11.4 Dhrystone Test

This plug-in allows to test the performance of your CPU. It's an old benchmark that is included in the package as example of VEGA ZZ plug-in system. The plug-in was developed in C/C++ using Reinhold P. Weicker's original code and to show it, you must select Tools Dhrystone test in main menu.

 

Dhrystone 2.1 CPU Test

 

Clicking Run button, the test begin. The plug-in shows an error message if the number of steps is too little to obtain meaningful results. Faster CPUs require higher number of steps.

 

Results

 

Clicking the About label, the copyright dialog is shown:

 

  About Dhrystone

 

For more information about Dhrystone test, see below:

    Dhrystone Benchmark: Rationale for Version 2 and Measurement Rules
                 Reinhold P. Weicker
                 Siemens AG, E STE 35
                 Postfach 3240
                 D-8520 Erlangen
                 Germany (West)


1.  Why a Version 2 of Dhrystone?
The Dhrystone benchmark  program  [1]  has  become  a  popular  benchmark  for
CPU/compiler   performance   measurement,   in   particular  in  the  area  of
minicomputers, workstations, PC's and microprocessors. It apparently satisfies
a  need  for  an  easy-to-use  integer benchmark; it gives a first performance
indication which is more meaningful than MIPS numbers which, in their  literal
meaning  (million  instructions  per  second), cannot be used across different
instruction sets (e.g. RISC  vs.  CISC).   With  the  increasing  use  of  the
benchmark, it seems necessary to reconsider the benchmark and to check whether
it can still fulfill this function.  Version 2 of Dhrystone is the  result  of
such a re-evaluation, it has been made for two reasons:
o Dhrystone has been published in Ada [1], and Versions in Ada, Pascal  and  C
  have  been  distributed  by  Reinhold Weicker via floppy disk.  However, the
  version that was used most often for benchmarking has been the version  made
  by  Rick  Richardson  by another translation from the Ada version into the C
  programming language, this has been the version  distributed  via  the  UNIX
  network Usenet [2].
  There is an obvious need for a common C version of Dhrystone, since C is  at
  present  the  most  popular  system  programming  language  for the class of
  systems (microcomputers, minicomputers,  workstations)  where  Dhrystone  is
  used  most.   There  should  be,  as  far as possible, only one C version of
  Dhrystone such that results can be compared  without  restrictions.  In  the
  past,  the  C  versions  distributed by Rick Richardson (Version 1.1) and by
  Reinhold Weicker had small (though not significant) differences.
  Together with the new C version, the  Ada  and  Pascal  versions  have  been
  updated as well.
o As far as it is  possible  without  changes  to  the  Dhrystone  statistics,
  optimizing   compilers   should   be  prevented  from  removing  significant
  statements.  It has  turned  out  in  the  past  that  optimizing  compilers
  suppressed  code  generation for too many statements (by "dead code removal"
  or  "dead  variable  elimination").   This  has  lead  to  the  danger  that
  benchmarking  results obtained by a naive application of Dhrystone - without
  inspection of the code that was generated - could become meaningless.
The  overall  policy   for  version  2  has  been  that  the  distribution  of
statements,  operand types and operand locality described in [1] should remain
unchanged as much as possible.  (Very few changes were necessary; their impact
should be negligible.)  Also, the order of statements should remain unchanged.
Although I am aware of some critical remarks on the benchmark - I  agree  with
several  of them - and know some suggestions for improvement, I didn't want to
change the benchmark into something different from what has  become  known  as
"Dhrystone"; the confusion generated by such a change would probably outweight
the benefits. If I were to write a new benchmark program, I wouldn't  give  it
the  name  "Dhrystone"  since  this  denotes  the  program  published  in [1].
However, I do recognize  the  need  for  a  larger  number  of  representative
programs  that can be used as benchmarks; users should always be encouraged to
use more than just one benchmark.
The new versions (version 2.1 for C, Pascal and Ada) will  be  distributed  as
widely as possible.  (Version 2.1 differs from version 2.0 distributed via the
UNIX Network Usenet in  March  1988  only  in  a  few  corrections  for  minor
deficiencies  found  by  users  of  version 2.0.)  Readers who want to use the
benchmark for their own measurements can obtain  a  copy  in  machine-readable
form on floppy disk (MS-DOS or XENIX format) from the author.
2.  Overall Characteristics of Version 2
In general, version 2  follows  -  in  the  parts  that  are  significant  for
performance  measurement,  i.e.   within  the measurement loop - the published
(Ada) version and the C versions previously distributed.  Where  the  versions
distributed  by  Rick Richardson [2] and Reinhold Weicker have been different,
it  follows  the  version  distributed  by  Reinhold  Weicker.  (However,  the
differences  have  been  so  small  that their impact on execution time in all
likelihood has been negligible.)  The initialization and UNIX  instrumentation
part  -  which  had  been  omitted  in  [1] - follows mostly the ideas of Rick
Richardson [2].  However, any changes in the initialization part  and  in  the
printing  of  the  result have no impact on performance measurement since they
are outside the  measurement loop.  As a concession to older compilers,  names
have been made unique within the first 8 characters for the C version.
The original publication of Dhrystone did not contain any statements for  time
measurement  since  they  are necessarily system-dependent. However, it turned
out that it is not enough just to enclose the main procedure of Dhrystone in a
loop  and  to  measure the execution time.  If the variables that are computed
are not used somehow, there is the danger that the compiler considers them  as
"dead  variables" and suppresses code generation for a part of the statements.
Therefore in version 2 all variables of "main" are printed at the end  of  the
program.  This also permits some plausibility control for correct execution of
the benchmark.
At several places in the benchmark, code has been added, but only in  branches
that  are  not  executed. The intention is that optimizing compilers should be
prevented from moving code out of the measurement loop, or from removing  code
altogether.  Statements that are executed have been changed in very few places
only.  In these cases, only the role of some operands has been changed, and it
was   made  sure  that  the  numbers  defining  the  "Dhrystone  distribution"
(distribution of statements, operand types and locality) still hold as much as
possible.   Except for sophisticated optimizing compilers, execution times for
version 2.1 should be the same as for previous versions.
Because of the self-imposed limitation that the order and distribution of  the
executed  statements  should  not  be  changed,  there  are  still cases where
optimizing compilers may not generate code for some statements. To  a  certain
degree,  this  is  unavoidable  for  small synthetic benchmarks.  Users of the
benchmark are advised to check code listings whether code is generated for all
statements of Dhrystone.
Contrary to the suggestion in the published paper and its realization  in  the
versions previously distributed, no attempt has been made to subtract the time
for the measurement loop overhead. (This calculation has proven  difficult  to
implement  in  a  correct  way,  and  its omission makes the program simpler.)
However, since the loop check is now part of the benchmark, this does have  an
impact  -  though a very minor one - on the distribution statistics which have
been updated for this version.
3.  Discussion of Individual Changes
In this section, all changes are described that affect  the  measurement  loop
and  that  are  not  just  renaming   of variables. All remarks refer to the C
version; the other language versions have been updated similarly.
In addition to adding  the  measurement  loop  and  the  printout  statements,
changes have been made at the following places:
o In procedure "main", three statements have been added  in  the  non-executed
  "then" part of the statement
        if (Enum_Loc == Func_1 (Ch_Index, 'C'))
  they are
        strcpy (Str_2_Loc, "DHRYSTONE PROGRAM, 3'RD STRING");
        Int_2_Loc = Run_Index;
        Int_Glob = Run_Index;
  The string assignment prevents  movement  of  the  preceding  assignment  to
  Str_2_Loc  (5'th  statement  of  "main")  out  of the measurement loop (This
  probably will not happen for the C version, but it did happen  with  another
  language   and  compiler.)   The  assignment  to  Int_2_Loc  prevents  value
  propagation for Int_2_Loc, and the assignment to Int_Glob makes the value of
  Int_Glob possibly dependent from the value of Run_Index.
o In the three arithmetic computations at the end of the measurement  loop  in
  "main  ",  the  role  of  some  variables has been exchanged, to prevent the
  division from just cancelling out the multiplication as it was  in  [1].   A
  very   smart  compiler  might  have  recognized  this  and  suppressed  code
  generation for the division.
o For Proc_2, no code has been changed, but the values of the actual parameter
  have changed due to changes in "main".
o In Proc_4, the second assignment has been changed from
        Bool_Loc = Bool_Loc | Bool_Glob;
  to
        Bool_Glob = Bool_Loc | Bool_Glob;
  It now assigns a value to a global variable  instead  of  a  local  variable
  (Bool_Loc);   Bool_Loc  would  be  a  "dead  variable"  which  is  not  used
  afterwards.
o In Func_1, the statement
        Ch_1_Glob = Ch_1_Loc;
  was added in the non-executed "else" part of the "if" statement, to  prevent
  the suppression of code generation for the assignment to Ch_1_Loc.
o In Func_2, the second character comparison statement has been changed to
        if (Ch_Loc == 'R')
  ('R' instead of 'X') because  a  comparison  with  'X'  is  implied  in  the
  preceding "if" statement.
  Also in Func_2, the statement
        Int_Glob = Int_Loc;
  has been added in the non-executed part of the last "if" statement, in order
  to prevent Int_Loc from becoming a dead variable.
o In Func_3, a non-executed "else" part has been added to the "if"  statement.
  While  the  program  would  not be incorrect without this "else" part, it is
  considered bad programming practice if a function  can  be  left  without  a
  return value.
  To compensate for this change, the (non-executed) "else" part  in  the  "if"
  statement of Proc_3 was removed.
The distribution statistics have been changed only  by  the  addition  of  the
measurement loop iteration (1 additional statement, 4 additional local integer
operands) and by the change in Proc_4  (one  operand  changed  from  local  to
global).  The distribution statistics in the comment headers have been updated
accordingly.
4.  String Operations
The string operations (string assignment and string comparison) have not  been
changed, to keep the program consistent with the original version.
There has been some concern that the string operations are over-represented in
the  program,  and that execution time is dominated by these operations.  This
was true in particular when optimizing compilers removed too much code in  the
main part of the program, this should have been mitigated in version 2.
It should be noted that this is a  language-dependent  issue:   Dhrystone  was
first  published  in  Ada, and with Ada or Pascal semantics, the time spent in
the string operations is,  at  least  in  all  implementations  known  to  me,
considerably smaller.  In Ada and Pascal, assignment and comparison of strings
are operators defined in the language, and the upper  bounds  of  the  strings
occuring  in  Dhrystone  are part of the type information known at compilation
time.  The compilers can therefore generate  efficient  inline  code.   In  C,
string  assignment and comparisons are not part of the language, so the string
operations must be expressed in terms of the C library functions "strcpy"  and
"strcmp".   (ANSI  C  allows  an  implementation  to use inline code for these
functions.)  In addition to the overhead caused by additional function  calls,
these  functions  are  defined for null-terminated strings where the length of
the strings is not known at compilation time; the function has to check  every
byte for the termination condition (the null byte).
Obviously, a C library which includes efficiently coded "strcpy" and  "strcmp"
functions  helps to obtain good Dhrystone results. However, I don't think that
this is unfair since string  functions  do  occur  quite  frequently  in  real
programs  (editors, command interpreters, etc.).  If the strings functions are
implemented efficiently,  this  helps  real  programs  as  well  as  benchmark
programs.
I admit that the  string  comparison  in  Dhrystone  terminates  later  (after
scanning  20  characters)  than most string comparisons in real programs.  For
consistency with the original benchmark, I didn't change the  program  despite
this weakness.
5.  Intended Use of Dhrystone
When Dhrystone is used, the following "ground rules" apply:
o Separate compilation (Ada and C versions)
  As mentioned in [1], Dhrystone was written  to  reflect  actual  programming
  practice  in  systems  programming.   The  division into several compilation
  units (5 in the Ada version, 2 in the C version)  is  intended,  as  is  the
  distribution of inter-module and intra-module subprogram calls.  Although on
  many systems there will be no difference in execution time  to  a  Dhrystone
  version  where  all  compilation units are merged into one file, the rule is
  that separate compilation should  be  used.   The  intention  is  that  real
  programming  practice,  where  programs  consist  of  several  independently
  compiled units, should  be  reflected.   This  also  has  implies  that  the
  compiler,  while  compiling  one  unit,  has no information about the use of
  variables, register allocation etc. occurring in  other  compilation  units.
  Although  in  real  life  compilation  units  will  probably  be larger, the
  intention is that these effects  of  separate  compilation  are  modeled  in
  Dhrystone.
  A few language systems have post-linkage optimization available (e.g., final
  register allocation is performed after linkage).  This is a borderline case:
  Post-linkage  optimization  involves  additional  program  preparation  time
  (although  not  as  much  as  compilation in one unit) which may prevent its
  general use in practical programming.  I think that  since  it  defeats  the
  intentions given above, it should not be used for Dhrystone.
  Unfortunately, ISO/ANSI  Pascal  does  not  contain  language  features  for
  separate  compilation.   Although  most  commercial Pascal compilers provide
  separate compilation in some way, we cannot use it for Dhrystone since  such
  a  version  would  not  be portable.  Therefore, no attempt has been made to
  provide a Pascal version with several compilation units.
o No procedure merging
  Although Dhrystone contains some very short procedures where execution would
  benefit  from  procedure  merging (inlining, macro expansion of procedures),
  procedure merging is not to be used.  The reason is that the  percentage  of
  procedure  and  function  calls  is  part of the "Dhrystone distribution" of
  statements contained in [1].  This restriction does not hold for the  string
  functions  of  the  C  version  since ANSI C allows an implementation to use
  inline code for these functions.
o Other optimizations are allowed, but they should be indicated
  It is often hard to draw an exact line between "normal code generation"  and
  "optimization"  in  compilers:  Some compilers perform operations by default
  that are invoked in other compilers only  when  optimization  is  explicitly
  requested.  Also, we cannot avoid that in benchmarking people try to achieve
  results that look as good as possible.  Therefore,  optimizations  performed
  by  compilers  -  other  than  those  listed  above - are not forbidden when
  Dhrystone execution times are measured.  Dhrystone is  not  intended  to  be
  non-optimizable  but  is  intended  to  be  similarly  optimizable as normal
  programs.   For  example,  there  are  several  places  in  Dhrystone  where
  performance   benefits   from   optimizations   like   common  subexpression
  elimination, value  propagation  etc.,  but  normal  programs  usually  also
  benefit  from  these  optimizations.   Therefore,  no  effort  was  made  to
  artificially  prevent  such  optimizations.   However,  measurement  reports
  should  indicate  which  compiler  optimization  levels  have been used, and
  reporting results with different levels of  compiler  optimization  for  the
  same hardware is encouraged.
o Default results are those without "register" declarations (C version)
  When Dhrystone results are quoted  without  additional  qualification,  they
  should  be  understood  as  results  obtained  without use of the "register"
  attribute. Good compilers should be able to make good use of registers  even
  without explicit register declarations ([3], p. 193).
Of course, for experimental  purposes,  post-linkage  optimization,  procedure
merging and/or compilation in one unit can be done to determine their effects.
However,  Dhrystone  numbers  obtained  under  these  conditions   should   be
explicitly  marked as such; "normal" Dhrystone results should be understood as
results obtained following the ground rules listed above.
In any case, for serious performance evaluation, users are advised to ask  for
code  listings  and  to  check  them carefully.  In this way, when results for
different systems are  compared,  the  reader  can  get  a  feeling  how  much
performance  difference is due to compiler optimization and how much is due to
hardware speed.
6.  Acknowledgements
The C version 2.1 of Dhrystone has been developed  in  cooperation  with  Rick
Richardson  (Tinton  Falls,  NJ), it incorporates many ideas from the "Version
1.1" distributed previously by him over the UNIX network Usenet.  Through  his
activity with Usenet, Rick Richardson has made a very valuable contribution to
the dissemination of the benchmark.  I also thank  Chaim  Benedelac  (National
Semiconductor),  David Ditzel (SUN), Earl Killian and John Mashey (MIPS), Alan
Smith and Rafael  Saavedra-Barrera  (UC  at  Berkeley)  for  their  help  with
comments on earlier versions of the benchmark.
7.  Bibliography
[1]
   Reinhold P. Weicker: Dhrystone: A Synthetic Systems Programming Benchmark.
   Communications of the ACM 27, 10 (Oct. 1984), 1013-1030
[2]
   Rick Richardson: Dhrystone 1.1 Benchmark Summary (and Program Text)
   Informal Distribution via "Usenet", Last Version Known  to  me:  Sept.  21,
   1987
[3]
   Brian W. Kernighan and Dennis M. Ritchie:  The C Programming Language.
   Prentice-Hall, Englewood Cliffs (NJ) 1978