.899
+   Performance counter stats for './hackbench 10' (5 runs):
+          16630  kmem:mm_page_alloc         ( +-   3.542% )
+          11486  kmem:mm_page_free_direct   ( +-   4.771% )
+           4730  kmem:mm_pagevec_free       ( +-   2.325% )
+    0.982653002  seconds time elapsed   ( +-   1.448% )
+In the event that some higher-level event is required that depends on some
+aggregation of discrete events, then a script would need to be developed.
+Using --repeat, it is also possible to view how events are fluctuating over
+time on a system wide basis using -a and sleep.
+  $ perf stat -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
+                -e kmem:mm_pagevec_free \
+                -a --repeat 10 \
+                sleep 1
+  Performance counter stats for 'sleep 1' (10 runs):
+           1066  kmem:mm_page_alloc         ( +-  26.148% )
+            182  kmem:mm_page_free_direct   ( +-   5.464% )
+            890  kmem:mm_pagevec_free       ( +-  30.079% )
+    1.002251757  seconds time elapsed   ( +-   0.005% )
+5. Higher-Level Analysis with Helper Scripts
+============================================
+When events are enabled the events that are triggering can be read from
+/sys/kernel/debug/tracing/trace_pipe in human-readable format although binary
+options exist as well. By post-processing the output, further information can
+be gathered on-line as appropriate. Examples of post-processing might include
+  o Reading information from /proc for the PID that triggered the event
+  o Deriving a higher-level event from a series of lower-level events.
+  o Calculate latencies between two events
+Documentation/trace/postprocess/trace-pagealloc-postprocess.pl is an example
+script that can read trace_pipe from STDIN or a copy of a trace. When used
+on-line, it can be interrupted once to generate a report without existing
+and twice to exit.
+Simplistically, the script just reads STDIN and counts up events but it
+also can do more such as
+  o Derive high-level events from many low-level events. If a number of pages
+    are freed to the main allocator from the per-CPU lists, it recognises
+    that as one per-CPU drain even though there is no specific tracepoint
+    for that event
+  o It can aggregate based on PID or individual process number
+  o In the event memory is getting externally fragmented, it reports
+    on whether the fragmentation event was severe or moderate.
+  o When receiving an event about a PID, it can record who the parent was so
+    that if large numbers of events are coming from very short-lived
+    processes, the parent process responsible for creating all the helpers
+    can be identified
+6. Lower-Level Analysis with PCL
+================================
+There may also be a requirement to identify what functions with a program
+were generating events within the kernel. To begin this sort of analysis, the
+data must be recorded. At the time of writing, this required root
+  $ perf record -c 1 \
+        -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
+        -e kmem:mm_pagevec_free \
+        ./hackbench 10
+  Time: 0.894
+  [ perf record: Captured and wrote 0.733 MB perf.data (~32010 samples) ]
+Note the use of '-c 1' to set the event period to sample. The default sample
+period is quite high to minimise overhead but the information collected can be
+very coarse as a result.
+This record outputted a file called perf.data which can be analysed using
+perf report.
+  $ perf report
+  # Samples: 30922
+  #
+  # Overhead    Command                     Shared Object
+  # ........  .........  ................................
+  #
+      87.27%  hackbench  [vdso]
+       6.85%  hackbench  /lib/i686/cmov/libc-2.9.so
+       2.62%  hackbench  /lib/ld-2.9.so
+       1.52%       perf  [vdso]
+       1.22%  hackbench  ./hackbench
+       0.48%  hackbench  [kernel]
+       0.02%       perf  /lib/i686/cmov/libc-2.9.so
+       0.01%       perf  /usr/bin/perf
+       0.01%       perf  /lib/ld-2.9.so
+       0.00%  hackbench  /lib/i686/cmov/libpthread-2.9.so
+  #
+  # (For more details, try: perf report --sort comm,dso,symbol)
+  #
+According to this, the vast majority of events occured triggered on events
+within the VDSO. With simple binaries, this will often be the case so lets
+take a slightly different example. In the course of writing this, it was
+noticed that X was generating an insane amount of page allocations so lets look
+at it
+  $ perf record -c 1 -f \
+                -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
+                -e kmem:mm_pagevec_free \
+                -p `pidof X`
+This was interrupted after a few seconds and
+  $ perf report
+  # Samples: 27666
+  #
+  # Overhead  Command                            Shared Object
+  # ........  .......  .......................................
+  #
+      51.95%     Xorg  [vdso]
+      47.95%     Xorg  /opt/gfx-test/lib/libpixman-1.so.0.13.1
+       0.09%     Xorg  /lib/i686/cmov/libc-2.9.so
+       0.01%     Xorg  [kernel]
+  #
+  # (For more details, try: perf report --sort comm,dso,symbol)
+  #
+So, almost half of the events are occuring in a library. To get an idea which
+symbol.
+  $ perf report --sort comm,dso,symbol
+  # Samples: 27666
+  #
+  # Overhead  Command                            Shared Object  Symbol
+  # ........  .......  .......................................  ......
+  #
+      51.95%     Xorg  [vdso]                                   [.] 0x000000ffffe424
+      47.93%     Xorg  /opt/gfx-test/lib/libpixman-1.so.0.13.1  [.] pixmanFillsse2
+       0.09%     Xorg  /lib/i686/cmov/libc-2.9.so               [.] _int_malloc
+       0.01%     Xorg  /opt/gfx-test/lib/libpixman-1.so.0.13.1  [.] pixman_region32_copy_f
+       0.01%     Xorg  [kernel]                                 [k] read_hpet
+       0.01%     Xorg  /opt/gfx-test/lib/libpixman-1.so.0.13.1  [.] get_fast_path
+       0.00%     Xorg  [kernel]                                 [k] ftrace_trace_userstack
+To see where within the function pixmanFillsse2 things are going wrong
+  $ perf annotate pixmanFillsse2
+  [ ... ]
+    0.00 :         34eeb:       0f 18 08                prefetcht0 (%eax)
+         :      }
+         :
+         :      extern __inline void __attribute__((__gnu_inline__, __always_inline__, _
+         :      _mm_store_si128 (__m128i *__P, __m128i __B) :      {
+         :        *__P = __B;
+   12.40 :         34eee:       66 0f 7f 80 40 ff ff    movdqa %xmm0,-0xc0(%eax)
+    0.00 :         34ef5:       ff
+   12.40 :         34ef6:       66 0f 7f 80 50 ff ff    movdqa %xmm0,-0xb0(%eax)
+    0.00 :         34efd:       ff
+   12.39 :         34efe:       66 0f 7f 80 60 ff ff    movdqa %xmm0,-0xa0(%eax)
+    0.00 :         34f05:       ff
+   12.67 :         34f06:       66 0f 7f 80 70 ff ff    movdqa %xmm0,-0x90(%eax)
+    0.00 :         34f0d:       ff
+   12.58 :         34f0e:       66 0f 7f 40 80          movdqa %xmm0,-0x80(%eax)
+   12.31 :         34f13:       66 0f 7f 40 90          movdqa %xmm0,-0x70(%eax)
+   12.40 :         34f18:       66 0f 7f 40 a0          movdqa %xmm0,-0x60(%eax)
+   12.31 :         34f1d:       66 0f 7f 40 b0          movdqa %xmm0,-0x50(%eax)
+At a glance, it looks like the time is being spent copying pixmaps to
+the card.  Further investigation would be needed to determine why pixmaps
+are being copied around so much but a starting point would be to take an
+ancient build of libpixmap out of the library path where it was totally
+forgotten about from months ago!

diff --git a/Documentation/trace/tracepoint-analysis.txt b/Documentation/trace/tracepoint-analysis.txt new file mode 100644 index 000000000000..5eb4e487e667 --- /dev/null +++ b/Documentation/trace/tracepoint-analysis.txt
@@ -0,0 +1,327 @@
	1	Notes on Analysing Behaviour Using Events and Tracepoints
	2
	3	Documentation written by Mel Gorman
	4	PCL information heavily based on email from Ingo Molnar
	5
	6	1. Introduction
	7	===============
	8
	9	Tracepoints (see Documentation/trace/tracepoints.txt) can be used without
	10	creating custom kernel modules to register probe functions using the event
	11	tracing infrastructure.
	12
	13	Simplistically, tracepoints will represent an important event that when can
	14	be taken in conjunction with other tracepoints to build a "Big Picture" of
	15	what is going on within the system. There are a large number of methods for
	16	gathering and interpreting these events. Lacking any current Best Practises,
	17	this document describes some of the methods that can be used.
	18
	19	This document assumes that debugfs is mounted on /sys/kernel/debug and that
	20	the appropriate tracing options have been configured into the kernel. It is
	21	assumed that the PCL tool tools/perf has been installed and is in your path.
	22
	23	2. Listing Available Events
	24	===========================
	25
	26	2.1 Standard Utilities
	27	----------------------
	28
	29	All possible events are visible from /sys/kernel/debug/tracing/events. Simply
	30	calling
	31
	32	$ find /sys/kernel/debug/tracing/events -type d
	33
	34	will give a fair indication of the number of events available.
	35
	36	2.2 PCL
	37	-------
	38
	39	Discovery and enumeration of all counters and events, including tracepoints
	40	are available with the perf tool. Getting a list of available events is a
	41	simple case of
	42
	43	$ perf list 2>&1 \| grep Tracepoint
	44	ext4:ext4_free_inode [Tracepoint event]
	45	ext4:ext4_request_inode [Tracepoint event]
	46	ext4:ext4_allocate_inode [Tracepoint event]
	47	ext4:ext4_write_begin [Tracepoint event]
	48	ext4:ext4_ordered_write_end [Tracepoint event]
	49	[ .... remaining output snipped .... ]
	50
	51
	52	2. Enabling Events
	53	==================
	54
	55	2.1 System-Wide Event Enabling
	56	------------------------------
	57
	58	See Documentation/trace/events.txt for a proper description on how events
	59	can be enabled system-wide. A short example of enabling all events related
	60	to page allocation would look something like
	61
	62	$ for i in `find /sys/kernel/debug/tracing/events -name "enable" \| grep mm_`; do echo 1 > $i; done
	63
	64	2.2 System-Wide Event Enabling with SystemTap
	65	---------------------------------------------
	66
	67	In SystemTap, tracepoints are accessible using the kernel.trace() function
	68	call. The following is an example that reports every 5 seconds what processes
	69	were allocating the pages.
	70
	71	global page_allocs
	72
	73	probe kernel.trace("mm_page_alloc") {
	74	page_allocs[execname()]++
	75	}
	76
	77	function print_count() {
	78	printf ("%-25s %-s\n", "#Pages Allocated", "Process Name")
	79	foreach (proc in page_allocs-)
	80	printf("%-25d %s\n", page_allocs[proc], proc)
	81	printf ("\n")
	82	delete page_allocs
	83	}
	84
	85	probe timer.s(5) {
	86	print_count()
	87	}
	88
	89	2.3 System-Wide Event Enabling with PCL
	90	---------------------------------------
	91
	92	By specifying the -a switch and analysing sleep, the system-wide events
	93	for a duration of time can be examined.
	94
	95	$ perf stat -a \
	96	-e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
	97	-e kmem:mm_pagevec_free \
	98	sleep 10
	99	Performance counter stats for 'sleep 10':
	100
	101	9630 kmem:mm_page_alloc
	102	2143 kmem:mm_page_free_direct
	103	7424 kmem:mm_pagevec_free
	104
	105	10.002577764 seconds time elapsed
	106
	107	Similarly, one could execute a shell and exit it as desired to get a report
	108	at that point.
	109
	110	2.4 Local Event Enabling
	111	------------------------
	112
	113	Documentation/trace/ftrace.txt describes how to enable events on a per-thread
	114	basis using set_ftrace_pid.
	115
	116	2.5 Local Event Enablement with PCL
	117	-----------------------------------
	118
	119	Events can be activate and tracked for the duration of a process on a local
	120	basis using PCL such as follows.
	121
	122	$ perf stat -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
	123	-e kmem:mm_pagevec_free ./hackbench 10
	124	Time: 0.909
	125
	126	Performance counter stats for './hackbench 10':
	127
	128	17803 kmem:mm_page_alloc
	129	12398 kmem:mm_page_free_direct
	130	4827 kmem:mm_pagevec_free
	131
	132	0.973913387 seconds time elapsed
	133
	134	3. Event Filtering
	135	==================
	136
	137	Documentation/trace/ftrace.txt covers in-depth how to filter events in
	138	ftrace. Obviously using grep and awk of trace_pipe is an option as well
	139	as any script reading trace_pipe.
	140
	141	4. Analysing Event Variances with PCL
	142	=====================================
	143
	144	Any workload can exhibit variances between runs and it can be important
	145	to know what the standard deviation in. By and large, this is left to the
	146	performance analyst to do it by hand. In the event that the discrete event
	147	occurrences are useful to the performance analyst, then perf can be used.
	148
	149	$ perf stat --repeat 5 -e kmem:mm_page_alloc -e kmem:mm_page_free_direct
	150	-e kmem:mm_pagevec_free ./hackbench 10
	151	Time: 0.890
	152	Time: 0.895
	153	Time: 0.915
	154	Time: 1.001
	155	Time: 0.899
	156
	157	Performance counter stats for './hackbench 10' (5 runs):
	158
	159	16630 kmem:mm_page_alloc ( +- 3.542% )
	160	11486 kmem:mm_page_free_direct ( +- 4.771% )
	161	4730 kmem:mm_pagevec_free ( +- 2.325% )
	162
	163	0.982653002 seconds time elapsed ( +- 1.448% )
	164
	165	In the event that some higher-level event is required that depends on some
	166	aggregation of discrete events, then a script would need to be developed.
	167
	168	Using --repeat, it is also possible to view how events are fluctuating over
	169	time on a system wide basis using -a and sleep.
	170
	171	$ perf stat -e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
	172	-e kmem:mm_pagevec_free \
	173	-a --repeat 10 \
	174	sleep 1
	175	Performance counter stats for 'sleep 1' (10 runs):
	176
	177	1066 kmem:mm_page_alloc ( +- 26.148% )
	178	182 kmem:mm_page_free_direct ( +- 5.464% )
	179	890 kmem:mm_pagevec_free ( +- 30.079% )
	180
	181	1.002251757 seconds time elapsed ( +- 0.005% )
	182
	183	5. Higher-Level Analysis with Helper Scripts
	184	============================================
	185
	186	When events are enabled the events that are triggering can be read from
	187	/sys/kernel/debug/tracing/trace_pipe in human-readable format although binary
	188	options exist as well. By post-processing the output, further information can
	189	be gathered on-line as appropriate. Examples of post-processing might include
	190
	191	o Reading information from /proc for the PID that triggered the event
	192	o Deriving a higher-level event from a series of lower-level events.
	193	o Calculate latencies between two events
	194
	195	Documentation/trace/postprocess/trace-pagealloc-postprocess.pl is an example
	196	script that can read trace_pipe from STDIN or a copy of a trace. When used
	197	on-line, it can be interrupted once to generate a report without existing
	198	and twice to exit.
	199
	200	Simplistically, the script just reads STDIN and counts up events but it
	201	also can do more such as
	202
	203	o Derive high-level events from many low-level events. If a number of pages
	204	are freed to the main allocator from the per-CPU lists, it recognises
	205	that as one per-CPU drain even though there is no specific tracepoint
	206	for that event
	207	o It can aggregate based on PID or individual process number
	208	o In the event memory is getting externally fragmented, it reports
	209	on whether the fragmentation event was severe or moderate.
	210	o When receiving an event about a PID, it can record who the parent was so
	211	that if large numbers of events are coming from very short-lived
	212	processes, the parent process responsible for creating all the helpers
	213	can be identified
	214
	215	6. Lower-Level Analysis with PCL
	216	================================
	217
	218	There may also be a requirement to identify what functions with a program
	219	were generating events within the kernel. To begin this sort of analysis, the
	220	data must be recorded. At the time of writing, this required root
	221
	222	$ perf record -c 1 \
	223	-e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
	224	-e kmem:mm_pagevec_free \
	225	./hackbench 10
	226	Time: 0.894
	227	[ perf record: Captured and wrote 0.733 MB perf.data (~32010 samples) ]
	228
	229	Note the use of '-c 1' to set the event period to sample. The default sample
	230	period is quite high to minimise overhead but the information collected can be
	231	very coarse as a result.
	232
	233	This record outputted a file called perf.data which can be analysed using
	234	perf report.
	235
	236	$ perf report
	237	# Samples: 30922
	238	#
	239	# Overhead Command Shared Object
	240	# ........ ......... ................................
	241	#
	242	87.27% hackbench [vdso]
	243	6.85% hackbench /lib/i686/cmov/libc-2.9.so
	244	2.62% hackbench /lib/ld-2.9.so
	245	1.52% perf [vdso]
	246	1.22% hackbench ./hackbench
	247	0.48% hackbench [kernel]
	248	0.02% perf /lib/i686/cmov/libc-2.9.so
	249	0.01% perf /usr/bin/perf
	250	0.01% perf /lib/ld-2.9.so
	251	0.00% hackbench /lib/i686/cmov/libpthread-2.9.so
	252	#
	253	# (For more details, try: perf report --sort comm,dso,symbol)
	254	#
	255
	256	According to this, the vast majority of events occured triggered on events
	257	within the VDSO. With simple binaries, this will often be the case so lets
	258	take a slightly different example. In the course of writing this, it was
	259	noticed that X was generating an insane amount of page allocations so lets look
	260	at it
	261
	262	$ perf record -c 1 -f \
	263	-e kmem:mm_page_alloc -e kmem:mm_page_free_direct \
	264	-e kmem:mm_pagevec_free \
	265	-p `pidof X`
	266
	267	This was interrupted after a few seconds and
	268
	269	$ perf report
	270	# Samples: 27666
	271	#
	272	# Overhead Command Shared Object
	273	# ........ ....... .......................................
	274	#
	275	51.95% Xorg [vdso]
	276	47.95% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1
	277	0.09% Xorg /lib/i686/cmov/libc-2.9.so
	278	0.01% Xorg [kernel]
	279	#
	280	# (For more details, try: perf report --sort comm,dso,symbol)
	281	#
	282
	283	So, almost half of the events are occuring in a library. To get an idea which
	284	symbol.
	285
	286	$ perf report --sort comm,dso,symbol
	287	# Samples: 27666
	288	#
	289	# Overhead Command Shared Object Symbol
	290	# ........ ....... ....................................... ......
	291	#
	292	51.95% Xorg [vdso] [.] 0x000000ffffe424
	293	47.93% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1 [.] pixmanFillsse2
	294	0.09% Xorg /lib/i686/cmov/libc-2.9.so [.] _int_malloc
	295	0.01% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1 [.] pixman_region32_copy_f
	296	0.01% Xorg [kernel] [k] read_hpet
	297	0.01% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1 [.] get_fast_path
	298	0.00% Xorg [kernel] [k] ftrace_trace_userstack
	299
	300	To see where within the function pixmanFillsse2 things are going wrong
	301
	302	$ perf annotate pixmanFillsse2
	303	[ ... ]
	304	0.00 : 34eeb: 0f 18 08 prefetcht0 (%eax)
	305	: }
	306	:
	307	: extern __inline void __attribute__((__gnu_inline__, __always_inline__, _
	308	: _mm_store_si128 (__m128i *__P, __m128i __B) : {
	309	: *__P = __B;
	310	12.40 : 34eee: 66 0f 7f 80 40 ff ff movdqa %xmm0,-0xc0(%eax)
	311	0.00 : 34ef5: ff
	312	12.40 : 34ef6: 66 0f 7f 80 50 ff ff movdqa %xmm0,-0xb0(%eax)
	313	0.00 : 34efd: ff
	314	12.39 : 34efe: 66 0f 7f 80 60 ff ff movdqa %xmm0,-0xa0(%eax)
	315	0.00 : 34f05: ff
	316	12.67 : 34f06: 66 0f 7f 80 70 ff ff movdqa %xmm0,-0x90(%eax)
	317	0.00 : 34f0d: ff
	318	12.58 : 34f0e: 66 0f 7f 40 80 movdqa %xmm0,-0x80(%eax)
	319	12.31 : 34f13: 66 0f 7f 40 90 movdqa %xmm0,-0x70(%eax)
	320	12.40 : 34f18: 66 0f 7f 40 a0 movdqa %xmm0,-0x60(%eax)
	321	12.31 : 34f1d: 66 0f 7f 40 b0 movdqa %xmm0,-0x50(%eax)
	322
	323	At a glance, it looks like the time is being spent copying pixmaps to
	324	the card. Further investigation would be needed to determine why pixmaps
	325	are being copied around so much but a starting point would be to take an
	326	ancient build of libpixmap out of the library path where it was totally
	327	forgotten about from months ago!