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Valgrind User Manual |  |
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Valgrind User Manual | |
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Table of Contents
Detailed technical documentation on how Cachegrind works is available in How Cachegrind works. If you only want to know how to use it, this is the page you need to read.
To use this tool, you must specify
--tool=cachegrind on the
Valgrind command line.
Cachegrind is a tool for doing cache simulations and annotating your source line-by-line with the number of cache misses. In particular, it records:
L1 instruction cache reads and misses;
L1 data cache reads and read misses, writes and write misses;
L2 unified cache reads and read misses, writes and writes misses.
On a modern machine, an L1 miss will typically cost around 10 cycles, and an L2 miss can cost as much as 200 cycles. Detailed cache profiling can be very useful for improving the performance of your program.
Also, since one instruction cache read is performed per instruction executed, you can find out how many instructions are executed per line, which can be useful for traditional profiling and test coverage.
Any feedback, bug-fixes, suggestions, etc, welcome.
First off, as for normal Valgrind use, you probably want to
compile with debugging info (the
-g flag). But by contrast with
normal Valgrind use, you probably do want to turn
optimisation on, since you should profile your program as it will
be normally run.
The two steps are:
Run your program with valgrind
--tool=cachegrind in front of the normal
command line invocation. When the program finishes,
Cachegrind will print summary cache statistics. It also
collects line-by-line information in a file
cachegrind.out.pid, where
pid is the program's process
id.
This step should be done every time you want to collect information about a new program, a changed program, or about the same program with different input.
Generate a function-by-function summary, and possibly
annotate source files, using the supplied
cg_annotate program. Source
files to annotate can be specified manually, or manually on
the command line, or "interesting" source files can be
annotated automatically with the
--auto=yes option. You can
annotate C/C++ files or assembly language files equally
easily.
This step can be performed as many times as you like for each Step 2. You may want to do multiple annotations showing different information each time.
The steps are described in detail in the following sections.
Cachegrind uses a simulation for a machine with a split L1 cache and a unified L2 cache. This configuration is used for all (modern) x86-based machines we are aware of. Old Cyrix CPUs had a unified I and D L1 cache, but they are ancient history now.
The more specific characteristics of the simulation are as follows.
Write-allocate: when a write miss occurs, the block written to is brought into the D1 cache. Most modern caches have this property.
Bit-selection hash function: the line(s) in the cache to which a memory block maps is chosen by the middle bits M--(M+N-1) of the byte address, where:
line size = 2^M bytes
(cache size / line size) = 2^N bytes
Inclusive L2 cache: the L2 cache replicates all the entries of the L1 cache. This is standard on Pentium chips, but AMD Athlons use an exclusive L2 cache that only holds blocks evicted from L1. Ditto AMD Durons and most modern VIAs.
The cache configuration simulated (cache size,
associativity and line size) is determined automagically using
the CPUID instruction. If you have an old machine that (a)
doesn't support the CPUID instruction, or (b) supports it in an
early incarnation that doesn't give any cache information, then
Cachegrind will fall back to using a default configuration (that
of a model 3/4 Athlon). Cachegrind will tell you if this
happens. You can manually specify one, two or all three levels
(I1/D1/L2) of the cache from the command line using the
--I1,
--D1 and
--L2 options.
Other noteworthy behaviour:
References that straddle two cache lines are treated as follows:
If both blocks hit --> counted as one hit
If one block hits, the other misses --> counted as one miss.
If both blocks miss --> counted as one miss (not two)
Instructions that modify a memory location
(eg. inc and
dec) are counted as doing
just a read, ie. a single data reference. This may seem
strange, but since the write can never cause a miss (the read
guarantees the block is in the cache) it's not very
interesting.
Thus it measures not the number of times the data cache is accessed, but the number of times a data cache miss could occur.
If you are interested in simulating a cache with different
properties, it is not particularly hard to write your own cache
simulator, or to modify the existing ones in
vg_cachesim_I1.c,
vg_cachesim_D1.c,
vg_cachesim_L2.c and
vg_cachesim_gen.c. We'd be
interested to hear from anyone who does.
To gather cache profiling information about the program
ls -l, invoke Cachegrind like
this:
valgrind --tool=cachegrind ls -l
The program will execute (slowly). Upon completion, summary statistics that look like this will be printed:
==31751== I refs: 27,742,716 ==31751== I1 misses: 276 ==31751== L2 misses: 275 ==31751== I1 miss rate: 0.0% ==31751== L2i miss rate: 0.0% ==31751== ==31751== D refs: 15,430,290 (10,955,517 rd + 4,474,773 wr) ==31751== D1 misses: 41,185 ( 21,905 rd + 19,280 wr) ==31751== L2 misses: 23,085 ( 3,987 rd + 19,098 wr) ==31751== D1 miss rate: 0.2% ( 0.1% + 0.4%) ==31751== L2d miss rate: 0.1% ( 0.0% + 0.4%) ==31751== ==31751== L2 misses: 23,360 ( 4,262 rd + 19,098 wr) ==31751== L2 miss rate: 0.0% ( 0.0% + 0.4%)
Cache accesses for instruction fetches are summarised
first, giving the number of fetches made (this is the number of
instructions executed, which can be useful to know in its own
right), the number of I1 misses, and the number of L2 instruction
(L2i) misses.
Cache accesses for data follow. The information is similar
to that of the instruction fetches, except that the values are
also shown split between reads and writes (note each row's
rd and
wr values add up to the row's
total).
Combined instruction and data figures for the L2 cache follow that.
As well as printing summary information, Cachegrind also
writes line-by-line cache profiling information to a file named
cachegrind.out.pid. This file
is human-readable, but is best interpreted by the accompanying
program cg_annotate, described
in the next section.
Things to note about the
cachegrind.out.pid
file:
It is written every time Cachegrind is run, and will
overwrite any existing
cachegrind.out.pid
in the current directory (but that won't happen very often
because it takes some time for process ids to be
recycled).
It can be huge: ls -l
generates a file of about 350KB. Browsing a few files and
web pages with a Konqueror built with full debugging
information generates a file of around 15 MB.
The .pid suffix
on the output file name serves two purposes. Firstly, it means you
don't have to rename old log files that you don't want to overwrite.
Secondly, and more importantly, it allows correct profiling with the
--trace-children=yes option of
programs that spawn child processes.
Cache-simulation specific options are:
--I1=<size>,<associativity>,<line_size> --D1=<size>,<associativity>,<line_size> --L2=<size>,<associativity>,<line_size> [default: uses CPUID for automagic cache configuration]
Manually specifies the I1/D1/L2 cache configuration, where
size and
line_size are measured in bytes.
The three items must be comma-separated, but with no spaces,
eg:
valgrind --tool=cachegrind --I1=65535,2,64
You can specify one, two or three of the I1/D1/L2 caches. Any level not manually specified will be simulated using the configuration found in the normal way (via the CPUID instruction, or failing that, via defaults).
Before using cg_annotate,
it is worth widening your window to be at least 120-characters
wide if possible, as the output lines can be quite long.
To get a function-by-function summary, run
cg_annotate --pid in a directory
containing a cachegrind.out.pid
file. The --pid is required so that
cg_annotate knows which log file
to use when several are present.
The output looks like this:
-------------------------------------------------------------------------------- I1 cache: 65536 B, 64 B, 2-way associative D1 cache: 65536 B, 64 B, 2-way associative L2 cache: 262144 B, 64 B, 8-way associative Command: concord vg_to_ucode.c Events recorded: Ir I1mr I2mr Dr D1mr D2mr Dw D1mw D2mw Events shown: Ir I1mr I2mr Dr D1mr D2mr Dw D1mw D2mw Event sort order: Ir I1mr I2mr Dr D1mr D2mr Dw D1mw D2mw Threshold: 99% Chosen for annotation: Auto-annotation: on -------------------------------------------------------------------------------- Ir I1mr I2mr Dr D1mr D2mr Dw D1mw D2mw -------------------------------------------------------------------------------- 27,742,716 276 275 10,955,517 21,905 3,987 4,474,773 19,280 19,098 PROGRAM TOTALS -------------------------------------------------------------------------------- Ir I1mr I2mr Dr D1mr D2mr Dw D1mw D2mw file:function -------------------------------------------------------------------------------- 8,821,482 5 5 2,242,702 1,621 73 1,794,230 0 0 getc.c:_IO_getc 5,222,023 4 4 2,276,334 16 12 875,959 1 1 concord.c:get_word 2,649,248 2 2 1,344,810 7,326 1,385 . . . vg_main.c:strcmp 2,521,927 2 2 591,215 0 0 179,398 0 0 concord.c:hash 2,242,740 2 2 1,046,612 568 22 448,548 0 0 ctype.c:tolower 1,496,937 4 4 630,874 9,000 1,400 279,388 0 0 concord.c:insert 897,991 51 51 897,831 95 30 62 1 1 ???:??? 598,068 1 1 299,034 0 0 149,517 0 0 ../sysdeps/generic/lockfile.c:__flockfile 598,068 0 0 299,034 0 0 149,517 0 0 ../sysdeps/generic/lockfile.c:__funlockfile 598,024 4 4 213,580 35 16 149,506 0 0 vg_clientmalloc.c:malloc 446,587 1 1 215,973 2,167 430 129,948 14,057 13,957 concord.c:add_existing 341,760 2 2 128,160 0 0 128,160 0 0 vg_clientmalloc.c:vg_trap_here_WRAPPER 320,782 4 4 150,711 276 0 56,027 53 53 concord.c:init_hash_table 298,998 1 1 106,785 0 0 64,071 1 1 concord.c:create 149,518 0 0 149,516 0 0 1 0 0 ???:tolower@@GLIBC_2.0 149,518 0 0 149,516 0 0 1 0 0 ???:fgetc@@GLIBC_2.0 95,983 4 4 38,031 0 0 34,409 3,152 3,150 concord.c:new_word_node 85,440 0 0 42,720 0 0 21,360 0 0 vg_clientmalloc.c:vg_bogus_epilogue
First up is a summary of the annotation options:
I1 cache, D1 cache, L2 cache: cache configuration. So you know the configuration with which these results were obtained.
Command: the command line invocation of the program under examination.
Events recorded: event abbreviations are:
Ir : I cache reads
(ie. instructions executed)
I1mr: I1 cache read
misses
I2mr: L2 cache
instruction read misses
Dr : D cache reads
(ie. memory reads)
D1mr: D1 cache read
misses
D2mr: L2 cache data
read misses
Dw : D cache writes
(ie. memory writes)
D1mw: D1 cache write
misses
D2mw: L2 cache data
write misses
Note that D1 total accesses is given by
D1mr +
D1mw, and that L2 total
accesses is given by I2mr +
D2mr +
D2mw.
Events shown: the events shown (a subset of events
gathered). This can be adjusted with the
--show option.
Event sort order: the sort order in which functions are
shown. For example, in this case the functions are sorted
from highest Ir counts to
lowest. If two functions have identical
Ir counts, they will then be
sorted by I1mr counts, and
so on. This order can be adjusted with the
--sort option.
Note that this dictates the order the functions appear.
It is not the order in which the columns
appear; that is dictated by the "events shown" line (and can
be changed with the --show
option).
Threshold: cg_annotate
by default omits functions that cause very low numbers of
misses to avoid drowning you in information. In this case,
cg_annotate shows summaries the functions that account for
99% of the Ir counts;
Ir is chosen as the
threshold event since it is the primary sort event. The
threshold can be adjusted with the
--threshold
option.
Chosen for annotation: names of files specified manually for annotation; in this case none.
Auto-annotation: whether auto-annotation was requested
via the --auto=yes
option. In this case no.
Then follows summary statistics for the whole
program. These are similar to the summary provided when running
valgrind
--tool=cachegrind.
Then follows function-by-function statistics. Each function
is identified by a
file_name:function_name pair. If
a column contains only a dot it means the function never performs
that event (eg. the third row shows that
strcmp() contains no
instructions that write to memory). The name
??? is used if the the file name
and/or function name could not be determined from debugging
information. If most of the entries have the form
???:??? the program probably
wasn't compiled with -g. If any
code was invalidated (either due to self-modifying code or
unloading of shared objects) its counts are aggregated into a
single cost centre written as
(discarded):(discarded).
It is worth noting that functions will come from three types of source files:
From the profiled program
(concord.c in this example).
From libraries (eg. getc.c)
From Valgrind's implementation of some libc functions
(eg. vg_clientmalloc.c:malloc).
These are recognisable because the filename begins with
vg_, and is probably one of
vg_main.c,
vg_clientmalloc.c or
vg_mylibc.c.
There are two ways to annotate source files -- by choosing
them manually, or with the
--auto=yes option. To do it
manually, just specify the filenames as arguments to
cg_annotate. For example, the
output from running cg_annotate concord.c
for our example produces the same output as above followed by an
annotated version of concord.c, a section of
which looks like:
--------------------------------------------------------------------------------
-- User-annotated source: concord.c
--------------------------------------------------------------------------------
Ir I1mr I2mr Dr D1mr D2mr Dw D1mw D2mw
[snip]
. . . . . . . . . void init_hash_table(char *file_name, Word_Node *table[])
3 1 1 . . . 1 0 0 {
. . . . . . . . . FILE *file_ptr;
. . . . . . . . . Word_Info *data;
1 0 0 . . . 1 1 1 int line = 1, i;
. . . . . . . . .
5 0 0 . . . 3 0 0 data = (Word_Info *) create(sizeof(Word_Info));
. . . . . . . . .
4,991 0 0 1,995 0 0 998 0 0 for (i = 0; i < TABLE_SIZE; i++)
3,988 1 1 1,994 0 0 997 53 52 table[i] = NULL;
. . . . . . . . .
. . . . . . . . . /* Open file, check it. */
6 0 0 1 0 0 4 0 0 file_ptr = fopen(file_name, "r");
2 0 0 1 0 0 . . . if (!(file_ptr)) {
. . . . . . . . . fprintf(stderr, "Couldn't open '%s'.\n", file_name);
1 1 1 . . . . . . exit(EXIT_FAILURE);
. . . . . . . . . }
. . . . . . . . .
165,062 1 1 73,360 0 0 91,700 0 0 while ((line = get_word(data, line, file_ptr)) != EOF)
146,712 0 0 73,356 0 0 73,356 0 0 insert(data->;word, data->line, table);
. . . . . . . . .
4 0 0 1 0 0 2 0 0 free(data);
4 0 0 1 0 0 2 0 0 fclose(file_ptr);
3 0 0 2 0 0 . . . }
(Although column widths are automatically minimised, a wide terminal is clearly useful.)
Each source file is clearly marked
(User-annotated source) as
having been chosen manually for annotation. If the file was
found in one of the directories specified with the
-I / --include option, the directory
and file are both given.
Each line is annotated with its event counts. Events not applicable for a line are represented by a `.'; this is useful for distinguishing between an event which cannot happen, and one which can but did not.
Sometimes only a small section of a source file is executed. To minimise uninteresting output, Cachegrind only shows annotated lines and lines within a small distance of annotated lines. Gaps are marked with the line numbers so you know which part of a file the shown code comes from, eg:
(figures and code for line 704) -- line 704 ---------------------------------------- -- line 878 ---------------------------------------- (figures and code for line 878)
The amount of context to show around annotated lines is
controlled by the --context
option.
To get automatic annotation, run
cg_annotate --auto=yes.
cg_annotate will automatically annotate every source file it can
find that is mentioned in the function-by-function summary.
Therefore, the files chosen for auto-annotation are affected by
the --sort and
--threshold options. Each
source file is clearly marked (Auto-annotated
source) as being chosen automatically. Any
files that could not be found are mentioned at the end of the
output, eg:
------------------------------------------------------------------ The following files chosen for auto-annotation could not be found: ------------------------------------------------------------------ getc.c ctype.c ../sysdeps/generic/lockfile.c
This is quite common for library files, since libraries are
usually compiled with debugging information, but the source files
are often not present on a system. If a file is chosen for
annotation both manually and automatically, it
is marked as User-annotated
source. Use the -I /
--include option to tell Valgrind where to look
for source files if the filenames found from the debugging
information aren't specific enough.
Beware that cg_annotate can take some time to digest large
cachegrind.out.pid files,
e.g. 30 seconds or more. Also beware that auto-annotation can
produce a lot of output if your program is large!
Valgrind can annotate assembler programs too, or annotate the assembler generated for your C program. Sometimes this is useful for understanding what is really happening when an interesting line of C code is translated into multiple instructions.
To do this, you just need to assemble your
.s files with assembler-level
debug information. gcc doesn't do this, but you can use the GNU
assembler with the --gstabs
option to generate object files with this information, eg:
as --gstabs foo.s
You can then profile and annotate source files in the same way as for C/C++ programs.
Indicates which
cachegrind.out.pid file to
read. Not actually an option -- it is required.
-h, --help
-v, --version
Help and version, as usual.
--sort=A,B,C [default:
order in
cachegrind.out.pid]
Specifies the events upon which the sorting of the
function-by-function entries will be based. Useful if you
want to concentrate on eg. I cache misses
(--sort=I1mr,I2mr), or D
cache misses
(--sort=D1mr,D2mr), or L2
misses
(--sort=D2mr,I2mr).
--show=A,B,C [default:
all, using order in
cachegrind.out.pid]
Specifies which events to show (and the column
order). Default is to use all present in the
cachegrind.out.pid file (and
use the order in the file).
Sets the threshold for the function-by-function summary. Functions are shown that account for more than X% of the primary sort event. If auto-annotating, also affects which files are annotated.
Note: thresholds can be set for more than one of the
events by appending any events for the
--sort option with a colon
and a number (no spaces, though). E.g. if you want to see
the functions that cover 99% of L2 read misses and 99% of L2
write misses, use this option:
--sort=D2mr:99,D2mw:99
--auto=yes
When enabled, automatically annotates every file that is mentioned in the function-by-function summary that can be found. Also gives a list of those that couldn't be found.
Print N lines of context before and after each annotated line. Avoids printing large sections of source files that were not executed. Use a large number (eg. 10,000) to show all source lines.
-I<dir>,
--include=<dir> [default: empty
string]
Adds a directory to the list in which to search for files. Multiple -I/--include options can be given to add multiple directories.
There are a couple of situations in which
cg_annotate issues
warnings.
If a source file is more recent than the
cachegrind.out.pid file.
This is because the information in
cachegrind.out.pid is only
recorded with line numbers, so if the line numbers change at
all in the source (eg. lines added, deleted, swapped), any
annotations will be incorrect.
If information is recorded about line numbers past the
end of a file. This can be caused by the above problem,
ie. shortening the source file while using an old
cachegrind.out.pid file. If
this happens, the figures for the bogus lines are printed
anyway (clearly marked as bogus) in case they are
important.
Some odd things that can occur during annotation:
If annotating at the assembler level, you might see something like this:
1 0 0 . . . . . . leal -12(%ebp),%eax
1 0 0 . . . 1 0 0 movl %eax,84(%ebx)
2 0 0 0 0 0 1 0 0 movl $1,-20(%ebp)
. . . . . . . . . .align 4,0x90
1 0 0 . . . . . . movl $.LnrB,%eax
1 0 0 . . . 1 0 0 movl %eax,-16(%ebp)
How can the third instruction be executed twice when
the others are executed only once? As it turns out, it
isn't. Here's a dump of the executable, using
objdump -d:
8048f25: 8d 45 f4 lea 0xfffffff4(%ebp),%eax
8048f28: 89 43 54 mov %eax,0x54(%ebx)
8048f2b: c7 45 ec 01 00 00 00 movl $0x1,0xffffffec(%ebp)
8048f32: 89 f6 mov %esi,%esi
8048f34: b8 08 8b 07 08 mov $0x8078b08,%eax
8048f39: 89 45 f0 mov %eax,0xfffffff0(%ebp)
Notice the extra mov
%esi,%esi instruction. Where did this come
from? The GNU assembler inserted it to serve as the two
bytes of padding needed to align the movl
$.LnrB,%eax instruction on a four-byte
boundary, but pretended it didn't exist when adding debug
information. Thus when Valgrind reads the debug info it
thinks that the movl
$0x1,0xffffffec(%ebp) instruction covers the
address range 0x8048f2b--0x804833 by itself, and attributes
the counts for the mov
%esi,%esi to it.
Inlined functions can cause strange results in the
function-by-function summary. If a function
inline_me() is defined in
foo.h and inlined in the functions
f1(),
f2() and
f3() in
bar.c, there will not be a
foo.h:inline_me() function
entry. Instead, there will be separate function entries for
each inlining site, ie.
foo.h:f1(),
foo.h:f2() and
foo.h:f3(). To find the
total counts for
foo.h:inline_me(), add up
the counts from each entry.
The reason for this is that although the debug info
output by gcc indicates the switch from
bar.c to foo.h, it
doesn't indicate the name of the function in
foo.h, so Valgrind keeps using the old
one.
Sometimes, the same filename might be represented with
a relative name and with an absolute name in different parts
of the debug info, eg:
/home/user/proj/proj.h and
../proj.h. In this case, if you use
auto-annotation, the file will be annotated twice with the
counts split between the two.
Files with more than 65,535 lines cause difficulties
for the stabs debug info reader. This is because the line
number in the struct nlist
defined in a.out.h under Linux is only a
16-bit value. Valgrind can handle some files with more than
65,535 lines correctly by making some guesses to identify
line number overflows. But some cases are beyond it, in
which case you'll get a warning message explaining that
annotations for the file might be incorrect.
If you compile some files with
-g and some without, some
events that take place in a file without debug info could be
attributed to the last line of a file with debug info
(whichever one gets placed before the non-debug-info file in
the executable).
This list looks long, but these cases should be fairly rare.
Note: stabs is not an easy
format to read. If you come across bizarre annotations that
look like might be caused by a bug in the stabs reader, please
let us know.
Valgrind's cache profiling has a number of shortcomings:
It doesn't account for kernel activity -- the effect of system calls on the cache contents is ignored.
It doesn't account for other process activity (although this is probably desirable when considering a single program).
It doesn't account for virtual-to-physical address mappings; hence the entire simulation is not a true representation of what's happening in the cache.
It doesn't account for cache misses not visible at the instruction level, eg. those arising from TLB misses, or speculative execution.
Valgrind will schedule threads differently from how they would be when running natively. This could warp the results for threaded programs.
The x86/amd64 instructions bts,
btr and
btc will incorrectly be
counted as doing a data read if both the arguments are
registers, eg:
btsl %eax, %edx
This should only happen rarely.
x86/amd64 FPU instructions with data sizes of 28 and 108 bytes
(e.g. fsave) are treated as
though they only access 16 bytes. These instructions seem to
be rare so hopefully this won't affect accuracy much.
Another thing worth nothing is that results are very
sensitive. Changing the size of the
valgrind.so file, the size of the program
being profiled, or even the length of its name can perturb the
results. Variations will be small, but don't expect perfectly
repeatable results if your program changes at all.
While these factors mean you shouldn't trust the results to be super-accurate, hopefully they should be close enough to be useful.