Document Title: config.txt Subject: SPEC CPU2000 Config files Last updated: 11-Oct-2000 9:00am jh (To check for possible updates to this document, please see http://www.spec.org/osg/cpu2000 ) ------------------------------------------------------------------------ Overview -------- I. Introduction II. Config file options for runspec III. Config file options for specmake IV. Config file options for the shell V. Config file options for the reader VI. Files output during a build VII. Troubleshooting Detailed Contents ----------------- I. Introduction A. What is a config file? (Background: benchmark philosophy.) B. What does a config file affect? 1. runspec 2. specmake 3. the shell 4. the reader of the results C. Config file structure 1. Comments and whitespace 2. Header section 3. Named sections a. Precedence for the benchmark specifier b. Precedence for the tuning specifier c. Precedence for the extension specifier d. Combining specifier types e. Precedence among section types 4. MD5 section 5. Variable Substitution a. By runspec (1) Example: cleaning files before a training run (2) Example: submitting to multiple nodes, Compaq Tru64 Unix b. By the shell (1) Protecting shell variables (2) Example: submitting to multiple nodes, SGI Origin c. By specmake d. Limitations on variable substitution 6. Shell-like "here documents" and continued lines 7. Included files II. Config file options for runspec A. Options for runspec that can also be used on the command line action deletework ext ignore_errors iterations mach make_no_clobber max_active_compares output_format reportable rate rebuild runlist setprocgroup size table tune unbuffer users verbose B. Options for runspec that can only be used in a config file backup_config basepeak check_md5 command_add_redirect difflines env_vars expand_notes feedback ignore_sigint line_width locking log_line_width make makeflags mean_anyway minimize_rundirs minimize_builddirs srcalt submit teeout use_submit_for_speed III. Config file options for specmake CC, CXX, FC, F77 CLD, CXXLD, FLD, F77LD ONESTEP OPTIMIZE, COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE, F77OPTIMIZE PORTABILITY, CPORTABILITY, CXXPORTABILITY, FPORTABILITY... RM_SOURCES PASSn_CFLAGS, PASSn_CXXFLAGS, PASSn_FFLAGS, PASSn_F77FLAGS IV. Config file options for the shell V. Config file options for the reader A. Pre-defined fields company_name hw_avail hw_cpu hw_cpu_mhz hw_disk hw_fpu hw_memory hw_model hw_ncpu hw_ncpuorder hw_ocache hw_other hw_parallel hw_pcache hw_scache hw_tcache hw_vendor license_num machine_name prepared_by sw_avail sw_compiler sw_file sw_os sw_state test_date tester_name B. Field scoping and continuation C. Free form notes VI. Files output during a build A. Automatic backup of config files B. The log file and verbosity levels C. Log file example: Feedback-directed optimization. D. Help, I've got too many logs! E. Finding the build directory F. Files in the build directory G. For more information VII. Troubleshooting I. Introduction --------------- This document assumes that you have already read "runspec.txt". There, you learned about the primary user interface for running SPEC CPU2000; with this document, attention turns more toward how things work inside. A. What is a config file? (Background: benchmark philosophy.) A config file contains: * the instructions for building the benchmarks * the instructions for running the benchmarks * the description of the system under test * the key to result reproducibility * the repository for all information unique to a vendor/system * the guts, the real controls, the gold, the Good Stuff * the place where the benchmark philosophy hits the road (Readers who just want to get on with the technical description should skip the remainder of this section; those who are interested in benchmark design philosophy should continue reading.) A key decision that must be made by designers of a benchmark suite is whether to allow the benchmark source code to be changed when the suite is used. If source code changes are allowed: + The benchmark can be adapted to the system under test. + Portability may be easier. - But it may be hard to compare results between systems, unless some formal audit is done to ensure that comparable work is done. If source code changes are not allowed: + Results may be easier to compare. - It may take more time and effort to develop the benchmark, because portability will have to be built in ahead of time. - Portability may be hard to achieve, at least for real applications. (Simple loops of 15 lines can port with little effort, and such benchmarks have their uses. But real applications are more complex.) SPEC has chosen not to allow source code changes for the CPU2000 suite, except under very limited circumstances described below. By restricting source code changes, we separate the activity of porting benchmarks (which has a goal of being performance neutral), from the activity of using the benchmarks (where the goal is not neutrality, it's Get The Best Score You Can.) Prior to the first use of CPU2000, SPEC therefore invested substantial effort to port the suite to as many platforms as practical. Testing was done on 7 different hardware architectures, 11 versions of Unix (including 4 versions of Linux) and 2 versions of NT. Are source code changes ever allowed? Normally, no. But if you discover a reason why you believe such a change is required, SPEC wants to hear about it, and will consider such requests for a future revision of the suite. SPEC will normally not approve publication of CPU2000 results using modified source code, unless such modifications are unavoidable for the target environment, are submitted to SPEC, are made available to all users of the suite, and are formally approved by a vote. So, if source code changes are not allowed, but the benchmarks must be compiled in a wide variety of environments, can the users at least write their own Makefiles, and select "-D" options to select different environments? The answer to these two questions are "no", and "yes", respectively: * No, you can't write your own Makefiles. * But yes, you can select portability options (such as "-D"). You do this in the config file, which contains a centralized collection of all the portability options and optimization options for all the benchmarks in a CPU2000 suite. The SPEC tools then automatically generate the Makefiles for you. The config file contains places where you can specify the characteristics of both your compile time and run time environments. It allows the advanced user to perform detailed manipulation of Makefile options, but retains all the changes in one place so that they can be examined and reproduced. The config file is one of the key ingredients in making results reproducible. For example, if a customer would like to run the CPU2000 suite on her own SuperHero Model 4 and discover how close results are in her environment to the environment used when the vendor published a CPU2000 result, she should be able to do that using only 3 ingredients: - the SPEC CPU2000 CD ordered from SPEC - the software and hardware as specified in the full disclosure when the vendor submitted the original results - the config file from the vendor's submission I. Introduction (continued) B. What does a config file affect? A config file contains directives that are addressed to four different consumers: runspec, specmake, the shell, and the reader of the results: 1. runspec Various aspects of the operation of runspec can be set within the config file. For example, if michael.cfg includes the lines: output_format = asc,ps tune = base reportable = 1 runlist = fp then the defaults for the runspec command would change as specified. A user who types either of the following two commands would get precisely the same effect: runspec --config=michael runspec --config=michael --output=asc,ps --tune=base --reportable fp 2. specmake The tool 'specmake' is simply gnu make renamed to avoid any possible conflicts with other versions of make that may be on your system. Config file lines such as: CC = cc CPORTABILITY = -DSPEC_CPU2000_LP64 OPTIMIZE = -O4 are written to the Makefile set that is ultimately used to build the benchmark, and these lines are interpreted by specmake. 3. The shell Certain commands are interpreted by the shell, for example: fdo_pre0 = mkdir /tmp/ahmad; rm -f /tmp/ahmad/* Runspec passes the above command to the shell prior to running a training run for feedback directed optimization, and the shell actually carries out the requested commands. It is therefore important to peruse a config file you are given before using it. 4. The reader of the results A SPEC CPU2000 result, when submitted to http://www.spec.org, is expected to contain all the information needed so that readers can understand exactly what was tested. Config file lines such as these are addressed to that reader: test_date = Nov-1999 hw_avail = Apr-1999 sw_avail = May-1999 notes015 = Note: Feedback directed optimization was not used In addition, the config file itself is available to the reader at http://www.spec.org. The config file is presented in its entirety, with one exception described below under "Comments and whitespace". The reason that the config file is made available is because it is so important to reproducing results, as described in the Introduction. The config file is saved on every run, as a compressed portion of the rawfile. I. Introduction (continued) C. Config file structure 1. Comments and whitespace Comment lines begin with a "#", and can be placed anywhere in a config file. When the config file is saved (as an encoded portion of the rawfile), the comments are included. But if a comment line begins with "#>", it will not be saved in the rawfile. Thus you could use "#" for most of your comments, and use "#>" for proprietary information, such as: #> I didn't use the C++ beta test because of Bob's big back-end bug. Blank lines can be placed anywhere in a config file. Spaces within a line are almost always ignored. Of course, you wouldn't want to spell OPTIMIZE as OPT I MIZE, but you are perfectly welcome to do either of the following: OPTIMIZE=-O2 OPTIMIZE = -02 The one place where spaces are considered significant is in notes, where the tools assume you are trying to line up your comments in the full disclosure reports. 2. Header section A config file contains the following: - A header section - An arbitrary number of named sections, delimited by section markers (described below). - An MD5 section Most attempts to address runspec itself must be done in the header section. For example, if you want to set "reportable=1", you must do so before any occurrences of section markers. The next several pages are devoted to sections that you name; the MD5 section is explained after that. I. Introduction (continued) C. Config file structure (continued) 3. Named Sections A "section marker" is a four-part string of the form: benchmark=tuning=extension=machine: These are referred to below as the 4 "section specifiers". The allowed values for the section specifiers are: benchmark: default int fp Any individual benchmark, such as 252.eon tuning: default base peak extension: default any arbitrary string, such as "cloyce-genius" machine: default (As of the date of this documentation, this feature is only partly implemented. Leave it at default unless you feel particularly courageous.) Trailing default sections may be omitted. Thus all of the following are equivalent: 252.eon=base=default=default: 252.eon=base=default: 252.eon=base: Section markers can be entered in any order. Section markers can be repeated; material from identical section markers will automatically be consolidated. That is, you are welcome to start one section, start a different one, then go back and add more material to the first section. But please note that since there is no marker for the header section, you cannot go back to it. I. Introduction (continued) C. Config file structure (continued) 3. Named sections (continued) a. Precedence for the benchmark specifier By constructing section markers, you specify how you would like your options applied, with powerful defaulting and over-riding capabilities. Let's examine these capabilities by way of examples. We start with a simple config file: % cat tmp.cfg runlist = swim size = test iterations = 1 tune = base output_format = asc teeout = 1 default=default=default=default: OPTIMIZE = -O2 % runspec --config=tmp | grep swim.f f90 -c -o swim.o -O2 swim.f % The config file above is designed for quick, simple testing: it runs only one benchmark, namely 171.swim, using the smallest (test) workload, runs it only once, uses only base tuning, outputs only the text (ASCII) format report, and displays the build commands to the screen. To use it, we issue a runspec command, and pipe the output to grep to search for the actual generated compile command. (Alternatively, on NT, we could use findstr on the generated log file). And, indeed, the tuning applied was the expected -O2. Now consider this example, where a section marker is added that has the first specifier set to "fp", for the floating point suite: % cat tmp.cfg runlist = swim size = test iterations = 1 tune = base output_format = asc teeout = 1 default=default=default=default: OPTIMIZE = -O2 fp=default=default=default: OPTIMIZE = -O3 % runspec --config=tmp | grep swim.f f90 -c -o swim.o -O3 swim.f % The second OPTIMIZE command is used above because the reference to the floating point suite is considered to be more specific than the overall default. Furthermore, we can add a specifier that mentions swim by name: % cat tmp.cfg runlist = swim size = test iterations = 1 tune = base output_format = asc teeout = 1 default=default=default=default: OPTIMIZE = -O2 fp=default=default=default: OPTIMIZE = -O3 171.swim=default=default=default: OPTIMIZE = -O4 % runspec --config=tmp | grep swim.f f90 -c -o swim.o -O4 swim.f % The third OPTIMIZE command wins above, because it is included in the section that is considered to be the most specific. But what if we had said these in a different order? % cat tmp.cfg runlist = swim size = test iterations = 1 tune = base output_format = asc teeout = 1 171.swim=default=default=default: OPTIMIZE = -O4 default=default=default=default: OPTIMIZE = -O2 fp=default=default=default: OPTIMIZE = -O3 % runspec --config=tmp | grep swim.f f90 -c -o swim.o -O4 swim.f % Notice above that the order of entry is not significant; it's the order of precedence from least specific to most specific. Note: when a specifier is listed more than once at the same descriptive level, the last instance of the specifier is used. Consider this case: 171.swim=default=default=default: OPTIMIZE = -O4 171.swim=default=default=default: OPTIMIZE = -O3 The ending value of OPTIMIZE for 171.swim is '-O3', not '-O4'. I. Introduction (continued) C. Config file structure (continued) 3. Named sections (continued) b. Precedence for the tuning specifier The tuning specifier is the the second in the group of four, taking the value "default", "base", or "peak". Here is an example of its use: % cat tmp.cfg runlist = swim size = test iterations = 1 tune = base,peak output_format = asc teeout = 1 default=default=default=default: FC = f90 F77 = f77 default=base=default=default: FC = kf90 default=peak=default=default: F77 = kf77 % runspec --config=tmp | grep swim.f | grep swim.o kf90 -c -o swim.o swim.f kf77 -c -o swim.o swim.f % In the above example, we compile swim twice: once for base tuning, and once for peak. Notice that in both cases the compilers defined by the more specific section markers have been used, namely kf90 and kf77, rather than the f90 and f77 from default=default=default=default. (The alert reader may ask here "Why does FC apply to base and F77 apply to peak?" The reason for this is that in base, the CPU2000 Run Rules allow only one Fortran compiler, which must be used for both the benchmarks that use the older Fortran-77 features, and for the benchmarks that use the newer Fortran-90 features. But for peak tuning your definition of FC is used for source files "*.f90", and your definition of F77 is used for source files ".f".) I. Introduction (continued) C. Config file structure (continued) 3. Named sections (continued) c. Precedence for the extension specifier Now let's examine the third section specifier, extension: % cat tmp.cfg runlist = swim size = test iterations = 1 tune = base output_format = asc teeout = 1 default=default=default=default: LIBS = -lm default=default=ev6=default: LIBS = -lm_ev6 % runspec --config=tmp | grep swim.o f90 -c -o swim.o swim.f f90 swim.o -lm -o swim % runspec --config=tmp --extension=ev6 | grep swim.o f90 -c -o swim.o swim.f f90 swim.o -lm_ev6 -o swim % % cd $SPEC/benchspec/CFP2000/171.swim/exe % ls -lt | head -3 total 3400 -rwxr-xr-x 1 john users 65536 Dec 10 02:47 swim_base.ev6 -rwxr-xr-x 1 john users 49152 Dec 10 02:47 swim_base.none % Notice above that two different versions of swim were built from the same config file, and both executables are present in the exe directory for swim. I. Introduction (continued) C. Config file structure (continued) 3. Named sections (continued) d. Combining specifier types What if more than one section applies to a particular benchmark? Consider this example: % cat tmp.cfg runlist = swim size = test iterations = 1 tune = peak output_format = asc teeout = 1 default=default=default=default: OPTIMIZE = -O2 F77 = f77 LIBS = -lm 171.swim=default=default=default: OPTIMIZE = -O4 default=peak=default=default: F77 = kf77 default=default=ev6=default: LIBS = -lm_ev6 % runspec --config=tmp --extension=ev6 | grep swim.o kf77 -c -o swim.o -O4 swim.f kf77 -O4 swim.o -lm_ev6 -o swim % Notice above that all three sections applied: the section specifier for 171.swim, the specifier for peak tuning, and the specifier for extension ev6. I. Introduction (continued) C. Config file structure (continued) 3. Named sections (continued) e. Precedence among section types If sections contradict each other, the order of precedence is: highest benchmark suite tuning lowest extension And this order can be demonstrated as follows: % cat tmp.cfg size = test iterations = 1 output_format = asc teeout = 1 default=default=default=default: OPTIMIZE = -O0 fp=default=default=default: OPTIMIZE = -O1 171.swim=default=default=default: OPTIMIZE = -O3 default=peak=default=default: OPTIMIZE = -O4 default=default=ev6=default: OPTIMIZE = -O5 % runspec --conf=tmp swim | grep swim.f [1] f90 -c -o swim.o -O3 swim.f % runspec --conf=tmp --tune=peak swim | grep swim.f [2] f77 -c -o swim.o -O3 swim.f % runspec --conf=tmp --extension=ev6 swim | grep swim.f [3] f90 -c -o swim.o -O3 swim.f % % runspec --conf=tmp --tune=base mgrid | grep mgrid.f [4] f90 -c -o mgrid.o -O1 mgrid.f % runspec --conf=tmp --tune=peak mgrid | grep mgrid.f [5] f77 -c -o mgrid.o -O1 mgrid.f % runspec --conf=tmp --extension=ev6 mgrid | grep mgrid.f [6] f90 -c -o mgrid.o -O1 mgrid.f % % runspec --conf=tmp --tune=base gzip | grep gzip.c [7] cc -c -o gzip.o -O0 gzip.c % runspec --conf=tmp --tune=peak gzip | grep gzip.c [8] cc -c -o gzip.o -O4 gzip.c % runspec --conf=tmp --extension=ev6 gzip | grep gzip.c [9] cc -c -o gzip.o -O5 gzip.c % runspec --conf=tmp --tune=peak --extension=ev6 gzip | grep gzip.c [10] cc -c -o gzip.o -O4 gzip.c Notice above that the named benchmark always wins: lines [1], [2], and [3]. If there is no section specifier that names a benchmark, but there is a section specifier that names a suite, then the suite wins: lines [4], [5], and [6]. If there are no applicable benchmark or suite specifiers, then tuning or extension can be applied: lines [8] and [9]. But if both tuning and extension are applied, tuning wins [10]. I. Introduction (continued) C. Config file structure (continued) 4. MD5 The final section of your config file is generated automatically by the tools at compile time, and looks something like this: __MD5__ 168.wupwise=peak=nov14a=default: # Last updated Sun Nov 14 04:49:15 1999 optmd5=6cfebb629cf395d958755f68a6c9e05b exemd5=3d51c75d1c97918bf212c4fb47a30003 183.equake=peak=nov14a=default: # Last updated Sun Nov 14 04:49:22 1999 optmd5=f3f0d2022f2be4a9530c000b1e883008 exemd5=923a7bfd6f68ccf0d6e49261fa1c2030 The "MD5" is a checksum that ensures that the binaries referenced in the config file are in fact built using the options described therein. For example, if you edit the config file to change the optimization level for 255.vortex, the next time the file is used the tools will notice the change and will recompile vortex. You can optionally disable this behavior, but doing so is strongly discouraged. See the sarcastic remarks in the description of "check_md5", below. If you would like to see what portions of your config file are used in computing the MD5 hash, runspec with --debug=30 or higher, and examine the log file. I. Introduction (continued) C. Config file structure (continued) 5. Variable Substitution You can do variable substitution using your config file. But, as described in the introduction, a config file can affect runspec itself, specmake, and the shell. Therefore, effective use of variable substitution requires you to be aware of which software is doing the substitution: - If runspec itself does the substitution, it uses perl variable interpolation. The items to be substituted usually look something like this: $hw_avail. - If runspec generates an external command which is handed off to your shell (or command interpreter), the variable will be interpreted according to the rules of your shell. Such a variable might look like this: \$SPEC. - If the variable is handed off to specmake, it is interpreted by the usual rules of gnu make. Such variables might look like this: $(FOPTIMIZE). I. Introduction (continued) C. Config file structure (continued) 5. Variable Substitution (continued) a. By runspec Substitution by runspec itself uses perl variable interpolation. Only perl scalars (denoted by a leading $) can be interpolated. For example, notes001 below uses the log file number (generated by the tools) and the hardware availability date (which was set directly): % cat tmp.cfg size = test iterations = 1 output_format = asc teeout = 1 expand_notes = 1 runlist = swim tune = base hw_avail = May-2000 notes001 = This run is from log.$lognum with hw_avail $hw_avail % runspec -c tmp | grep asc Identifying output formats...asc...config...html...pdf...ps...raw... format: ASCII -> /greg/result/CFP2000.101.asc % grep with /greg/result/CFP2000.101.asc This run is from log.101 with hw_avail May-2000 As another example, let's say you want to go for minimal performance. You might want to do this with the 'nice' command. You can say: submit=nice 20 '$command' and the $command gets expanded to whatever would normally be executed but with 'nice 20' stuck in front of it. If you'd like a complete list of the variables that you can use in your commands (relative to the config file you're using), set runspec's verbosity to 80 or higher (-v 80) and either do a run that causes a command substitution to happen, or run with expand_notes set to 1. To put text immediately after a variable, you need to make it possible for the parser to see the variable that you want, by using braces: % tail -2 tmp.cfg notes001 =You have done ${lognum}x runs tonight, aren't you tired yet? % runspec -c tmp | grep asc Identifying output formats...asc...config...html...pdf...ps...raw... format: ASCII -> /john/result/CFP2000.103.asc % grep done /john/result/CFP2000.103.asc You have done 103x runs tonight, aren't you tired yet? (1) Example: cleaning files before a training run Perhaps a more useful example is this one, which directs the shell to clean files related to the current executable in the temporary directory, before a training run for feedback directed optimization: fdo_pre0 = mkdir /tmp/pb; rm -f /tmp/pb/${baseexe}* NOTICE in this example that although the commands are carried out by the shell, the variable substitution is done by runspec. I. Introduction (continued) C. Config file structure (continued) 5. Variable Substitution (continued) a. By runspec (continued) (2) Example: submitting to multiple nodes, Compaq Tru64 Unix The following lines submit to multiple nodes on a Compaq AlphaServer SC Series Supercomputer running Tru64 Unix: submit= echo "$command" > dobmk; prun -n 1 sh dobmk command_add_redirect=1 In this example, the command that actually runs the benchmark is written to a small file, "dobmk", which is then submitted to a remote node selected by "prun". (The parallel run command, prun, can execute multiple copies of a process, but in this case we have requested just one copy by saying "-n 1". The SPEC tools will create as many copies as required.) The "command_add_redirect" is crucial. What happens without it? % head -1 $SPEC/config/tmp1.cfg submit= echo "$command" > dobmk; prun -n 1 sh dobmk % runspec --config=tmp1 --size=test -n 1 --rate --users=1 swim ... % cat $SPEC/benchspec/CFP2000/171.swim/run/00000006/dobmk ../00000006/swim_base.none Now let's use command_add_redirect, and see how dobmk changes: % diff $SPEC/config/tmp1.cfg $SPEC/config/tmp2.cfg 1a2 > command_add_redirect=1 % runspec --config=tmp2 --size=test -n 1 --rate --users=1 swim ... % cat $SPEC/benchspec/CFP2000/171.swim/run/00000006/dobmk ../00000006/swim_base.none < swim.in > swim.out 2> swim.err Notice that with command_add_redirect=1, the substitution for $command includes both the name of the executable and the file assignments for standard in, standard out, and standard error. This is needed because otherwise the files would not be connected to swim on the remote node. That is, the former generates [*]: echo "swim_base.none" > dobmk; prun -n 1 sh dobmk < swim.in > swim.out 2> swim.err And the latter generates [*]: echo "swim_base.none < swim.in > swim.out 2> swim.err" > dobmk; prun -n 1 sh dobmk [*] The picky reader may wish to know that the examples were editted for readability: a line wrap was added, and the directory string "../00000006/" was omitted. The advanced reader may wonder how the above lines were discovered: for the former, we found out what runspec would generate by going to the run directory and typing "specinvoke -n", where -n means dry run; in the latter, we typed "specinvoke -nr", where -r means that $command already has device redirection. For more information on specinvoke, see $SPEC/docs/utility.txt. I. Introduction (continued) C. Config file structure (continued) 5. Variable Substitution (continued) b. By the shell (1) Protecting shell variables Because perl variables look a lot like shell variables, you need to specially protect shell variables if you want to prevent perl from trying to interpret them. Notice what happens with the protected and unprotected versions: % cat tmp.cfg size = test iterations = 1 output_format = asc teeout = 1 expand_notes = 1 runlist = swim tune = base,peak use_submit_for_speed = 1 default=peak=default=default: submit = echo "home=$HOME; spec=$SPEC;" >/tmp/chan; $command default=base=default=default: submit = echo "home=\$HOME; spec=\$SPEC;" > /tmp/nui; $command % runspec --config=tmp > /dev/null % cat /tmp/chan home=; spec=; % cat /tmp/nui home=/usr/users/chris; spec=/cpu2000; % Please note that, by default, 'submit' is only applied to rate runs. In this example, we used it for a speed run as well, by setting use_submit_for_speed = 1 in the configuration file. I. Introduction (continued) C. Config file structure (continued) 5. Variable Substitution (continued) b. By the shell (continued) (2) Example: submitting to multiple nodes, SGI Origin Here is a more complex example which uses substitution by both runspec and by the shell (line wraps added for readability): submit= let "MYNUM=$SPECUSERNUM" ; let "NODE=\$MYNUM/2"; export NODE=/hw/nodenum/\$NODE; let "CPU=2*((\$MYNUM+1)/2)-\$MYNUM "; export CPU; /usr/sbin/dplace -place \$SPEC/submit.pf -mustrun $command Runspec substitutes the current user number for $SPECUSERNUM, and then passes the above command to the shell which does the substitutions for CPU and NODE. This example originated on an SGI Origin system, where there are two CPUs per node. Suppose that runspec is about to submit the copy for user number 17. In that case: submit= let "MYNUM=$SPECUSERNUM" ; # i.e. 17 let "NODE=\$MYNUM/2"; # So, NODE=8 export NODE=/hw/nodenum/\$NODE; # Now NODE=/hw/nodenum/8 let "CPU=2*((\$MYNUM+1)/2)-\$MYNUM "; # and CPU=1 export CPU; /usr/sbin/dplace # So we execute dplace -place \$SPEC/submit.pf # using $SPEC/submit.pf -mustrun $command # and the expected command The desired $command is run under the control of submit.pf, with $NODE=/hw/nodenum/8 and $CPU=1. Here are the contents of the placement file, submit.pf: memories 1 in topology physical near $NODE threads 1 run thread 0 on memory 0 using cpu $CPU Two important notes about the above submit command: 1) $SPECUSERNUM must be spelled exactly as it is in the examples above. It is a limitation of the tools that saying things like '${SPECUSERNUM}' just won't work. 2) The above example was constructed using the first release of the SPEC CPU2000 suite. It should still work with the V1.1 update, but could probably be simplified. In V1.0, only the first occurrence of $SPECUSERNUM was substituted. That's why the example above immediately assigns the result to MYNUM, which can then be used repeatedly. I. Introduction (continued) C. Config file structure (continued) 5. Variable Substitution (continued) c. By specmake For an example of variable substitution handled by specmake, see $SPEC/docs/example-advanced.cfg %SPEC%\docs.nt\example-advanced.cfg Search that file for LIBS, and note the long comment which provides a walk-through of a complex substitution handled by specmake. d. Limitations on variable substitution Once runspec hands control over to specmake or to the shell, the results of further substitution are invisible to runspec. For this reason, you can't say: wrong: MYDIR = /usr/paul/compilers F90 = $(MYDIR)/f90 notes001 = compiler: $(F90) 6. Shell-like "here documents" and continued lines Shell-style "here documents" are supported for setting variables to multi-line values. Continued lines (with \) are also supported: $ cat tmp2.cfg expand_notes=1 foo = < /cpu2000/result/CFP2000.024.asc $ grep + ../result/*24.asc This + is a + test + and + so + is + this+ Note: although continued lines are supported, they are rarely used. The more common method of continuation is by appending a number to a field, as described in the section "Field scoping and continuation". I. Introduction (continued) C. Config file structure (continued) 7. Included files It is possible to include another file in your config file. A typical use for this feature might be to keep all the software information in the main config file, but to include the hardware information about the current System Under Test (SUT) in another file. For example: % cat tmp.cfg sw_compiler = GoFast C/C++ V4.2 sw_avail = Mar-2000 include: SUT.inc default=default=default=default: OPTIMIZE = -O4 % cat SUT.inc hw_model = SuperHero IV hw_avail = Feb-2000 % runspec --config=tmp --iterations=1 --size=test swim After the above command is completed, we end up with a report that mentions both hardware and software dates: ... Hardware availability: Feb-2000 ... Software availability: Mar-2000 II. Config file options for runspec ----------------------------------- This section documents options that control the operation of runspec itself. A. Options for runspec that can also be used on the command line The following items can be specified in a config file, and have the same meaning as if they are specified on the runspec command line. Please see runspec.txt for details. If an item is specified in both places, the command line wins. All of these should be specified in your config file header section, unless the description states that the item can be applied to individual benchmarks. option default Meaning ----------------- --------- ------------------------------------------- action validate What to do. deletework 0 If set to 1, always delete existing benchmark working directories. An extra-careful person might want to set this to ensure no unwanted leftovers from previous benchmark runs, but the tools are already trying to enforce that property. ext none Extension for executables created ignore_errors 0 Ignore certain errors. Very useful when debugging a new compiler and new set of options. iterations 3 Number of iterations to run mach default Default machine id make_no_clobber 0 Don't delete directory when building executables. This option should only be used for troubleshooting a problematic compile. It is against the run rules to use it when building binaries for an actual submission. max_active_compares <# users> Max number of parallel compares. Useful when doing large SPECrate runs on a system with lots of CPUs. Do not set a value larger than the number of users. output_format all Format for reports. Valid options are asc (ASCII text), html, pdf, and ps. You might prefer to set this to "asc" if you're going to be doing lots of runs, and only create the pretty reports at the end of the series. See runspec --output_format and --rawformat. reportable 0 Strictly follow reporting rules. You must set reportable, in order to generate a valid run suitable for submission to SPEC. rate 0 Rate vs Speed (1=rate, 0=speed) rebuild 0 Rebuild binaries even if they exist runlist none What benchmarks to run setprocgroup 1 Set the process group. On Unix-like systems, improves the chances that ^C gets the whole run, not just one of the children size ref Size of input set. If you are in the early stages of testing a new compiler or new set of options, you might set this to test or train. table 1 In ASCII reports, include information about each execution of the benchmark. tune base default tuning level. In a reportable run, must be one of "all" or "base". unbuffer 0 Unbuffer STDOUT. For CPU95, there were occasional complaints about redundant output when a child process would flush its buffer. If similar problems occur for CPU2000, try setting this to 1. users 1 Number of users (see runspec --users). This option can also be used for specific benchmarks - e.g. you could decide to run 64 copies of all benchmarks except gcc, which would run only 63. For base, the number of copies must be the same for all benchmarks, but for peak it is allowed to vary. verbose 5 Verbosity level. Select level 1 through 99 to control how much debugging info runspec prints out. For more information, see the section on the log file, elsewhere in this document. II. Config file options for runspec (continued) B. Options for runspec that can only be used in a config file The following options control the operation of runspec, but are not specified on the command line. Instead, they must be specified in the config file. All of these should be specified in your config file header section, unless the description states that the item can be applied to individual benchmarks. option default Meaning ----------------- --------- ------------------------------------------- backup_config 1 When updating the MD5 hashes in the config file, make a backup copy first. Highly recommended to defend against full-file-system errors, system crashes, or other unfortunate events. basepeak 0 Use base binary and/or base result for peak. If applied to the whole suite (in the header section), then only base is run, and its results are reported for both the base and peak metrics. If applied to a single benchmark, the same binary will be used for both base and peak runs, and the lower of the two medians will be reported for both. check_md5 1 Runspec uses MD5 hashes to verify that executables match the config file that invokes them, and if they do not, runspec forces a recompile. You can turn that feature off by setting check_md5=0. WARNING: If you turn this feature off, you effectively say that you are willing to run a benchmark even if you don't know what you did or how you did it -- that is, you lack information as to how it was built! Since SPEC requires that you disclose how you built it, such a run would not be submittable to SPEC. command_add_redirect 0 If set, let the shell do I/O redirection. Otherwise, specinvoke will do it itself. difflines 10 Number of lines of differences to print when comparing results. env_vars 0 Allow environment to be overridden by ENV_* For example: env_vars=1 164.gzip=default=default=default: ENV_FOO=367 will cause the tools to spawn gzip (or anything related, like monitor_prebench) with FOO=367 expand_notes 0 If set, will expand variables in notes. This capability is limited because notes are NOT processed by specmake, so you cannot do repeated substitutions. feedback 1 Normally, feedback is controlled by the presence of one or more PASSn options (see the documentation of make variables). An additional control is provided by this config file option, which can be used to selectively turn feedback off for individual benchmarks. Note: in a base run, all benchmarks in a given language must use the same settings for feedback. ignore_sigint 0 Ignore SIGINT. If this is set, runspec will attempt to ignore you when you press ^C. (It is not clear why one might want to set this feature.) line_width 0 line wrap width for screen locking 1 Try to lock files log_line_width 0 line wrap width for logfiles. If your editor complains about lines being too long when you look at logfiles, try setting this to some reasonable value, such as 80 or 132. make specmake Name of make executable. Note that the run rules require use of specmake for reportable results. makeflags '' Extra flags for make (such as -j). Use only if you are familiar with gnu make. mean_anyway 0 Calculate mean even if invalid. DANGER this will write a mean to all reports even if no valid mean can be computed (e.g. half the benchmarks failed!) DANGER minimize_rundirs 0 Try to keep working disk size down. Cannot be used in a reportable run. minimize_builddirs 0 Try to keep working disk size down during builds srcalt '' Name of subdirectory under /src/src.alt/ from which to draw approved source code modifications. This should be set only where required, on a per-benchmark basis. Any use of this feature must be mentioned in the full disclosure notes. submit undef Commands used to submit jobs; typically used for large rate runs. See the section on variable substitution to discover how to make this feature useful. teeout 0 Run output [from build] through tee so you can see it on the screen use_submit_for_speed 0 If set, use submit commands for speed runs as well as rate runs. Handy for running the benchmarks on a simulator, etc. III. Config file options for specmake ------------------------------------- For a complete list of options that are used by specmake, please see $SPEC/docs/makevars.txt and notice which variables are documented as OK to mention in a config file. Here are the commonly used variables: CC How to invoke your C Compiler CXX How to invoke your C++ Compiler FC How to invoke Fortran (the one that handles both .f and .f90) F77 How to invoke your Fortran-77 compiler (for .f files only) CLD How to invoke the Linker when compiling C programs CXXLD How to invoke the Linker when compiling C++ programs FLD How to invoke the Linker when compiling Fortran programs F77LD How to invoke the Linker when compiling Fortran-77 programs ONESTEP If set, build from sources directly to final binary. See the discussion in rule 2.2.6.13 of $SPEC/docs/runrules.txt or %SPEC%\docs.nt\runrules.txt OPTIMIZE Optimization flags to be applied for all compilers COPTIMIZE Optimization flags to be applied when using your C compiler CXXOPTIMIZE Ditto, for C++ FOPTIMIZE Ditto, for Fortran F77OPTIMIZE Ditto, for F77 PORTABILITY Portability flags to be applied no matter what the compiler CPORTABILITY Portability flags to be applied when using your C compiler CXXPORTABILITY Ditto, for C++ FPORTABILITY Ditto, for Fortran F77PORTABILITY Ditto, for Fortran-77 RM_SOURCES Remove a source file. Should only be used for library substitutions that comply with run rule 2.1.2 PASSn_CFLAGS Flags for pass "n" C compilation when doing profile- directed feedback. Typically n is either 1 or 2, for the compile done before the training run and the compile done after the training run. Search for the word "feedback" in $SPEC/docs/runrules.txt for more info; especially rule 2.2.3. See the feedback examples in example-medium.cfg and example-advanced.cfg from $SPEC/docs/ or %SPEC%\docs.nt\ . PASSn_CXXFLAGS Ditto, for C++ PASSn_FFLAGS Ditto, for Fortran PASSn_F77FLAGS Ditto, for Fortran-77 Note that you can also make up your own variable names, which specmake will use (and perform substitution on). For an example of this feature, see $SPEC/docs/example-advanced.cfg. IV. Config file options for the shell ------------------------------------- The following config file options will cause their contents to be executed by the shell (or the Windows/NT command interpreter): fdo_pre0 commands to be executed before starting a feedback directed compilation series fdo_preN commands to be executed before pass N fdo_make_cleanN commands to be executed for cleanup at pass N fdo_pre_makeN commands to be done prior to Nth compile fdo_make_passN commands to actually do the Nth compile fdo_post_makeN commands to be done after the Nth compile fdo_runN commands to be used for Nth training run fdo_postN commands to be done at the end of pass N submit commands to be used for distributing jobs across a multiprocessor system. See the detailed example in the section on "Variable Substitution", above. For an example of one of the fdo_ options, see the "Log file example" later in this document. V. Config file options for the reader ------------------------------------- Whether or not you submit your result to SPEC, you should fully disclose how you achieved the result. If it requires the installation of the GoFastLinker, you should say so. By setting the appropriate fields in the config file, you can cause information about the GoFastLinker to appear in all reports. A. Pre-defined fields Here are the pre-defined fields that you can set: company_name The company performing the tests. Will not be printed in reports unless it differs from the field hw_vendor. hw_avail Date hardware first shipped. If more than one date applies, use the LATEST one. hw_cpu CPU type hw_cpu_mhz Speed of the CPUs, in MHz hw_disk Disk subsystem hw_fpu Floating point unit hw_memory Size of main memory hw_model Model name hw_ncpu Number of CPUs configured. Note that if your system has the ability to turn CPUs off, for example through a firmware setting, then it is acceptable to report "1" here if only 1 CPU was enabled on an SMP system. But beware -- you need to ensure that your method is effective and that you are not silently getting help from the allegedly turned-off CPUs. hw_ncpuorder Valid number of CPUs orderable for this model. For example, "2 to 16". hw_ocache 4th level or other form of cache hw_other Any other performance-relevant hardware hw_parallel Were multiple CPUs employed by a parallelizing compiler? Note that a speed run that uses a parallelizing compiler causes a single instance of a benchmark to run using multiple CPUs; this is different from a rate run, which typically distributes N instances over N CPUs. hw_pcache 1st level (primary) cache hw_scache 2nd level cache hw_tcache 3rd level cache hw_vendor Name of manufacturer for hardware license_num Your SPEC license number machine_name Machine name: not currently used, leave blank prepared_by Is never output. If you wish, you could set this to your own name, so that the rawfile will be tagged with your name but not the formal reports. sw_avail Availability date for the software used. If more than one date, use the LATEST one. sw_compiler Name and version of compiler sw_file File system (nfs, ufs, etc) sw_os Operating system name and version sw_state Multi-user, single-user, default, etc test_date When you ran the tests tester_name Your employer. Printed in reports. V. Config file options for the reader (continued) B. Field scoping and continuation Note that these fields are scoped by section headers - that is, you can vary them according to the type of run that you are doing. You can also continue any of these fields to another line by appending a numeral to it. Here is an example of both these features: default=default=default=default: sw_compiler = Compaq C X6.2-259-449AT CC = cc -v int=default=default=default: sw_compiler2 = DIGITAL C++ V6.1-029-408B6 CXX = cxx -v fp=default=default=default: sw_compiler2 = Compaq Fortran V5.3 sw_compiler3 = KAP Fortran V4.2 FC = kf90 -v Notice in the above example that the information about the C compiler will be printed for both integer and floating point runs. The information about the C++ compiler will be printed only for integer runs; the information about Fortran compilers will be printed only for floating point runs. V. Config file options for the reader (continued) C. Free form notes In addition, you can write as many free-form notes as you wish. Start your notes with the characters "notes", and then add numbers and/or underscores. The notes will be sorted before being printed. For example: % cat tmp.cfg size = test iterations = 1 output_format = asc teeout = 1 runlist = swim tune = base notes01_1 = ++ how notes02 = ++ you? notes01_2 = ++ are notes01 = ++ Alex, notes000 = ++ hi default=base=default=default: % runspec --config=tmp > /nev/dull % ls -t ../result/*asc | head -1 ../result/CFP2000.111.asc % grep ++ ../result/CFP2000.111.asc ++ hi ++ Alex, ++ how ++ are ++ you? % You can also use notes to describe software or hardware information with more detail beyond the predefined fields. For an example of where this might be useful, see $SPEC/docs/example-medium.cfg and search for "patch". VI. Files output during a build -------------------------------- A. Automatic backup of config files It was mentioned above that the MD5 section of the config file is written automatically by the tools. Each time your config file is updated, a backup copy is made. Thus your config directory may soon come to look like this: % ls /home/jim/CPU2000/config/tmp.c* tmp.cfg tmp.cfg.19991210aq tmp.cfg.19991210j tmp.cfg.19991210 tmp.cfg.19991210ar tmp.cfg.19991210k tmp.cfg.19991210a tmp.cfg.19991210as tmp.cfg.19991210l tmp.cfg.19991210aa tmp.cfg.19991210at tmp.cfg.19991210m tmp.cfg.19991210ab tmp.cfg.19991210au tmp.cfg.19991210n tmp.cfg.19991210ac tmp.cfg.19991210av tmp.cfg.19991210o tmp.cfg.19991210ad tmp.cfg.19991210aw tmp.cfg.19991210p tmp.cfg.19991210ae tmp.cfg.19991210ax tmp.cfg.19991210q tmp.cfg.19991210af tmp.cfg.19991210ay tmp.cfg.19991210r tmp.cfg.19991210ag tmp.cfg.19991210az tmp.cfg.19991210s tmp.cfg.19991210ah tmp.cfg.19991210b tmp.cfg.19991210t tmp.cfg.19991210ai tmp.cfg.19991210ba tmp.cfg.19991210u tmp.cfg.19991210aj tmp.cfg.19991210c tmp.cfg.19991210v tmp.cfg.19991210ak tmp.cfg.19991210d tmp.cfg.19991210w tmp.cfg.19991210al tmp.cfg.19991210e tmp.cfg.19991210x tmp.cfg.19991210am tmp.cfg.19991210f tmp.cfg.19991210y tmp.cfg.19991210an tmp.cfg.19991210g tmp.cfg.19991210z tmp.cfg.19991210ao tmp.cfg.19991210h tmp.cfg.19991210ap tmp.cfg.19991210i If this feels like too much clutter, you can disable the backup mechanism, as described under "backup_config", below. Note that doing so may leave you with a risk of losing the config file in case of a filesystem overflow or system crash. A better idea may be to periodically remove the clutter, for example by typing: rm *.cfg.199912* VI. Files output during a build (continued) B. The log file and verbosity levels $SPEC/result (Unix) or %SPEC%\result (NT) contains reports and log files, as mentioned in runspec.txt. When you are doing a build, you will probably find that you want to pay close attention to the log file. Depending on the verbosity level that you have selected, it will contain enormous amounts of information about how your build went. The CPU2000 tool suite provides for varying amounts of output about its actions during a run. These levels range from the bare minimum of output (level 0) to copious streams of information almost certainly worthless to anyone not developing the tools themselves (level 99). Note: selecting one output level gives you the output from all lower levels, which may cause you to wade through more output than you might like. The 'level' referred to in the table is the in 'runspec --verbose '. Levels higher than 99 are special; they are always output to your log file. You can also see them on the screen if you set verbosity to the specified level minus 100. For example, the default log level is 3. This means that on your screen you will get messages at levels 0 through 3, and 100 through 103. Additionally, in your log file, you'll find messages at levels 104 through 199. Level What you get -------- --------------------------------------------------------------- 0 Basic status information, and most errors. These messages can not be turned off. 1 List of the benchmarks which will be acted upon. 2 A list of possible output formats, as well as notification when beginning and ending each phase of operation (build, setup, run, reporting). 3 (default) A list of each action performed during each phase of operation (e.g. "Building 176.gcc", "Setting up 253.perlbmk") 4 Notification of benchmarks excluded 10 Information on basepeak operation. 12 Errors during discovery of benchmarks and output formats. 24 Notification of additions to and replacements in the list of benchmarks. 30 A list of options included in the MD5 hash of options used to determine whether or not a given binary needs to be recompiled. 35 A list of key=value pairs that can be used in command and notes substitutions. 40 A list of 'submit' commands for each benchmark. 70 Information on selection of median results. 99 Gruesome detail of comparing MD5 hashes on files being copied during run directory setup. --- Messages at the following levels will always appear in your log files --- 100 Error message if the 'pdflib' module can't be loaded. 103 A tally of successes and failures during the run broken down by benchmark. 106 A list of runtime and calculated ratio for each benchmark run. 107 Dividers to visually block each phase of the run. 110 Error messages about writing temporary files in the config file output format. 120 Messages about which commands are being issued for which benchmarks. 125 A listing of each individual child processes' start, end, and elapsed times. 130 A nice header with the time of the runspec invocation and the command line used. 140 General information about the settings for the current run. 145 Messages about file comparisons. 150 List of commands that will be run, and details about the settings used for comparing output files. Also the contents of the Makefile written. 155 Start, end, and elapsed times for benchmark run. 160 Start, end, and elapsed times for benchmark compilation. 180 stdout and stderr from commands run 191 Notification of command line used to run specinvoke. VI. Files output during a build (continued) C. Log file example: Feedback-directed optimization. Let's consider the log file for a compile with feedback-directed optimization (FDO). This will serve both as an example of how you accomplish such a compile and how to interpret a log file. [Note: this section uses an actual log file, but white space has been liberally adjusted, and much extraneous output has been removed.] Feedback-directed optimization typically means that we want to compile a program twice: the first compile creates an image with certain instrumentation. Then, we run the program, and data about that run is collected (a profile). When the program is re-compiled, the collected data is use to improve the optimization. First, let's look at the config file entries that enabled FDO. The log file tells us what was written to the Makefile.spec, along with lots of state information: ----------------------------------- Building 197.parser ref base nov14a default Wrote to makefile '/cpu2000/benchspec/CINT2000/197.parser/run/00000002/Makefile.spec': PASS1_CFLAGS = -prof_gen_noopt -prof_dir /tmp/pb PASS2_CFLAGS = -prof_use_feedback -prof_dir /tmp/pb baseexe = parser fdo_pre0 = mkdir /tmp/pb; rm -f /tmp/pb/${baseexe}* feedback = 1 To tell the tools that we wanted to use FDO, all we had to do was set PASSn_CFLAGS. If the tools see any use of PASSn_xxxxx, they will perform multiple compiles. The particular compiler used in this example expects to be invoked twice: once with "-prof_gen_noopt" and then again with "-prof_use_feedback". Note that we have also requested special processing before we start, in the fdo_pre0 step. The variable ${baseexe} is substituted with the name of the generated executable, minus any extensions or directories: Issuing fdo_pre0 command 'mkdir /tmp/pb; rm -f /tmp/pb/parser* Below, the first compile is done. Notice that specmake is invoked with FDO=PASS1. If you want to understand exactly how this affects the build, read $SPEC/benchspec/Makefile.defaults, along with the document $SPEC/docs/makevars.txt. Briefly, the fact that FDO=PASS1 causes the switches from PASS1_CFLAGS to be used. Output from fdo_make_pass1 'specmake FDO=PASS1 build > fdo_make_pass1.out 2> fdo_make_pass1.err': cc -v -prof_gen_noopt -prof_dir /tmp/pb -DSPEC_CPU2000 -v -arch ev6 -fast analyze-linkage.c and.c build-disjuncts.c extract-links.c ... The next section shows how specinvoke runs the benchmark for the training run, according to the commands in speccmds.cmd. For more information on specinvoke, see $SPEC/docs/utility.txt. Basically, the instrumented parser is called using the training data set as input. Training 197.parser Commands to run: -u /cpu2000/benchspec/CINT2000/197.parser/run/00000002 -i train.in -o train.out -e train.err ../00000002/parser 2.1.dict -batch Specinvoke: /cpu2000/bin/specinvoke -d /cpu2000/benchspec/CINT2000/197.parser/run/00000002 -e speccmds.err -o speccmds.out -f speccmds.cmd Finally, the compiler is run a second time, this time to use the profile feedback and build a new executable. Notice that this time, specmake is invoked with FDO=PASS2, which is why the compile picks up the PASS2_CFLAGS: Output from fdo_make_pass2 'specmake FDO=PASS2 build > fdo_make_pass2.out 2> fdo_make_pass2.err': cc -v -prof_use_feedback -prof_dir /tmp/pb -DSPEC_CPU2000 -v -arch ev6 -fast analyze-linkage.c and.c build-disjuncts.c extract-links.c ... Compile for '197.parser' ended at:Thu Dec 16 23:35:48 1999 (945405348) Elapsed compile for '197.parser': 00:02:45 (165) Build Complete And that's it. The tools did most of the work; the user simply set PASS1_CFLAGS, PASS2_CFLAGS, and fdo_pre0 in the config file. VI. Files output during a build (continued) D. Help, I've got too many logs! If you do a very large number of builds and runs, you may find that your result directory gets far too cluttered. If it does, you should feel free to issue commands such as these on Unix systems: cd $SPEC mv result result_old mkdir result On NT, you could say: cd %SPEC% rename result result_old mkdir result E. Finding the build directory As described under "About Disk Usage" in runspec.txt, the CPU2000 tools do the actual builds and runs in numbered run directories. The benchmark sources are never modified in the src directory. To find the build directory, look for the word "build" in run/list. If more than one build directory is present, you can pipe the output to search for the specific extension that you want. For example: F:\cpu2000> cd %SPEC%\benchspec\CINT2000\164.gzip\run F:\cpu2000\benchspec\CINT2000\164.gzip\run>findstr build list 00000001 dir=F:/cpu2000/benchspec/CINT2000/164.gzip/run/00000001 ext=oct14a lock=0 type=build username=Administrator F:\cpu2000\benchspec\CINT2000\164.gzip\run>cd *01 VI. Files output during a build (continued) F. Files in the build directory A variety of files are output to the build directory. Here are some of the key files which can usefully be examined: Makefile.spec - the components for make that were generated for the current config file with the current set of runspec options options.out - For 1 pass compile: build options summary options1.out - For N pass compile: summary of first pass options2.out - For N pass compile: summary of second pass make.out - For 1 pass compile: detailed commands generated fdo_make_pass1.out - For N pass compile: detailed commands generated for 1st pass fdo_make_pass2.out - For N pass compile: detailed commands generated for 2nd pass *.err - The output from standard error corresponding to the above files. G. For more information For more information about how the run directories work, see the descriptions of specinvoke, specmake, and specdiff in $SPEC/docs/utility.txt (Unix) or %SPEC%\docs.nt\utility.txt (NT) VII. Troubleshooting --------------------- When something goes wrong with a build, here are some things to check: 1) Are there any obvious clues in the log file? Search for the word "Building". Keep searching until you hit the next benchmark AFTER the one that you are interested in. Now scroll backward one screenful. 2) Did your desired switches get applied? Go to the build directory, and look at options*out. 3) Did the tools or your compilers report any errors? Look in the build directory at *err. 4) What happens if you try the build by hand? See the section on specmake in utility.txt. 5) If an actual run fails, what happens if you invoke the run by hand? See the information about "specinvoke -n" in utility.txt. ----------------------------------------------------------------------------- Copyright (C) 1999-2000 Standard Performance Evaluation Corporation All Rights Reserved