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ftmemsim-valgrind/dhat/docs/dh-manual.xml
Nicholas Nethercote 441bfc5f51 Overhaul DHAT. 
This commit thoroughly overhauls DHAT, moving it out of the
"experimental" ghetto. It makes moderate changes to DHAT itself,
including dumping profiling data to a JSON format output file. It also
implements a new data viewer (as a web app, in dhat/dh_view.html).

The main benefits over the old DHAT are as follows.

- The separation of data collection and presentation means you can run a
  program once under DHAT and then sort the data in various ways. Also,
  full data is in the output file, and the viewer chooses what to omit.

- The data can be sorted in more ways than previously. Some of these
  sorts involve useful filters such as "short-lived" and "zero reads or
  zero writes".

- The tree structure view avoids the need to choose stack trace depth.
  This avoids both the problem of not enough depth (when records that
  should be distinct are combined, and may not contain enough
  information to be actionable) and the problem of too much depth (when
  records that should be combined are separated, making them seem less
  important than they really are).

- Byte and block measures are shown with a percentage relative to the
  global count, which helps gauge relative significance of different
  parts of the profile.

- Byte and blocks measures are also shown with an allocation rate
  (bytes and blocks per million instructions), which enables comparisons
  across multiple profiles, even if those profiles represent different
  workloads.

- Both global and per-node measurements are taken at the global heap
  peak ("At t-gmax"), which gives Massif-like insight into the point of
  peak memory use.

- The final/liftimes stats are a bit more useful than the old deaths
  stats. (E.g. the old deaths stats didn't take into account lifetimes
  of unfreed blocks.)

- The handling of realloc() has changed. The sequence `p = malloc(100);
  realloc(p, 200);` now increases the total block count by 2 and the
  total byte count by 300. Previously it increased them by 1 and 200.
  The new handling is a more operational view that better reflects the
  effect of allocations on performance. It makes a significant
  difference in the results, giving paths involving reallocation (e.g.
  repeated pushing to a growing vector) more prominence.

Other things of note:

- There is now testing, both regression tests that run within the
  standard test suite, and viewer-specific tests that cannot run within
  the standard test suite. The latter are run by loading
  dh_view.html?test=1 in a web browser.

- The commit puts all tool lists in Makefiles (and similar files) in the
  following consistent order: memcheck, cachegrind, callgrind, helgrind,
  drd, massif, dhat, lackey, none; exp-sgcheck, exp-bbv.

- A lot of fields in dh_main.c have been given more descriptive names.
  Those names now match those used in dh_view.js.
2019-02-01 14:54:34 +11:00

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<?xml version="1.0"?> <!-- -*- sgml -*- -->
<!DOCTYPE chapter PUBLIC "-//OASIS//DTD DocBook XML V4.2//EN"
"http://www.oasis-open.org/docbook/xml/4.2/docbookx.dtd"
[ <!ENTITY % vg-entities SYSTEM "../../docs/xml/vg-entities.xml"> %vg-entities; ]>
<chapter id="dh-manual"
xreflabel="DHAT: a dynamic heap analysis tool">
<title>DHAT: a dynamic heap analysis tool</title>
<para>To use this tool, you must specify
<option>--tool=dhat</option> on the Valgrind command line.</para>
<sect1 id="dh-manual.overview" xreflabel="Overview">
<title>Overview</title>
<para>DHAT is a tool for examining how programs use their heap
allocations.</para>
<para>It tracks the allocated blocks, and inspects every memory access
to find which block, if any, it is to. It presents, on an allocation point
basis, information about these blocks such as sizes, lifetimes, numbers of
reads and writes, and read and write patterns.</para>
<para>Using this information it is possible to identify allocation points with
the following characteristics:</para>
<itemizedlist>
<listitem><para>potential process-lifetime leaks: blocks allocated
by the point just accumulate, and are freed only at the end of the
run.</para></listitem>
<listitem><para>excessive turnover: points which chew through a lot
of heap, even if it is not held onto for very long</para></listitem>
<listitem><para>excessively transient: points which allocate very
short lived blocks</para></listitem>
<listitem><para>useless or underused allocations: blocks which are
allocated but not completely filled in, or are filled in but not
subsequently read.</para></listitem>
<listitem><para>blocks with inefficient layout -- areas never
accessed, or with hot fields scattered throughout the
block.</para></listitem>
</itemizedlist>
<para>As with the Massif heap profiler, DHAT measures program progress
by counting instructions, and so presents all age/time related figures
as instruction counts. This sounds a little odd at first, but it
makes runs repeatable in a way which is not possible if CPU time is
used.</para>
</sect1>
<sect1 id="dh-manual.profile" xreflabel="Using DHAT">
<title>Using DHAT</title>
<para>First off, as for normal Valgrind use, you probably want to compile with
debugging info (the <option>-g</option> option). 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.</para>
<para>Second, you need to run your program under DHAT to gather the profiling
information.</para>
<para>Finally, you need to use DHAT's viewer (in a web browser) to get a
detailed presentation of that information.</para>
<sect2 id="dh-manual.running-DHAT" xreflabel="Running DHAT">
<title>Running DHAT</title>
<para>To run DHAT on a program <filename>prog</filename>, run:</para>
<screen><![CDATA[
valgrind --tool=dhat prog
]]></screen>
<para>The program will execute (slowly). Upon completion, summary statistics
that look like this will be printed:</para>
<programlisting><![CDATA[
==11514== Total: 823,849,731 bytes in 3,929,133 blocks
==11514== At t-gmax: 133,485,082 bytes in 436,521 blocks
==11514== At t-end: 258,002 bytes in 2,129 blocks
==11514== Reads: 2,807,182,810 bytes
==11514== Writes: 1,149,617,086 bytes
]]></programlisting>
<para>The first line shows how many heap blocks and bytes were allocated over
the entire execution.</para>
<para>The second line shows how many heap blocks and bytes were alive at
<computeroutput>t-gmax</computeroutput>, i.e. the time when the heap size
reached its global maximum (as measured in bytes).</para>
<para>The third line shows how many heap blocks and bytes were alive at
<computeroutput>t-end</computeroutput>, i.e. the end of execution. In other
words, how many blocks and bytes were not explicitly freed. </para>
<para>The fourth and fifth lines show how many bytes within heap blocks were
read and written during the entire execution. </para>
<para>These lines are moderately interesting at best. More useful information
can be seen with DHAT's viewer.</para>
</sect2>
<sect2 id="dh-manual.outputfile" xreflabel="Output File">
<title>Output File</title>
<para>As well as printing summary information, DHAT also writes more detailed
profiling information to a file. By default this file is named
<filename>dhat.out.&lt;pid&gt;</filename> (where
<filename>&lt;pid&gt;</filename> is the program's process ID), but its name can
be changed with the <option>--dhat-out-file</option> option. This file is JSON,
and intended to be viewed by DHAT's viewer, which is described in the next
section.</para>
<para>The default <computeroutput>.&lt;pid&gt;</computeroutput> 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
<option>--trace-children=yes</option> option of programs that spawn child
processes.</para>
<para>The output file can be big, many megabytes for large applications
built with full debugging information.</para>
</sect2>
</sect1>
<sect1 id="dh-manual.viewer" xreflabel="DHAT's viewer">
<title>DHAT's Viewer</title>
<para>DHAT's viewer can be run in a web browser by loading the file
<computeroutput>dh_view.html</computeroutput>. Use the "Load" button to choose
a DHAT output file to view.</para>
<sect2><title>The Output Header</title>
<para>The first part of the output shows the program command and process ID.
For example:</para>
<programlisting><![CDATA[
Invocation {
Command: /home/njn/moz/rust0/build/x86_64-unknown-linux-gnu/stage2/bin/rustc --crate-name tuple_stress src/main.rs
PID: 18816
}
]]></programlisting>
<para>The second part of the output shows the
<computeroutput>t-gmax</computeroutput> and
<computeroutput>t-end</computeroutput> values again. For example:</para>
<programlisting><![CDATA[
Times {
t-gmax: 8,138,210,673 instrs (86.92% of program duration)
t-end: 9,362,544,994 instrs
}
]]></programlisting>
</sect2>
<sect2><title>The AP Tree</title>
<para>The third part of the output is the largest and most interesting part,
showing the allocation point (AP) tree.</para>
<sect3><title>Structure</title>
The following image shows a screenshot of part of an AP tree. The font is very
small because this screenshot is intended to demonstrate the high-level
structure of the tree rather than the details within the text.
<graphic fileref="images/dh-tree.png" scalefit="1"/>
<para>Like any tree, it has a root node, leaf nodes, and non-leaf nodes. The
structure of the tree is shown by the lines connecting nodes. Child nodes are
beneath their parent and indented one level.</para>
<para>The sub-trees beneath a non-leaf node can be collapsed or expanded by
clicking on the node. It is useful to collapse sub-trees that you aren't
interested in.</para>
<para>Colours are meaningful, and are intended to ease tree navigation, but the
information they represent is also present within the text. (This means that
colour-blind users are not denied any information.)</para>
<para>Each leaf node is coloured green. Each non-leaf node is coloured blue
and has a down arrow (<computeroutput></computeroutput>) next to it when
its sub-tree is expanded. Each non-leaf node is coloured yellow and has a
left arrow (<computeroutput></computeroutput>) next to it when its sub-tree
is collapsed.</para>
<para>The shade of green, blue or yellow used for a node indicate its
significance. Darker shades represent greater significance (in terms of bytes
or blocks).</para>
<para>Note that the entire output is text, even the arrows and lines connecting
nodes. This means you can copy and paste any part of the output easily into an
email, bug report, etc.</para>
</sect3>
<sect3><title>The Root Node</title>
<para>The root node looks like this:</para>
<programlisting><![CDATA[
AP 1/1 (25 children) {
Total: 1,355,253,987 bytes (100%, 67,454.81/Minstr) in 5,943,417 blocks (100%, 295.82/Minstr), avg size 228.03 bytes, avg lifetime 3,134,692,250.67 instrs (15.6% of program duration)
At t-gmax: 423,930,307 bytes (100%) in 1,575,682 blocks (100%), avg size 269.05 bytes
At t-end: 258,002 bytes (100%) in 2,129 blocks (100%), avg size 121.18 bytes
Reads: 5,478,606,988 bytes (100%, 272,685.7/Minstr), 4.04/byte
Writes: 2,040,294,800 bytes (100%, 101,551.22/Minstr), 1.51/byte
Allocated at {
#0: [root]
}
}
]]></programlisting>
<para>The root node covers the entire execution. The information is a superset
of the information shown when DHAT ran, adding details such as allocation
rates, average block sizes, block lifetimes, and read and write ratios. The
next example will explain these in more detail.</para>
</sect3>
<sect3><title>Interior Nodes</title>
<para>AP nodes further down the tree show information about a subset of
allocations. For example:</para>
<programlisting><![CDATA[
AP 1.1/25 (2 children) {
Total: 54,533,440 bytes (4.02%, 2,714.28/Minstr) in 458,839 blocks (7.72%, 22.84/Minstr), avg size 118.85 bytes, avg lifetime 1,127,259,403.64 instrs (5.61% of program duration)
At t-gmax: 0 bytes (0%) in 0 blocks (0%), avg size 0 bytes
At t-end: 0 bytes (0%) in 0 blocks (0%), avg size 0 bytes
Reads: 15,993,012 bytes (0.29%, 796.02/Minstr), 0.29/byte
Writes: 20,974,752 bytes (1.03%, 1,043.97/Minstr), 0.38/byte
Allocated at {
#1: 0x95CACC9: alloc (alloc.rs:72)
#2: 0x95CACC9: alloc (alloc.rs:148)
#3: 0x95CACC9: reserve_internal<syntax::tokenstream::TokenStream,alloc::alloc::Global> (raw_vec.rs:669)
#4: 0x95CACC9: reserve<syntax::tokenstream::TokenStream,alloc::alloc::Global> (raw_vec.rs:492)
#5: 0x95CACC9: reserve<syntax::tokenstream::TokenStream> (vec.rs:460)
#6: 0x95CACC9: push<syntax::tokenstream::TokenStream> (vec.rs:989)
#7: 0x95CACC9: parse_token_trees_until_close_delim (tokentrees.rs:27)
#8: 0x95CACC9: syntax::parse::lexer::tokentrees::<impl syntax::parse::lexer::StringReader<'a>>::parse_token_tree (tokentrees.rs:81)
}
}
]]></programlisting>
<para>The first line indicates the node's position in the tree. The
<computeroutput>1.1</computeroutput> is a unique identifier for the node and
also says that it is the first child node <computeroutput>1</computeroutput>
(which is the root). The <computeroutput>/25</computeroutput> says that it is
one of 25 children, i.e. it has 24 siblings. The <computeroutput>(2
children)</computeroutput> says that this node node has two children of its
own.</para>
<para>Allocations are aggregated by their allocation stack trace. The
<computeroutput>Allocated at</computeroutput> section shows the allocation
stack trace that is shared by all the blocks covered by this node.</para>
<para>The <computeroutput>Total</computeroutput> line shows that this node
accounts for 4.02% of all bytes allocated during execution, and 7.72% of all
blocks. These percentages are useful for comparing the significance of
different nodes within a single profile; an AP that accounts for 10% of bytes
allocated is likely to be more interesting than one that accounts for
2%.</para>
<para>The <computeroutput>Total</computeroutput> line also shows allocation
rates, measured in bytes and blocks per million instructions. These rates are
useful for comparing the significance of nodes across profiles made with
different workloads.</para>
<para>Finally, the <computeroutput>Total</computeroutput> line shows the
average size and lifetimes of these blocks.</para>
<para>The <computeroutput>At t-gmax</computeroutput> line says shows that no
blocks from this AP were alive when the global heap peak occurred. In other
words, these blocks do not contribute at all to the global heap peak.</para>
<para>The <computeroutput>At t-end</computeroutput> line shows that no blocks
were from this AP were alive at shutdown. In other words, all those blocks were
explicitly freed before termination.</para>
<para>The <computeroutput>Reads</computeroutput> and
<computeroutput>Writes</computeroutput> lines show how many bytes were read
within this AP's blocks, the fraction this represents of all heap reads, and
the read rate. Finally, it shows the read ratio, which is the number of reads
per byte. In this case the number is 0.29, which is quite low -- if no byte was
read twice, then only 29% of the allocated bytes, which means that at least 71%
of the bytes were never read! This suggests that the blocks are being
underutilized and might be worth optimizing.</para>
<para>The <computeroutput>Writes</computeroutput> lines is similar to the
<computeroutput>Reads</computeroutput> line. In this case, at most 38% of the
bytes are ever written, and at least 62% of the bytes were never written.
</para>
<para>The <computeroutput>Reads</computeroutput> and
<computeroutput>Writes</computeroutput> measurements suggest that the blocks
are being under-utilised and might be worth optimizing. Having said that, this
kind of under-utilisation is common in data structures that grow, such as
vectors and hash tables, and isn't always fixable. </para>
</sect3>
<sect3><title>Leaf Nodes</title>
<para>This is a leaf node:</para>
<programlisting><![CDATA[
AP 1.1.1.1/2 {
Total: 31,460,928 bytes (2.32%, 1,565.9/Minstr) in 262,171 blocks (4.41%, 13.05/Minstr), avg size 120 bytes, avg lifetime 986,406,885.05 instrs (4.91% of program duration)
Max: 16,779,136 bytes in 65,543 blocks, avg size 256 bytes
At t-gmax: 0 bytes (0%) in 0 blocks (0%), avg size 0 bytes
At t-end: 0 bytes (0%) in 0 blocks (0%), avg size 0 bytes
Reads: 5,964,704 bytes (0.11%, 296.88/Minstr), 0.19/byte
Writes: 10,487,200 bytes (0.51%, 521.98/Minstr), 0.33/byte
Allocated at {
^1: 0x95CACC9: alloc (alloc.rs:72)
^2: 0x95CACC9: alloc (alloc.rs:148)
^3: 0x95CACC9: reserve_internal<syntax::tokenstream::TokenStream,alloc::alloc::Global> (raw_vec.rs:669)
^4: 0x95CACC9: reserve<syntax::tokenstream::TokenStream,alloc::alloc::Global> (raw_vec.rs:492)
^5: 0x95CACC9: reserve<syntax::tokenstream::TokenStream> (vec.rs:460)
^6: 0x95CACC9: push<syntax::tokenstream::TokenStream> (vec.rs:989)
^7: 0x95CACC9: parse_token_trees_until_close_delim (tokentrees.rs:27)
^8: 0x95CACC9: syntax::parse::lexer::tokentrees::<impl syntax::parse::lexer::StringReader<'a>>::parse_token_tree (tokentrees.rs:81)
^9: 0x95CAC39: parse_token_trees_until_close_delim (tokentrees.rs:26)
^10: 0x95CAC39: syntax::parse::lexer::tokentrees::<impl syntax::parse::lexer::StringReader<'a>>::parse_token_tree (tokentrees.rs:81)
#11: 0x95CAC39: parse_token_trees_until_close_delim (tokentrees.rs:26)
#12: 0x95CAC39: syntax::parse::lexer::tokentrees::<impl syntax::parse::lexer::StringReader<'a>>::parse_token_tree (tokentrees.rs:81)
}
}
]]></programlisting>
<para>The <computeroutput>1.1.1.1/2</computeroutput> indicates that this node
is a great-grandchild of the root; is the first grandchild of the node in the
previous example; and has no children.</para>
<para>Leaf nodes contain an additional <computeroutput>Max</computeroutput>
line, indicating the peak memory use for the blocks covered by this AP. (This
peak may have occurred at a time other than
<computeroutput>t-gmax</computeroutput>.) In this case, 31,460,298 bytes were
allocated from this AP, but the maximum size alive at once was 16,779,136
bytes.</para>
<para>Stack frames that begin with a <computeroutput>^</computeroutput> rather
than a <computeroutput>#</computeroutput> are copied from ancestor nodes.
(In this example, the first 8 frames are identical to those from the node in
the previous example.) These frames could be found by tracing back through
ancestor nodes, but that can be annoying, which is why they are duplicated.
This also means that each node makes complete sense on its own.</para>
</sect3>
<sect3><title>Access Counts</title>
<para>If all blocks covered by an AP node have the same size, an additional
<computeroutput>Accesses</computeroutput> field will be present. It indicates
how the reads and writes within these blocks were distributed. For
example:</para>
<programlisting><![CDATA[
Total: 8,388,672 bytes (0.62%, 417.53/Minstr) in 262,146 blocks (4.41%, 13.05/Minstr), avg size 32 bytes, avg lifetime 16,726,078,401.51 instrs (83.25% of program duration)
At t-gmax: 8,388,672 bytes (1.98%) in 262,146 blocks (16.64%), avg size 32 bytes
At t-end: 0 bytes (0%) in 0 blocks (0%), avg size 0 bytes
Reads: 9,109,682 bytes (0.17%, 453.41/Minstr), 1.09/byte
Writes: 7,340,088 bytes (0.36%, 365.34/Minstr), 0.88/byte
Accesses: {
[ 0] 65547 7 8 4 65529 〃 〃 〃 16 〃 〃 〃 12 〃 〃 〃 〃 〃 〃 〃 〃 〃 〃 〃 65542 〃 〃 〃 - - - -
}
]]></programlisting>
<para>Every block covered by this AP was 32 bytes. Within all of those blocks,
byte 0 was accessed (read or written) 65,547 times, byte 1 was accessed 7
times, byte 2 was accessed 8 times, and so on.</para>
<para>The ditto symbol (<computeroutput></computeroutput>) means "same access
count as the previous byte".</para>
<para>A dash (<computeroutput>-</computeroutput>) means "zero". (It is used
instead of <computeroutput>0</computeroutput> because it makes unaccessed
regions more easily identifiable.)</para>
<para>The infinity symbol (<computeroutput></computeroutput>, not present in
this example) means "exceeded the maximum tracked count".</para>
<para>Block layout can often be inferred from counts. For example, these blocks
probably have four separate byte-sized fields, followed by a four-byte field,
and so on.</para>
<para>Access counts can be useful for identifying data alignment holes or other
layout inefficiencies.</para>
</sect3>
<sect3><title>Aggregate Nodes</title>
<para>The AP tree is very large and many nodes represent tiny numbers of blocks
and bytes. Therefore, DHAT's viewer aggregates insignificant nodes like
this:</para>
<programlisting><![CDATA[
AP 1.14.2/2 {
Total: 5,175 blocks (0.09%, 0.26/Minstr)
Allocated at {
[5 insignificant]
}
}
]]></programlisting>
<para>Much of the detail is stripped away, leaving only basic measurements,
along with an indication of how many nodes were aggregated together (5 in this
case).</para>
</sect3>
</sect2>
<sect2><title>The Output Footer</title>
<para>Below the AP tree is a line like this:</para>
<programlisting><![CDATA[
AP significance threshold: total >= 59,434.17 blocks (1%)
]]></programlisting>
<para>It shows the function used to determine if an AP node is significant. All
nodes that don't satisfy this function are aggregated. It is occasionally
useful if you don't understand why an AP node has been aggregated. The exact
threshold depends on the sort metric (see below).</para>
<para>Finally, the bottom of the page shows a legend that explains some of the
terms, abbreviations and symbols used in the output.</para>
</sect2>
<sect2><title>Sort Metrics</title>
<para>The order in which sub-trees are sorted can be changed via the "Sort
metric" drop-down menu at the top of DHAT's viewer. Different sort metrics can
be useful for finding different things. Some sort metrics also incorporate some
filtering, so that only nodes meeting a particular criteria are shown.</para>
<!-- start of xi:include in the manpage -->
<variablelist>
<varlistentry>
<term>Total (bytes)</term>
<listitem><para>The total number of bytes allocated during the execution.
Highly useful for evaluating heap churn, though not quite as useful as
"Total (blocks)".
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (blocks)</term>
<listitem><para>The total number of blocks allocated during the execution.
Highly useful for evaluating heap churn; reducing the number of calls to
the allocator can significantly speed up a program. This is the default
sort metric.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (blocks), tiny</term>
<listitem><para>Like "Total (blocks)", but shows only very small blocks.
Moderately useful, because such blocks are often easy to avoid allocating.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (blocks), short-lived</term>
<listitem><para>Like "Total (blocks)", but shows only very short-lived
blocks. Moderately useful, because such blocks are often easy to avoid
allocating.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (bytes), zero reads or zero writes</term>
<listitem><para>Like "Total (bytes)", but shows only blocks that are
never read or never written to (or both). Highly useful, because such
blocks indicate poor use of memory and are often easy to avoid allocating.
For example, sometimes a block is allocated and written to but then only
read if a condition C is true; in that case, it may be possible to delay
creating the block until condition C is true. Alternatively, sometimes
blocks are created and never used; such blocks are trivial to remove.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (blocks), zero reads or zero writes</term>
<listitem><para>Like "Total (bytes), zero reads or zero writes" but for
blocks. Highly useful.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (bytes), low-access</term>
<listitem><para>Like "Total (bytes)", but shows only blocks that have low
numbers of reads or low numbers of writes (or both). Moderately useful,
because such blocks indicate poor use of memory.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Total (blocks), low-access</term>
<listitem><para>Like "Total (bytes), low-access", but for blocks.
</para></listitem>
</varlistentry>
<varlistentry>
<term>At t-gmax (bytes)</term>
<listitem><para>This shows the breakdown of memory at the point of peak
heap memory usage. Highly useful for reducing peak memory usage.
</para></listitem>
</varlistentry>
<varlistentry>
<term>At t-end (bytes)</term>
<listitem><para>This shows the breakdown of memory at program termination.
Highly useful for identifying process-lifetime leaks.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Reads (bytes)</term>
<listitem><para>The number of bytes read within heap blocks. Occasionally
useful.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Reads (bytes), high-access</term>
<listitem><para>Like "Reads (bytes)", but only shows blocks with high read
ratios. Occasionally useful for identifying hot areas of memory.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Writes (bytes)</term>
<listitem><para>Like "Reads (bytes)", but for writes. Occasionally useful.
</para></listitem>
</varlistentry>
<varlistentry>
<term>Writes (bytes), high-access</term>
<listitem><para>Like "Reads (bytes), high-access", but for writes.
Occasionally useful.
</para></listitem>
</varlistentry>
</variablelist>
<para>The values within a node that represent the chosen sort metric are shown
in bold, so they stand out.</para>
<para>Here is part of an AP node found with "Total (blocks), tiny", showing
blocks with an average size of only 8.67 bytes:</para>
<programlisting><![CDATA[
Total: 3,407,848 bytes (0.25%, 169.62/Minstr) in 393,214 blocks (6.62%, 19.57/Minstr), avg size 8.67 bytes, avg lifetime 1,167,795,629.1 instrs (5.81% of program duration)
]]></programlisting>
<para>Here is part of an AP node found with "Total (blocks), short-lived",
showing blocks with an average lifetime of only 181.75 instructions:</para>
<programlisting><![CDATA[
Total: 23,068,584 bytes (1.7%, 1,148.19/Minstr) in 262,143 blocks (4.41%, 13.05/Minstr), avg size 88 bytes, avg lifetime 181.75 instrs (0% of program duration)
]]></programlisting>
<para>Here is an example of an AP identified with "Total (blocks), zero reads
or zero writes", showing blocks that are allocated but never touched:</para>
<programlisting><![CDATA[
Total: 7,339,920 bytes (0.54%, 365.33/Minstr) in 262,140 blocks (4.41%, 13.05/Minstr), avg size 28 bytes, avg lifetime 1,141,103,997.69 instrs (5.68% of program duration)
Max: 3,669,960 bytes in 131,070 blocks, avg size 28 bytes
At t-gmax: 3,336,400 bytes (0.79%) in 119,157 blocks (7.56%), avg size 28 bytes
At t-end: 0 bytes (0%) in 0 blocks (0%), avg size 0 bytes
Reads: 0 bytes (0%, 0/Minstr), 0/byte
Writes: 0 bytes (0%, 0/Minstr), 0/byte
]]></programlisting>
<para>All the blocks identified by these APs are good candidates for
optimization.</para>
</sect2>
</sect1>
<sect1 id="dh-manual.options" xreflabel="DHAT Command-line Options">
<title>DHAT Command-line Options</title>
<para>DHAT-specific command-line options are:</para>
<!-- start of xi:include in the manpage -->
<variablelist id="dh.opts.list">
<varlistentry id="opt.dhat-out-file" xreflabel="--dhat-out-file">
<term>
<option><![CDATA[--dhat-out-file=<file> ]]></option>
</term>
<listitem>
<para>Write the profile data to
<computeroutput>file</computeroutput> rather than to the default
output file,
<filename>dhat.out.&lt;pid&gt;</filename>. The
<option>%p</option> and <option>%q</option> format specifiers
can be used to embed the process ID and/or the contents of an
environment variable in the name, as is the case for the core
option <option><xref linkend="opt.log-file"/></option>.
</para>
</listitem>
</varlistentry>
</variablelist>
<para>Note that stacks by default have 12 frames. This may be more than
necessary, in which case the <option>--num-callers</option> flag can be used to
reduce the number, which may make DHAT run slightly faster.
</para>
<!-- end of xi:include in the manpage -->
</sect1>
</chapter>
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