Provided by: duma_2.5.21-8_amd64 
NAME
DUMA - DUMA Malloc Debugger
SYNOPSIS
#include <stdlib.h>
void * malloc (size_t size);
void free (void *ptr);
void * realloc (void *ptr, size_t size);
void * calloc (size_t nelem, size_t elsize);
void * memalign (size_t alignment, size_t size);
void * valloc (size_t size);
extern int DUMA_ALIGNMENT;
extern int DUMA_PROTECT_BELOW;
extern int DUMA_PROTECT_FREE;
extern int DUMA_ALLOW_MALLOC_0;
extern int DUMA_FILL;
DESCRIPTION
DUMA helps you detect two common programming bugs: software that overruns the boundaries of a malloc()
memory allocation, and software that touches a memory allocation that has been 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. It 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 bugs of
this type, you'll have to read and understand the rest of this man page.
USAGE
Link your program with the library libduma.a . Make sure you are not linking with -lmalloc,
-lmallocdebug, or with other malloc-debugger or malloc-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 for libduma.a in the linker's command
line. You can also use dynamic linking. If you're using a Bourne shell, the statement export
LD_PRELOAD=libduma.so.0.0 will cause DUMA to be loaded to run all dynamic executables. The command duma
command runs a single command under DUMA.
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.
GLOBAL AND ENVIRONMENT VARIABLES
DUMA has four configuration switches that can be enabled via the shell environment, or by setting the
value of global integer variables using a debugger. These switches change what bugs DUMA will detect, so
it's important that you know how to use them.
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 sizeof(int) by default, since that is generally the word-size
of your CPU. If your program requires that allocations be aligned to 64-bit boundaries and you
have a 32-bit int 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. The memory allocation that is returned
by DUMA malloc() is aligned using the value in DUMA_ALIGNMENT, and its size the multiple of that
value that is greater than or equal to the requested size. For this reason, you will sometimes
want to set DUMA_ALIGNMENT to 0 (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 assign to the global integer variable DUMA_ALIGNMENT using a debugger.
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. Setting DUMA_PROTECT_BELOW to
1 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. When DUMA_PROTECT_BELOW is set, the
DUMA_ALIGNMENT parameter is ignored. All allocations will be aligned to virtual-memory-page
boundaries, and their size will be the exact size that was requested. To change this value, set
DUMA_PROTECT_BELOW in the shell environment to an integer value, or assign to the global integer
variable DUMA_PROTECT_BELOW using a debugger.
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, set DUMA_PROTECT_FREE to 1. This will cause DUMA to never
re-allocate memory once it has been freed, so that any access to free memory will be detected.
Some programs will use tremendous amounts of memory when this parameter is set. To change this
value, set DUMA_PROTECT_FREE in the shell environment to an integer value, or assign to the global
integer variable DUMA_PROTECT_FREE using a debugger.
DUMA_ALLOW_MALLOC_0
By default, DUMA traps calls to malloc() with a size of zero, because they are often the result of
a software bug. If DUMA_ALLOW_MALLOC_0 is non-zero, the software will not trap calls to malloc()
with a size of zero. To change this value, set DUMA_ALLOC_MALLOC_0 in the shell environment to an
integer value, or assign to the global integer variable DUMA_ALLOC_MALLOC_0 using a debugger.
DUMA_FILL
When set to a value between 0 and 255, every byte of allocated memory is initialized to that
value. This can help detect reads of uninitialized memory. When set to -1, some memory is filled
with zeroes (the operating system default on most systems) and some memory will retain the values
written to it during its last use.
DUMA_MEMCPY_OVERLAP
Setting this variable to 1 will make DUMA to ignore memcpy region overlapping when the destination
address is less than source address. It was added as a workaround for ARM port where memmove
implementation calls memcpy if the overlapping destination is safe and produces in false aborts.
WORD-ALIGNMENT AND OVERRUN DETECTION
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 zero. 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 < word-size is the strcmp() function and
other string functions on SunOS (and probably Solaris), 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.
INSTRUCTIONS FOR DEBUGGING YOUR PROGRAM
1. Link with libduma.a as explained above.
2. Run your program in a debugger and fix any overruns or accesses to free memory.
3. Quit the debugger.
4. Set DUMA_PROTECT_BELOW = 1 in the shell environment.
5. Repeat step 2, this time repairing underruns if they occur.
6. Quit the debugger.
7. Read the restrictions in the section on WORD-ALIGNMENT AND OVERRUN DETECTION. See if you can set
DUMA_ALIGNMENT to 0 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.
MEMORY USAGE AND EXECUTION SPEED
Since DUMA uses at least two virtual memory pages for each of its allocations, it's a terrible memory
hog. I've sometimes found it necessary to add a swap file using swapon(8) so that the system would have
enough virtual memory to debug my program. Also, the way we manipulate memory results in various cache
and translation buffer entries being flushed with each call to malloc or free. The end result is that
your program will be much slower and use more resources while you are debugging it with DUMA.
Don't leave libduma.a linked into production software! Use it only for debugging.
AUTHOR
Hayati Ayguen
WARNINGS
I have tried to do as good a job as I can on this software, but I doubt that it is even theoretically
possible to make it bug-free. This software has no warranty. It will not detect some bugs that you might
expect it to detect, and will indicate that some non-bugs are bugs.
LICENSE
Copyright 1987-1999 Bruce Perens. All rights reserved.
This program is free software; you can redistribute it and/or modify it under the terms of the GNU
General Public License, Version 2, as published by the Free Software Foundation. A copy of this license
is distributed with this software in the file "COPYING".
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. Read the file "COPYING" for
more details.
CONTACTING THE AUTHOR
Bruce Perens
1563 Solano Ave. #349
Berkeley, CA 94707
Telephone: 510-526-1165
Internet: bruce@perens.com
FILES
/dev/zero: Source of memory pages (via mmap(2)).
SEE ALSO
malloc(3), mmap(2), mprotect(2), swapon(8)
DIAGNOSTICS
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 page.
BUGS
My explanation of the alignment issue could be improved.
Some Sun systems running SunOS 4.1 were reported to signal an access to a protected page with SIGBUS
rather than SIGSEGV, I suspect this is an undocumented feature of a particular Sun hardware version, not
just the operating system. On these systems, dumatest will fail with a bus error until you modify the
Makefile to define PAGE_PROTECTION_VIOLATED_SIGNAL as SIGBUS.
There are, without doubt, other bugs and porting issues. Please contact me via e-mail if you have any bug
reports, ideas, etc.
WHAT'S BETTER
Purify does a much more thorough job than DUMA, and does not have the huge memory overhead. Checkergcc,
a modified version of the GNU C Compiler that instruments all memory references, is available on Linux
systems and where GCC is used. It performs some of the same tasks as Purify, but only on code that it has
compiled.
10-September-2005 DUMA(3)