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<chapter id="sg-manual"
xreflabel="SGCheck: an experimental stack and global array overrun detector">
<title>SGCheck: an experimental stack and global array overrun detector</title>
<para>To use this tool, you must specify
<option>--tool=exp-sgcheck</option> on the Valgrind
command line.</para>
<sect1 id="sg-manual.overview" xreflabel="Overview">
<title>Overview</title>
<para>SGCheck is a tool for finding overruns of stack and global
arrays. It works by using a heuristic approach derived from an
observation about the likely forms of stack and global array accesses.
</para>
</sect1>
<sect1 id="sg-manual.options" xreflabel="SGCheck Command-line Options">
<title>SGCheck Command-line Options</title>
<para id="sg.opts.list">There are no SGCheck-specific command-line options at present.</para>
<!--
<para>SGCheck-specific command-line options are:</para>
<variablelist id="sg.opts.list">
</variablelist>
-->
</sect1>
<sect1 id="sg-manual.how-works.sg-checks"
xreflabel="How SGCheck Works">
<title>How SGCheck Works</title>
<para>When a source file is compiled
with <option>-g</option>, the compiler attaches DWARF3
debugging information which describes the location of all stack and
global arrays in the file.</para>
<para>Checking of accesses to such arrays would then be relatively
simple, if the compiler could also tell us which array (if any) each
memory referencing instruction was supposed to access. Unfortunately
the DWARF3 debugging format does not provide a way to represent such
information, so we have to resort to a heuristic technique to
approximate it. The key observation is that
<emphasis>
if a memory referencing instruction accesses inside a stack or
global array once, then it is highly likely to always access that
same array</emphasis>.</para>
<para>To see how this might be useful, consider the following buggy
fragment:</para>
<programlisting><![CDATA[
{ int i, a[10]; // both are auto vars
for (i = 0; i <= 10; i++)
a[i] = 42;
}
]]></programlisting>
<para>At run time we will know the precise address
of <computeroutput>a[]</computeroutput> on the stack, and so we can
observe that the first store resulting from <computeroutput>a[i] =
42</computeroutput> writes <computeroutput>a[]</computeroutput>, and
we will (correctly) assume that that instruction is intended always to
access <computeroutput>a[]</computeroutput>. Then, on the 11th
iteration, it accesses somewhere else, possibly a different local,
possibly an un-accounted for area of the stack (eg, spill slot), so
SGCheck reports an error.</para>
<para>There is an important caveat.</para>
<para>Imagine a function such as <function>memcpy</function>, which is used
to read and write many different areas of memory over the lifetime of the
program. If we insist that the read and write instructions in its memory
copying loop only ever access one particular stack or global variable, we
will be flooded with errors resulting from calls to
<function>memcpy</function>.</para>
<para>To avoid this problem, SGCheck instantiates fresh likely-target
records for each entry to a function, and discards them on exit. This
allows detection of cases where (e.g.) <function>memcpy</function>
overflows its source or destination buffers for any specific call, but
does not carry any restriction from one call to the next. Indeed,
multiple threads may make multiple simultaneous calls to
(e.g.) <function>memcpy</function> without mutual interference.</para>
</sect1>
<sect1 id="sg-manual.cmp-w-memcheck"
xreflabel="Comparison with Memcheck">
<title>Comparison with Memcheck</title>
<para>SGCheck and Memcheck are complementary: their capabilities do
not overlap. Memcheck performs bounds checks and use-after-free
checks for heap arrays. It also finds uses of uninitialised values
created by heap or stack allocations. But it does not perform bounds
checking for stack or global arrays.</para>
<para>SGCheck, on the other hand, does do bounds checking for stack or
global arrays, but it doesn't do anything else.</para>
</sect1>
<sect1 id="sg-manual.limitations"
xreflabel="Limitations">
<title>Limitations</title>
<para>This is an experimental tool, which relies rather too heavily on some
not-as-robust-as-I-would-like assumptions on the behaviour of correct
programs. There are a number of limitations which you should be aware
of.</para>
<itemizedlist>
<listitem>
<para>False negatives (missed errors): it follows from the
description above (<xref linkend="sg-manual.how-works.sg-checks"/>)
that the first access by a memory referencing instruction to a
stack or global array creates an association between that
instruction and the array, which is checked on subsequent accesses
by that instruction, until the containing function exits. Hence,
the first access by an instruction to an array (in any given
function instantiation) is not checked for overrun, since SGCheck
uses that as the "example" of how subsequent accesses should
behave.</para>
</listitem>
<listitem>
<para>False positives (false errors): similarly, and more serious,
it is clearly possible to write legitimate pieces of code which
break the basic assumption upon which the checking algorithm
depends. For example:</para>
<programlisting><![CDATA[
{ int a[10], b[10], *p, i;
for (i = 0; i < 10; i++) {
p = /* arbitrary condition */ ? &a[i] : &b[i];
*p = 42;
}
}
]]></programlisting>
<para>In this case the store sometimes
accesses <computeroutput>a[]</computeroutput> and
sometimes <computeroutput>b[]</computeroutput>, but in no cases is
the addressed array overrun. Nevertheless the change in target
will cause an error to be reported.</para>
<para>It is hard to see how to get around this problem. The only
mitigating factor is that such constructions appear very rare, at
least judging from the results using the tool so far. Such a
construction appears only once in the Valgrind sources (running
Valgrind on Valgrind) and perhaps two or three times for a start
and exit of Firefox. The best that can be done is to suppress the
errors.</para>
</listitem>
<listitem>
<para>Performance: SGCheck has to read all of
the DWARF3 type and variable information on the executable and its
shared objects. This is computationally expensive and makes
startup quite slow. You can expect debuginfo reading time to be in
the region of a minute for an OpenOffice sized application, on a
2.4 GHz Core 2 machine. Reading this information also requires a
lot of memory. To make it viable, SGCheck goes to considerable
trouble to compress the in-memory representation of the DWARF3
data, which is why the process of reading it appears slow.</para>
</listitem>
<listitem>
<para>Performance: SGCheck runs slower than Memcheck. This is
partly due to a lack of tuning, but partly due to algorithmic
difficulties. The
stack and global checks can sometimes require a number of range
checks per memory access, and these are difficult to short-circuit,
despite considerable efforts having been made. A
redesign and reimplementation could potentially make it much faster.
</para>
</listitem>
<listitem>
<para>Coverage: Stack and global checking is fragile. If a shared
object does not have debug information attached, then SGCheck will
not be able to determine the bounds of any stack or global arrays
defined within that shared object, and so will not be able to check
accesses to them. This is true even when those arrays are accessed
from some other shared object which was compiled with debug
info.</para>
<para>At the moment SGCheck accepts objects lacking debuginfo
without comment. This is dangerous as it causes SGCheck to
silently skip stack and global checking for such objects. It would
be better to print a warning in such circumstances.</para>
</listitem>
<listitem>
<para>Coverage: SGCheck does not check whether the areas read
or written by system calls do overrun stack or global arrays. This
would be easy to add.</para>
</listitem>
<listitem>
<para>Platforms: the stack/global checks won't work properly on
PowerPC, ARM or S390X platforms, only on X86 and AMD64 targets.
That's because the stack and global checking requires tracking
function calls and exits reliably, and there's no obvious way to do
it on ABIs that use a link register for function returns.
</para>
</listitem>
<listitem>
<para>Robustness: related to the previous point. Function
call/exit tracking for X86 and AMD64 is believed to work properly
even in the presence of longjmps within the same stack (although
this has not been tested). However, code which switches stacks is
likely to cause breakage/chaos.</para>
</listitem>
</itemizedlist>
</sect1>
<sect1 id="sg-manual.todo-user-visible"
xreflabel="Still To Do: User-visible Functionality">
<title>Still To Do: User-visible Functionality</title>
<itemizedlist>
<listitem>
<para>Extend system call checking to work on stack and global arrays.</para>
</listitem>
<listitem>
<para>Print a warning if a shared object does not have debug info
attached, or if, for whatever reason, debug info could not be
found, or read.</para>
</listitem>
<listitem>
<para>Add some heuristic filtering that removes obvious false
positives. This would be easy to do. For example, an access
transition from a heap to a stack object almost certainly isn't a
bug and so should not be reported to the user.</para>
</listitem>
</itemizedlist>
</sect1>
<sect1 id="sg-manual.todo-implementation"
xreflabel="Still To Do: Implementation Tidying">
<title>Still To Do: Implementation Tidying</title>
<para>Items marked CRITICAL are considered important for correctness:
non-fixage of them is liable to lead to crashes or assertion failures
in real use.</para>
<itemizedlist>
<listitem>
<para> sg_main.c: Redesign and reimplement the basic checking
algorithm. It could be done much faster than it is -- the current
implementation isn't very good.
</para>
</listitem>
<listitem>
<para> sg_main.c: Improve the performance of the stack / global
checks by doing some up-front filtering to ignore references in
areas which "obviously" can't be stack or globals. This will
require using information that m_aspacemgr knows about the address
space layout.</para>
</listitem>
<listitem>
<para>sg_main.c: fix compute_II_hash to make it a bit more sensible
for ppc32/64 targets (except that sg_ doesn't work on ppc32/64
targets, so this is a bit academic at the moment).</para>
</listitem>
</itemizedlist>
</sect1>
</chapter>