A Red-Zone memory allocator
- DUMA
- Detect Unintended Memory Access
- Description
- Installation
- Usage
- Catching the Erroneous Line
- Debugging your Program
- Memory Usage and Execution Speed
- Memory Leak Detection
- C++ Memory Operators and Leak Detection
- Compilation Notes for Release/Production
- NO WARRANTY
- Diagnostics
- Comparison with other tools
- Availability
- Issue Tracking
- Security Policy
- Authors
- License
- Version History
- Detect Unintended Memory Access
DUMA helps you detect two of the most common programming errors:
- Software that overruns the boundaries of a
malloc()
memory allocation, - Software that touches memory allocations already released by
free()
.
Unlike other malloc()
debuggers, DUMA will detect read accesses as well as
writes, and it will pinpoint the exact instruction that causes an error.
Electric Fence, the predecessor of DUMA, has been in use at Pixar since 1987, and at many other sites for years.
DUMA uses the virtual memory hardware of your computer to place an
inaccessible memory page immediately after (or before, at the user's option)
each memory allocation. When software reads or writes this inaccessible page,
the hardware issues a segmentation fault, stopping the program at the offending
instruction. It is then trivial to find the erroneous statement using your
favorite debugger. In a similar manner, memory that has been released by
free()
is made inaccessible, and any code that touches it will get a
segmentation fault.
Simply linking your application with libduma.a
will allow you to detect most,
but not all, malloc()
buffer overruns and accesses of free memory. If you want
to be reasonably sure that you've found all catch-able bugs of this type, you'll
have to read and understand the rest of the documentation.
Besides catching these kind of memory bugs, DUMA also provides a means to
detect memory leaks. When using DUMA to pinpoint the source of a
memory-leak, some source modification is necessary - at the minimum, adding
#include "duma.h"
to your source.
DUMA may be installed from compiled binary packages or built from source code.
-
The latest release version of DUMA is available to download from GitHub and other mirrors.
- NOTE: If the latest release version is more than a few dozen commits behind the master branch, you may wish to try the master branch instead of the last release. While there are no guarantees made (for any release of DUMA), best efforts are put forth to ensure the master branch is functional and passes tests on Linux and Solaris.
- Pre-release versions are also available from GitHub and others mirrors.
-
You can use the Git distributed version control tool to download the latest release version, the current development version, or the entire history, from any of several source code repositories.
DUMA may be built using GNU Make.
GNU Make is available for many operating systems, including SunOS / Solaris, GNU/Hurd, AIX, HP-UX, BSD, GNU/Linux, and Microsoft Windows (using Cygwin or UWIN for POSIX compatibility, or natively with the MSYS / MINGW environment.)
GNU Make is often installed as gmake
, but may be installed under
a different name, such as mingw32-make
, mingw64-gmake
, or simply make
(especially on GNU systems such as Linux).
Some non-GNU "Make" systems may work, but are untested and not recommended for building DUMA.
- Inside the unpacked DUMA source directory, create and change to a
new
build
directorymkdir build && cd build
- (Optionally) review
GNUmakefile
for configuration, compilation, and installation options- Check the
OS
andOSTYPE
options (necessary if automated detection is unsuccessful) - Check any other options or variables that may be available
- Check the
- Build DUMA
gmake -f ../GNUmakefile srcdir=../
(for automatic OS detection and defaults; assumes gmake is GNU Make)make -f ../GNUmakefile srcdir=../ OSTYPE=cygwin
(for Microsoft Windows with Cygwin)mingw32-make -f ../GNUmakefile srcdir=../ OSTYPE=msys
(for Microsoft Windows with MSYS / MINGW via Command Prompt (CMD))make -f ../GNUmakefile srcdir=../ OS=linux
(for most GNU/Linux systems)
- Test DUMA
gmake -f ../GNUmakefile check
- Install DUMA
gmake -f ../GNUmakefile install DESTDIR=/opt/duma
- It may be necessary to prefix this command with
su, sudo, doas, etc. to elevate privileges,
depending on the specified
DESTDIR
orprefix
- It may be necessary to prefix this command with
su, sudo, doas, etc. to elevate privileges,
depending on the specified
- Test DUMA installation
gmake -f ../GNUmakefile installcheck
CMake is a portable suite of tools to automate the configuration, building, testing, packaging, and installation of software.
DUMA may be built using CMake 3.1 (December 2014) or later.
- Inside the unpacked DUMA source directory, create and change to a
new
build
directorymkdir build && cd build
- (Optionally) interactively configure compilation and installation options
ccmake ..
orccmake-gui ..
- Generate the necessary build files
cmake ..
- You may also specify options non-interactively, for example
cmake -DCMAKE_BUILD_TYPE="Debug" ..
cmake -DCMAKE_BUILD_TYPE="Release" ..
cmake -DCMAKE_INSTALL_PREFIX="/opt/duma" ..
cmake -DCMAKE_TOOLCHAIN_FILE=/opt/gcc/toolchain_gcc-8.cmake ..
cmake -G "Visual Studio 16 2019" -A "x64" ..
- Refer to the CMake Manual for full details
- Build DUMA
cmake --build .
- Test DUMA
ctest
(add-V
or-VV
for more verbose output)
- Install DUMA
cmake --build . --target "install"
- It may be necessary to prefix this command with
su, sudo, doas, etc. to elevate privileges,
depending on the configured
CMAKE_INSTALL_PREFIX
- It may be necessary to prefix this command with
su, sudo, doas, etc. to elevate privileges,
depending on the configured
- Compile and execute
createconf
- Verify the
duma_config.h
header file generated bycreateconf
- Verify the
- Compile
dumalib
- Customize your project's
INCLUDE
andLIBS
variables, as required for your environment
- Customize your project's
DUMA should work out of the box on most systems, however, specific environments may require additional configuration or warrant special consideration.
-
Both SPARC and Intel processors are supported.
-
DUMA is tested on Solaris using the GNU toolchain (GNU CC, G++, ld, binutils, etc.)
-
Older Solaris systems, such as Solaris 10, using the GNU tools from the Companion CD should add
/opt/sfw/bin
and/opt/sfw/lib/bin
to thePATH
. -
Newer Solaris systems, such as Solaris 11.next or OpenIndiana, require similar configuration.
-
-
The Solaris Studio toolchain has not been tested.
-
FreeBSD
- On FreeBSD 6.2, it is necessary to set
DUMA_DISABLE_BANNER=1
before running any program linked with DUMA. - NOTE: On FreeBSD 7.0 and later, there appears to be an incompatability with the new libthr, which is currently being investigated.
- On FreeBSD 6.2, it is necessary to set
-
NetBSD
-
On NetBSD 3.1 (
HOSTTYPE=i386
/OSTYPE=netbsdelf
), one (1
) memory leak is always detected. -
Installation on NetBSD is untested.
-
- On systems with ARM processors, it may be necessary to set the
DUMA_MEMCPY_OVERLAP
variable, which allows overlapping ofmemcpy()
regions when the destination address is less than the source address.
- On systems with 64-bit MIPS processors (MIPS-III / IV / V, MIPS64,
КОМДИВ-64, OCTEON, VR43xx, ICE9), it may be necessary to explicitly
set the
DUMA_ALIGNMENT
environment variable to eight (8
) bytes.
-
On systems using RISC-V processors, the base instruction set uses only fixed-length 32-bit instructions that must be aligned on four (
4
) byte (32-bit) boundaries. -
However, the standard RISC-V encoding scheme supports compressed and variable-length instructions. These instructions can be any number of 16-bit "instruction parcels" in length, and are always aligned on two (
2
) byte (16-bit) boundaries. -
The RISC-V processor will not fault when accessing an invalid (unaligned) address. Instead, it will simply use the next valid address. The
DUMA_ALIGNMENT
environment variable should be set to a value greater than one (1
) on systems using RISC-V processors.
-
Link your program with the library
libduma.a
. Make sure you are not linking with-lmalloc
,-lmallocdebug
, or with othermalloc()
debugger or enhancer libraries. You can only use one at a time. -
If your system administrator has installed DUMA for public use, you'll be able to use the
-lduma
argument to the linker, otherwise you'll have to put the path-name forlibduma.a
in the linker's command line.
-
If you're using a Bourne-style shell on most UNIX systems, the statement
export LD_PRELOAD=libduma.so
will cause DUMA to be loaded to run all dynamic executables. -
For Darwin-based systems such as macOS X, use
export DYLD_INSERT_LIBRARIES=libduma.dylib
andexport DYLD_FORCE_FLAT_NAMESPACE=1
. -
The included helper command
duma <command>
will run a single command under DUMA. -
For more details, review the documentation for the dynamic linking facility provided by your operating system vendor.
-
Some systems will require special arguments to the linker to assure that you are using the DUMA
malloc()
and not the one from your C library. -
Run your program using a debugger. It's easier to work this way than to create a core file and post-mortem debug it. DUMA can create huge core files, and some operating systems will thus take minutes simply to dump core! Some operating systems will not create usable core files from programs that are linked with DUMA.
-
If your program has one of the errors detected by DUMA, it will get a segmentation fault (
SIGSEGV
) at the offending instruction. Use the debugger to locate the erroneous statement, and repair it.
DUMA has several configuration switches that can be enabled via the shell environment. These switches change what bugs DUMA will detect, so it's important that you know how to use them.
-
You can use the
gdb
command'set environment variable value'
to set shell environment variables only for the program you are going to debug. This is useful especially if you are using the shared DUMA library. -
DUMA_ALIGNMENT
- This is an integer that specifies the alignment for any memory allocations that will be returned by malloc(), calloc(), and realloc(). The value is specified in bytes, thus a value of 4 will cause memory to be aligned to 32-bit boundaries unless your system doesn't have a 8-bit characters.DUMA_ALIGNMENT
is set to the minimum required alignment specific to your environment by default. The minimum required alignment is detected bycreateconf
and stored in the fileduma_config.h
.If your program requires that allocations be aligned to 64-bit boundaries you'll have to set this value to 8. This is the case when compiling with the
-mips2
flag on MIPS-based systems such as those from SGI. For some architectures the default is defined to even more - x86‑64 uses alignment to 16 bytes by default.DUMA internally uses a smaller value if the requested memory size is smaller than the alignment value: the next smaller power of 2 is used.
Thus allocating blocks smaller than
DUMA_ALIGNMENT
may result into smaller alignments - for example when allocating 3 bytes, they would be aligned to 2 byte boundary. This allows better detection of overrun.For this reason, you will sometimes want to set
DUMA_ALIGNMENT
to1
(no alignment), so that you can detect overruns of less than your CPU's word size. Be sure to read the section 'Word-Alignment and Overrun Detection' in this manual page before you try this.To change this value, set
DUMA_ALIGNMENT
in the shell environment to an integer value, or call the macro functionDUMA_SET_ALIGNMENT()
from your code.You don't need to change this setting, if you just need bigger alignment for some special buffers. In this case you may use the function
memalign(alignment, userSize)
. -
DUMA_PROTECT_BELOW
- DUMA usually places an inaccessible page immediately after each memory allocation, so that software that runs past the end of the allocation will be detected. SettingDUMA_PROTECT_BELOW
to1
causes DUMA to place the inaccessible page before the allocation in the address space, so that under-runs will be detected instead of over-runs.To change this value, set
DUMA_PROTECT_BELOW
in the shell environment to an integer value, or call the macro functionDUMA_SET_PROTECT_BELOW()
from your code. -
DUMA_SKIPCOUNT_INIT
- DUMA usually does its initialization with the first memory allocation. On some systems this may collide with initialization of pthreads or other libraries and produce a hang. To get DUMA work even in these situations you can control (with this environment variable) after how many allocations the full internal initialization of DUMA is done. Default is0
. -
DUMA_REPORT_ALL_LEAKS
- DUMA usually reports only memory leaks where the source file-name with line number of the allocating instruction is known. Setting this variable to1
in shell environment reports all memory leaks. The default is0
to avoid reporting of irrelevant memory leaks from system/compiler environment: there are many standard libraries leaking memory, which by default is no real problem as the system frees up all memory on program exit. -
DUMA_FILL
- When set to a value between0
and255
, every byte of allocated memory is initialized to that value. This can help detect reads of uninitialized memory. When set to-1
, DUMA does not initialize memory on allocation, so some memory may filled with zeroes (the operating system default on most systems) and some memory will retain the values written to it during its last use.Per default, DUMA will initialize all allocated bytes to
255
(0xFF
). To change this value, setDUMA_FILL
in the shell environment to an integer value, or call the macro functionDUMA_SET_FILL()
from your code. -
DUMA_SLACKFILL
- As DUMA internally allocates memory in whole pages, there retains an unused and unprotectable piece of memory: the slack or no-mans-land. Per default DUMA will initialize this area to170
(0xAA
), which is10101010
in binary representation.To change this value, set
DUMA_SLACKFILL
in the shell environment to an integer value.DUMA automatically checks this area, the no-mans-land, at deallocation. You can manually induce a check with the macro function
DUMA_CHECK()
for one memory block. With the macro functionDUMA_CHECKALL()
all memory blocks get checked. -
DUMA_CHECK_FREQ
- First seeDUMA_SLACKFILL
above for definition of no-mans-land. Checking the integrity of theno-mans-land costs performance. This is why this is usually done only at deallocation of a memory block. Set this variable to let DUMA check all memory blocks no-mans-land every valueth allocation or deallocation. Set this variable to 1, to let DUMA check at each allocation and deallocation.Per default the value
0
is used, which means to check only at deallocation. -
DUMA_ALLOW_MALLOC_0
- Memory allocation of size zero is ANSI conforming, but, often this is the result of a software bug. For this reason DUMA may trap such calls to malloc() with size zero. I leave this option disabled by default, but you are free to trap these calls setting theDUMA_ALLOC_MALLOC_0
in the shell environment to an integer value. -
DUMA_MALLOC_0_STRATEGY
- This environment variable controls DUMA's behavior onmalloc(0)
:-
0
- abort program with segfault (previouslyALLOW_MALLOC_0 = 0
) -
1
- return NULL pointer -
2
- return always the same pointer to some protected page -
3
- return mid address of a unique protected page (default)ATTENTION: Only
1
and3
are ANSI conforming. But value1
will break most programs, and value3
strategy most system libraries use/implement. All returned pointers can be passed tofree()
.
-
-
DUMA_NEW_0_STRATEGY
- This environment variable controls DUMA's behavior on C++ operator new with size zero:-
2
- return always the same pointer to some protected page -
3
- return mid address of a unique protected page (default)ATTENTION: Only
3
is standard conforming. Value2
may break some, but will work for most programs. With value2
you may reduce the memory consumption.
-
-
DUMA_MALLOC_FAILEXIT
- Many programs do not check for allocation failure. This often leads to delayed errors, no more understandable. Set this variable to a positive integer in the shell environment to exit the program immediately when memory allocation fails. This option is set by default. -
DUMA_PROTECT_FREE
- DUMA usually returns free memory to a pool from which it may be re-allocated. If you suspect that a program may be touching free memory, setDUMA_PROTECT_FREE
shell environment to-1
. This is the default and will cause DUMA not to re-allocate any memory.For programs with many allocations and de-allocations this may lead to the consumption of the full address space and thus to the failure of
malloc()
. It is important to discriminate between address space and physical memory; DUMA does free the physical memory; but the address space is not freed. Thus, the address space may be exhausted despite available physical memory. This is especially important on 32-bit systems. To avoid such failures, you may limit the amount of protected de-allocated memory by settingDUMA_PROTECT_FREE
to a positive value. This value in kB will be the limit for such protected free memory.A value of
0
will disable protection of freed memory. -
DUMA_MAX_ALLOC
- This shell environment variable limits the total memory print of a program. This is another way to indirectly limit the sum of freed protected memory (seeDUMA_PROTECT_FREE
). By default there is no limit (-1
). A positive value is interpreted in kB, which stands for the sum of allocated and freed protected memory. -
DUMA_FREE_ACCESS
- This is a debugging enhancer to catch deallocation of a memory block using watch expressions. DUMA does a write access to the first byte, which may lead a debugger to stop on a watch expression. You have to enable this by setting the shell environment variable to non zero. Default is disabled. -
DUMA_SHOW_ALLOC
- Set this shell environment variable to non-zero to let DUMA print all allocations and de-allocations to the console. Although this generates a lot of messages, this option can be useful to detect inefficient code containing many (de)allocations. This is switched off by default. -
DUMA_SUPPRESS_ATEXIT
- Set this shell environment variable to non-zero when DUMA should skip the installation of its exit handler. The exit handler is called at the end of the main program and checks for memory leaks, so the handler's installation should usually not be suppressed. One reason for doing so regardless are some buggy environments, where calls to the standard C library'satexit()
-function hangs. -
DUMA_DISABLE_BANNER
- Set this shell environment variable to non-zero to suppress the usual start-up message on console. Default is0
. -
DUMA_OUTPUT_DEBUG
- Set this shell environment variable to non-zero to output all DUMA messages to the debugging console. This option is only available on Windows and is off by default. -
DUMA_OUTPUT_STDOUT
- Set this shell environment variable to non-zero to output all DUMA messages to STDOUT. This option is off by default. -
DUMA_OUTPUT_STDERR
- Set this shell environment variable to non-zero to output all DUMA messages to STDERR. This option is on by default. -
DUMA_OUTPUT_FILE
- Set this shell environment variable to a file-name where all DUMA messages should be written to. This option is off by default. -
DUMA_OUTPUT_STACKTRACE
- Set this shell environment variable to non-zero to output a stacktrace of the allocation that is not freed. This option is available only on Windows and is off by default. This option also requires a map file generated by the linker. -
DUMA_OUTPUT_STACKTRACE_MAPFILE
- Set this shell environment variable to the map file, when it isn't found. This is very useful when using detours version of DUMA. This option is available only on Windows. -
DUMA_MEMCPY_OVERLAP
- Set this shell environment variable to allow overlapping of memcpy regions if the destination address is less than source address. (workaround for ARMmemmove
/memcpy
implementation).
There is a conflict between the alignment restrictions that malloc()
operates
under and the debugging strategy used by DUMA. When detecting overruns,
DUMA malloc()
allocates two or more virtual memory pages for each
allocation. The last page is made inaccessible in such a way that any read,
write, or execute access will cause a segmentation fault. Then, DUMA
malloc()
will return an address such that the first byte after the end of the
allocation is on the inaccessible page. Thus, any overrun of the allocation will
cause a segmentation fault.
It follows that the address returned by malloc()
is the address of the
inaccessible page minus the size of the memory allocation. Unfortunately,
malloc()
is required to return word-aligned allocations, since many CPUs can
only access a word when its address is aligned. The conflict happens when
software makes a memory allocation using a size that is not a multiple of the
word size, and expects to do word accesses to that allocation. The location of
the inaccessible page is fixed by hardware at a word-aligned address. If
DUMA malloc()
is to return an aligned address, it must increase the size
of the allocation to a multiple of the word size.
In addition, the functions memalign()
and valloc()
must honor explicit
specifications on the alignment of the memory allocation, and this, as well can
only be implemented by increasing the size of the allocation. Thus, there will
be situations in which the end of a memory allocation contains some padding
space, and accesses of that padding space will not be detected, even if they are
overruns.
DUMA provides the variable DUMA_ALIGNMENT
so that the user can control the
default alignment used by malloc()
, calloc()
, and realloc()
. To debug
overruns as small as a single byte, you can set DUMA_ALIGNMENT
to 1
. This
will result in DUMA malloc()
returning unaligned addresses for allocations
with sizes that are not a multiple of the word size. This is not a problem in
most cases, because compilers must pad the size of objects so that alignment
restrictions are honored when storing those objects in arrays. The problem
surfaces when software allocates odd-sized buffers for objects that must be
word-aligned. One case of this is software that allocates a buffer to contain
a structure and a string, and the string has an odd size (this example was in a
popular TIFF library).
If word references are made to un-aligned buffers, you will see a bus error
(SIGBUS
) instead of a segmentation fault. The only way to fix this is to
re-write the offending code to make byte references or not make odd-sized
allocations, or to set DUMA_ALIGNMENT
to the word size.
Another example of software incompatible with DUMA_ALIGNMENT
set less than
the system word-size is the strcmp()
function and other string functions
on SunOS 4, which make word-sized accesses to character strings, and may
attempt to access up to three bytes beyond the end of a string. These
result in a segmentation fault (SIGSEGV
). The only way around this is to use
versions of the string functions that perform byte references instead of
word references.
Using DUMA - and one of the following strategies - you can determine the offending line(s) of your source code responsible for causing an error.
- Compile your program with debugging information and statically linked to DUMA. On some systems, including some Linux distributions, the linking order is crucial - DUMA must be the last library passed to the linker.
- Start your program from debugger e.g. with
gdb <program>
- Set program environment variables such as
'set environment DUMA_PROTECT_BELOW 1'
- Set your program arguments with
'set args …'
- Run and wait for the segmentation fault
- Compile your program (with debugging information).
- Set
ulimit -c unlimited
to get core files - Start your program, choose one of following options
- Start your program (linked statically with DUMA)
- Start your program with
duma.sh <your_program>
- Wait for a segmentation fault. This should have created a
core[.<pid>]
file, which you can examine (i.e.gdb <program> -c <core file>
)
- Link with
libduma.a
as explained above, ensuring proper linking order. - Run your program in a debugger and fix any overruns or accesses to free memory.
- Quit the debugger.
- Set
DUMA_PROTECT_BELOW = 1
in the shell environment. - Repeat step 2, this time repairing under-runs if they occur.
- Quit the debugger.
- Optionally, read and install
gdbinit.rc
as~/.gdbinit
if you are using thegdb
debugger
- See if you can set
DUMA_ALIGNMENT
to1
, and repeat step 2.- Sometimes this will be too much work, or there will be problems with library routines for which you don't have the source, that will prevent you from doing this.
-
Since DUMA uses at least two virtual memory pages for each of its allocations, it's a terrible memory hog. It may be necessary to configure a swap file so the system will have enough virtual memory available. Also, the way DUMA manipulates memory results in various cache and translation buffer entries being flushed with each call to
malloc()
orfree()
. The end result is that your program will execute slower and use more resources while you are debugging it with DUMA.- The Linux kernel may limit the number of page mappings per process. See
/proc/sys/vm/max_map_count
. You may have to increase this value to allow debugging with DUMA with a command such as:sysctl -w vm.max_map_count=1000000
- The Linux kernel may limit the number of page mappings per process. See
-
Don't leave
libduma.a
enabled and linked in production software. Use it only for debugging. See the section 'Compilation Notes for Release / Production' below.
-
All memory allocation is protocol-ed from DUMA together with the file-name and line number of the calling function. The
atexit()
function checks if each allocated memory block was freed. To disable leak detection add the preprocessor definitionDUMA_SO_NO_LEAKDETECTION
orDUMA_LIB_NO_LEAKDETECTION
toDUMA_OPTIONS
in the Makefile.- If a leak is reported without a source file-name or line number, but is
reproducible with the same pointer, set a conditional breakpoint on the
function
void * duma_alloc_return( void * address)
, for example, using the gdb command'break duma_alloc_return if address==0x123'
- If a leak is reported without a source file-name or line number, but is
reproducible with the same pointer, set a conditional breakpoint on the
function
-
Macros for "
new
" and "delete
" are defined indumapp.h
. These macros give file-name and line number of the calling functions to DUMA, thus allowing the same leak detection reports as formalloc()
andfree()
.dumapp.h
needs to be included from your source file(s).- To disable the C++
new
,delete
,new[]
, anddelete[]
operators, add the preprocessor definitionDUMA_NO_CPP_SUPPORT
toDUMA_OPTIONS
in Makefile.
- To disable the C++
-
Definition of own member
new
/delete
operators for a class will fail because thenew
/delete
keywords are defined as macros from DUMA. You will have to un-define DUMA's macros with following line:#include "noduma.h"
Then you have to call DUMA's operators directly inside your own definition. -
For using DUMA's C++ operators without having the preprocessor macros defined, following syntax can be used:
// const char * file or __FILE__ macro
// int line or __LINE__ macro
// scalar new throwing bad_alloc() on error
ptr = new(file,line) type;
// scalar new returning 0 on error
ptr = new(std::nothrow,file,line) type;
// scalar delete
operator delete(ptr,file,line);
// vector new throwing bad_alloc() on error
ptr = new(file,line) type[n];
// vector new returning 0 on error
ptr = new(std::nothrow,file,line) type[n];
// vector delete
operator delete[](ptr, file,line);
-
Set the preprocessor definition
#define DUMA_NO_DUMA
in your Makefiles to disable DUMA usage - and don't link with DUMA library. WithDUMA_NO_DUMA
defined, all DUMA macro functions get defined, but do nothing.- This way, you don't have to change your code for release compilation, even when using special DUMA macros.
-
This software has NO WARRANTY.
- See the license for complete details.
-
Much effort has been expended to ensure the correctness of DUMA, however, it is (in all likelihood) not theoretically possible to make software of this nature bug-free.
-
DUMA may not report all bugs that exist in your code.
-
It may also incorrectly report bugs that do not exist.
-
-
Segmentation Fault: Examine the offending statement for violation of the boundaries of a memory allocation.
-
Bus Error: See the section on 'Word-Alignment and Overrun Detection' in this manual.
-
Explanation of alignment issues could be improved.
-
Some Sun systems running SunOS 4.1 were reported to signal an access to a protected page with
SIGBUS
rather thanSIGSEGV
. This is most likely an undocumented "feature" of particular Sun hardware versions, and not an operating system anomaly.- On these systems DUMA tests will fail with a bus error unless the
Makefile
is modified to definePAGE_PROTECTION_VIOLATED_SIGNAL
asSIGBUS
.
- On these systems DUMA tests will fail with a bus error unless the
- [pending]
NOTE: All source repositories are mirrors with identical contents.
Copyright © 2020‑2022 Jeffrey H. Johnson <[email protected]>
Copyright © 2006 Michael Eddington <[email protected]>
Copyright © 2002‑2021 Hayati Ayguen <[email protected]>, Procitec GmbH
Copyright © 1987‑1999 Bruce Perens <[email protected]>