Sun Studio 12 Update 1: OpenMP API User's Guide

Chapter 2 Compiling and Running OpenMP Programs

This chapter describes compiler and runtime options affecting programs that utilize the OpenMP API.

To run an OpenMP program in a multithreaded environment, you must set the number of threads in the the program to be greater than one. The number of threads is controlled by the OMP_SET_NUM_THREADS environment variable, which must be set greater than one prior to running the program. The number of threads can also be set by calling omp_set_num_threads() in the program with a value greater than one, or by using the num_threads clause with a PARALLEL directive.

The latest information regarding Sun Studio compilers and OpenMP can be found on the Sun Developer Network portal, http://developers.sun.com/sunstudio

2.1 Compiler Options To Use

To enable explicit parallelization with OpenMP directives, compile your program with the cc, CC, or f95 option flag -xopenmp. (The f95 compiler accepts both -xopenmp and -openmp as synonyms.)

The -xopenmp flag accepts the following optional keyword sub-options.

-xopenmp=parallel

Enables recognition of OpenMP directives.

The minimum optimization level for -xopenmp=parallel is -xO3.

The compiler changes the optimization from a lower level to -xO3 if necessary, and issues a warning.

-xopenmp=noopt

Enables recognition of OpenMP directives.

The compiler does not raise the optimization level if it is lower than -xO3.

If you explicitly set the optimization level lower than -xO3, as in -xO2 -openmp=noopt the compiler will issue an error.

If you do not specify an optimization level with -openmp=noopt, the OpenMP directives are recognized, the program is parallelized accordingly, but no optimization is done.

-xopenmp=stubs

This option is no longer supported.

An OpenMP stubs library is provided for users’ convenience.

To compile an OpenMP program that calls OpenMP library routines but ignores the OpenMP directives, compile the program without an -xopenmp option, and link the object files with the libompstubs.a library.

For example, % cc omp_ignore.c -lompstubs

Linking with both libompstubs.a and the OpenMP runtime library libmtsk.so is unsupported and may result in unexpected behavior.

-xopenmp=none

Disables recognition of OpenMP directives and does not change the optimization level.

Additional Notes:

If you do not specify —xopenmp on the command line, the compiler assumes —xopenmp=none (disabling recognition of OpenMP directives).
If you specify —xopenmp but without a keyword sub-option, the compiler assumes —xopenmp=parallel.
Specifying -xopenmp=parallel or noopt will define the _OPENMP preprocessor token to be YYYYMM (specifically 200805L for C/C++ and 200805 for Fortran 95).
When debugging OpenMP programs with dbx, compile with -xopenmp=noopt -g
The default optimization level for -xopenmp might change in future releases. Compilation warning messages can be avoided by specifying an appropriate optimization level explicitly.
With Fortran 95, -xopenmp , -xopenmp=parallel, -xopenmp=noopt will add -stackvar automatically.
When compiling and linking an OpenMP program in separate steps, include -xopenmp on each of the compile and the link steps.
Use the -xvpara C/C++/Fortran option to display compiler parallelization messages.
For best performance and functionality on Solaris platforms, make sure that the latest OpenMP runtime library, libmtsk.so, is installed on the running system.

2.2 OpenMP Environment Variables

The OpenMP specification defines a number of environment variables that control the execution of OpenMP programs. These are summarized in the following table. For details, refer to the OpenMP API Version 3.0 specifications. See also 3.8 Environment Variables

Table 2–1 OpenMP Environment Variables


Environment Variable	Function
`OMP_SCHEDULE`	Sets schedule type for `DO`, `PARALLEL` `DO`, `for`, `parallel` `for`, directives/pragmas with schedule type `RUNTIME` specified. If not set, a default value of `STATIC` is used. `value` is `“type[,chunk]”` Example: `setenv OMP_SCHEDULE 'GUIDED,4'`
`OMP_NUM_THREADS`	Sets the number of threads to use during execution of a parallel region. You can override this value by a `NUM_THREADS` clause, or a call to `OMP_SET_NUM_THREADS()`. If not set, a default of 1 is used. `value` is a positive integer. Example: `setenv OMP_NUM_THREADS 16`
`OMP_DYNAMIC`	Enables or disables dynamic adjustment of the number of threads available for execution of parallel regions. If not set, a default value of `TRUE` is used. `value` is either `TRUE` or `FALSE`. Example: `setenv OMP_DYNAMIC FALSE`
`OMP_NESTED`	Enables or disables nested parallelism. `value` is either `TRUE` or `FALSE`. The default is `FALSE`. Example: `setenv OMP_NESTED FALSE`
`OMP_STACKSIZE`	Sets the size of the stack for threads created by OpenMP. Size may be specified as a positive integer in Kilobytes, or with a suffix `B, K, M,` or `G`, for Bytes, Kilobytes, Megabytes, or Gigabytes. Example: `setenv OMP_STACKSIZE 10M`
`OMP_WAIT_POLICY`	Set desired policy regarding waiting threads. The value is either `ACTIVE` or `PASSIVE`. `ACTIVE` threads consume processor time while waiting. `PASSIVE` threads do not and may yield the processor or go to sleep.
`OMP_MAX_ACTIVE_LEVELS`	Sets the maximum number of levels of nested active parallel regions. Value is a non-negative integer.
`OMP_THREAD_LIMIT`	Sets the number of threads to use in the whole OpenMP program. Value is a positive integer.

Sun Studio supports additional multiprocessing environment variables that affect execution of OpenMP programs and are not part of the OpenMP specifications. These are summarized in the following table.

Table 2–2 Multiprocessing Environment Variables

Environment Variable

Function

PARALLEL

For compatibility with legacy programs, setting the PARALLEL environment variable has the same effect as setting OMP_NUM_THREADS. However, if both PARALLEL and OMP_NUM_THREADS are set, they must be set to the same value.

SUNW_MP_WARN

Controls warning messages issued by the OpenMP runtime library. If set to TRUE the runtime library issues warning messages to stderr; FALSE disables warning messages. The default is FALSE.

The OpenMP runtime library has the ability to check for many common OpenMP violations, such as incorrect nesting and deadlocks. However, runtime checking does add overhead to the execution of the program.

The runtime library issues warning messages to stderr if SUNW_MP_WARN is set to TRUE. The runtime library will also issue warning messages if the program registers a call-back function to accept warning messages. A program can register a user call-back function by calling the following function:

   int sunw_mp_register_warn (void (*func)(void *));

The address of the call-back function is passed as argument to sunw_mp_register_warn(). This function returns 0 upon successfully registering the call-back function, 1 upon failure.

If the program has registered a call-back function, libmtsk will call the registered function passing a pointer to the localized string containing the error message. The memory pointed to is no longer valid upon return from the call-back function.

Example:

setenv SUNW_MP_WARN TRUE

SUNW_MP_THR_IDLE

Controls the status of idle threads in an OpenMP program that are waiting at a barrier or waiting for new parallel regions to work on. You can set the value to be one of the following: SPIN, SLEEP, SLEEP( times), SLEEP(timems), SLEEP( timemc), where time is an integer that specifies an amount of time, and s, ms, and mc specify the time unit (seconds, milli-seconds, and micro-seconds, respectively). SLEEP, SLEEP(0), SLEEP(0s), SLEEP(0ms), and SLEEP(0mc) are all equivalent.

SPIN specifies that an idle thread should spin while waiting at barrier or waiting for new parallel regions to work on. SLEEP without a time argument specifies that an idle thread should sleep immediately. SLEEP with a time argument specifies the amount of time a thread should spin-wait before going to sleep.

The default idle thread status is to sleep after possibly spin-waiting for some amount of time.

Note that if both SUNW_MP_THR_IDLE and OMP_WAIT_POLICY are set, they must have consistent values.

Examples:

setenv SUNW_MP_THR_IDLE SPIN 
setenv SUNW_MP_THR_IDLE SLEEP 
setenv SUNW_MP_THR_IDLE SLEEP(2s) 
setenv SUNW_MP_THR_IDLE SLEEP(20ms) 
setenv SUNW_MP_THR_IDLE SLEEP(150mc)

SUNW_MP_PROCBIND

This environment variable works on both Solaris and Linux systems. The SUNW_MP_PROCBIND environment variable can be used to bind threads of an OpenMP program to virtual processors on the running system. Performance can be enhanced with processor binding, but performance degradation will occur if multiple threads are bound to the same virtual processor. See 2.3 Processor Binding for details.

SUNW_MP_MAX_POOL_THREADS

Specifies the maximum size of the thread pool. The thread pool contains only non-user threads that the OpenMP runtime library creates. It does not contain the master thread or any threads created explicitly by the user’s program. If this environment variable is set to zero, the thread pool will be empty and all parallel regions will be executed by one thread. The default, if not specified, is 1023. See 4.2 Control of Nested Parallelism for details.

Note that SUNW_MP_MAX_POOL_THREADS specifies the maximum number of non-user OpenMP threads to use for the whole program, while OMP_THREAD_LIMIT specifies the maximum number of user and non-user OpenMP threads for the whole program. If both SUNW_MP_MAX_POOL_THREADS and OMP_THREAD_LIMIT are set they must have consistent values such that OMP_THREAD_LIMIT is set to one more than the value of SUNW_MP_MAX_POOL_THREADS.

SUNW_MP_MAX_NESTED_LEVELS

Specifies the maximum depth of active nested parallel regions. Any parallel region that has an active nested depth greater than the value of this environment variable will be executed by only one thread. A parallel region is considered not active if it is an OpenMP parallel region that has a false IF clause. The default, if not specified, is 4. See 4.2 Control of Nested Parallelism for details.

Note that if both SUNW_MP_MAX_NESTED_LEVELS and OMP_MAX_ACTIVE_LEVELS are set, they must be set to the same value.

STACKSIZE

Sets the stack size for each thread. The value is in kilobytes. The default stack size for a helper thread is 4 Megabytes for 32-bit applications, and 8 Megabytes for 64-bit applications.

Example:

setenv STACKSIZE 8192 sets the thread stack size to 8 Mb

The STACKSIZE environment variable also accepts numerical values with a suffix of either B, K, M, or G for bytes, kilobytes, megabytes, or gigabytes respectively. The default is kilobytes.

Note that if both STACKSIZE and OMP_STACKSIZE are set, they must be set to the same value.

SUNW_MP_GUIDED_WEIGHT

Sets the weighting factor used to determine the size of chunks assigned to threads in loops with GUIDED scheduling. The value should be a positive floating-point number, and will apply to all loops with GUIDED scheduling in the program. If not set, the default value assumed is 2.0.

2.3 Processor Binding

With processor binding, the programmer instructs the operating system that a thread in the program should run on the same processor throughout the execution of the program.

Processor binding, when used along with static scheduling, benefits applications that exhibit a certain data reuse pattern where data accessed by a thread in a parallel or worksharing region will be in the local cache from a previous invocation of a parallel or worksharing region.

From the hardware point of view, a computer system is composed of one or more physical processors. From the operating system point of view, each of these physical processors maps to one or more virtual processors onto which threads in a program can be run. If n virtual processors are available, then n threads can be scheduled to run at the same time. Depending on the system, a virtual processor may be a processor, a core, etc.

For example, each UltraSPARC IV physical processor has two cores; from the Solaris OS point of view, each of these cores is a virtual processor onto which a thread can be scheduled to run. The UltraSPARC T1 physical processor, on the other hand, has eight cores, and each core can run four simultaneous processing threads; from the Solaris OS point of view, there are 32 virtual processors onto which threads can be scheduled to run. On the Solaris Operating System, the number of virtual processors can be determined by using the psrinfo(1M) command. On Linux systems, the file /proc/cpuinfo provides information about available processors.

When the operating system binds threads to processors, they are in effect bound to specific virtual processors, not physical processors.

Set the SUNW_MP_PROCBIND environment variable to bind threads in an OpenMP program to specific virtual processors. The value specified for SUNW_MP_PROCBIND can be one of the following:

The string "TRUE" or "FALSE" (or lower case "true" or "false"). For example, % setenv SUNW_MP_PROCBIND "false"
A non-negative integer. For example, % setenv SUNW_MP_PROCBIND "2"
A list of two or more non-negative integers separated by one or more spaces. For example, % setenv SUNW_MP_PROCBIND "0 2 4 6"
Two non-negative integers, n1 and n2, separated by a minus ("-"); n1 must be less than or equal to n2. For example, % setenv SUNW_MP_PROCBIND "0-6"

Note that the non-negative integers referred to above denote logical identifiers (IDs). Logical IDs may be different from virtual processor IDs. The difference will be explained below.

Virtual Processor IDs:

Each virtual processor in a system has a unique processor ID. On Solaris platforms, you can use the psrinfo(1M) command to display information about the processors in a system, including their processor IDs. You can use psrinfo -pv to list all physical processors in the system and the virtual processors that are associated with each physical processor. Moreover, you can use the prtdiag(1M) command to display system configuration and diagnostic information.

Virtual processor IDs may be sequential or there may be gaps in the IDs. For example, on a Sun Fire 4810 with 8 UltraSPARC IV processors (16 cores), the virtual processor IDs may be: 0, 1, 2, 3, 8, 9, 10, 11, 512, 513, 514, 515, 520, 521, 522, 523.

Logical IDs:

As mentioned above, the non-negative integers specified for SUNW_MP_PROCBIND are logical IDs. Logical IDs are consecutive integers that start with 0. If the number of virtual processors available in the system is n, then their logical IDs are 0, 1, ..., n-1, in the order presented by psrinfo(1M). The following Korn shell script can be used to display the mapping from virtual processor IDs to logical IDs.

#!/bin/ksh

NUMV=`psrinfo | fgrep "on-line" | wc -l `
set -A VID  `psrinfo | cut -f1 `

echo "Total number of on-line virtual processors = $NUMV"
echo

let "I=0"
let "J=0"
while [[ $I -lt $NUMV ]]
do
  echo "Virtual processor ID ${VID[I]} maps to logical ID ${J}"
  let "I=I+1"
  let "J=J+1"
done

On systems where a single physical processor maps to several virtual processors, it may be useful to know which logical IDs correspond to virtual processors that belong to the same physical processor. The following Korn shell script can be used with later Solaris releases to display this information.

#!/bin/ksh

NUMV= `psrinfo | grep "on-line" | wc -l `
set -A VLIST  `psrinfo | cut -f1 `
set -A CHECKLIST  `psrinfo | cut -f1 `

let "I=0"

while [ $I -lt $NUMV ]
do
  let "COUNT=0"
  SAMELIST="$I"

  let "J=I+1"

  while [ $J -lt $NUMV ]
  do
    if [ ${CHECKLIST[J]} -ne -1 ]
    then
      if [  `psrinfo -p ${VLIST[I]} ${VLIST[J]} ` = 1 ]
      then
        SAMELIST="$SAMELIST $J"
        let "CHECKLIST[J]=-1"
        let "COUNT=COUNT+1"
      fi
    fi
    let "J=J+1"
  done

  if [ $COUNT -gt 0 ]
  then
    echo "The following logical IDs belong to the same physical processor:"
    echo "$SAMELIST"
    echo " "
  fi

  let "I=I+1"
done

Interpreting the Value Specified for SUNW_MP_PROCBIND:

If the value specified for SUNW_MP_PROCBIND is TRUE, then the threads will be bound to virtual processors in a round-robin fashion, starting with the processor whose logical ID is 0. (Specifying TRUE is equivalent to specifying the value 0 for SUNW_MP_PROCBIND.)

If the value specified for SUNW_MP_PROCBIND is a non-negative integer, then that integer denotes the starting logical ID of the virtual processor to which threads should be bound. Threads will be bound to virtual processors in a round-robin fashion, starting with the processor with the specified logical ID, and wrapping around to the processor with logical ID 0, after binding to the processor with logical ID n-1.

If the value specified for SUNW_MP_PROCBIND is a list of two or more non-negative integers, then threads will be bound in a round-robin fashion to virtual processors with the specified logical IDs. Processors with logical IDs other than those specified will not be used.

If the value specified for SUNW_MP_PROCBIND is two non-negative integers separated by a minus ("-"), then threads will be bound in a round-robin fashion to virtual processors in the range that begins with the first logical ID and ends with the second logical ID. Processors with logical IDs other than those included in the range will not be used.

If the value specified for SUNW_MP_PROCBIND does not conform to one of the forms described above, or if an invalid logical ID is given, then an error message will be emitted and execution of the program will terminate.

Note that the number of threads created by the microtasking library, libmtsk, depends on environment variables, API calls in the user’s program, and the num_threads clause. SUNW_MP_PROCBIND specifies the logical IDs of virtual processors to which the threads should be bound. Threads will be bound to that set of processors in a round-robin fashion. If the number of threads used in the program is less than the number of logical IDs specified by SUNW_MP_PROCBIND, then some virtual processors will not be used by the program. If the number of threads is greater than the number of logical IDs specified by SUNW_MP_PROCBIND, them some virtual processors will have more than one thread bound to them.

Interaction with OS Processor Sets

A processor set can be specified using the psrset utility on Solaris platforms, or the taskset command on Linux platforms. SUNW_MP_PROCBIND does not take processor sets into account. If the programmer uses processor sets, then it is their responsibility to ensure that the setting of SUNW_MP_PROCBIND is consistent with the processor set used. Otherwise, the setting of SUNW_MP_PROCBIND will override the processor set setting on Linux systems, while on Solaris systems an error message will be issued.

2.4 Stacks and Stack Sizes

The executing program maintains a main stack for the initial thread executing the program, as well as distinct stacks for each helper thread. Stacks are temporary memory address spaces used to hold arguments and automatic variables during invocation of a subprogram or function reference.

In general, the default main stack size is 8 megabytes. Compiling Fortran programs with the f95 -stackvar option forces the allocation of local variables and arrays on the stack as if they were automatic variables. Use of -stackvar with OpenMP programs is implied However, this may lead to stack overflow if not enough memory is allocated for the stack.

Use the limit C-shell command, or the ulimit ksh/sh command, to display or set the size of the main stack.

Each helper thread of an OpenMP program has its own thread stack. This stack mimics the initial (or main) thread stack but is unique to the thread. The thread’s PRIVATE arrays and variables (local to the thread) are allocated on the thread stack. The default size is 4 megabytes on 32-bit SPARC V8 and x86 platforms, and 8 megabytes on 64-bit SPARC V9 and x86 platforms. The size of the helper thread stack is set with the OMP_STACKSIZE environment variable.

demo% setenv OMP_STACKSIZE 16384   <-Set thread stack size to 16 Mb (C shell)

demo$ OMP_STACKSIZE=16384          <-Same, using Bourne/Korn shell
demo$ export OMP_STACKSIZE

Finding the best stack size might have to be determined by trial and error. If the stack size is too small for a thread to run it may cause silent data corruption in neighboring threads, or segmentation faults. If you are unsure about stack overflows, compile your Fortran, C, or C++ programs with the -xcheck=stkovf compiler option to force a segmentation fault on stack overflow. This stops the program before any data corruption can occur.

2.5 Checking the Correctness of OpenMP Programs

The following are various mechanisms and tools that are available for checking the correctness of an OpenMP program.

You can use the -xvpara C/C++/Fortran option to display compiler parallelization messages
You can use the Sun Studio dbx tool to debug C, C++, and Fortran OpenMP programs. An OpenMP program should first be prepared for debugging with dbx by compiling it with the options-xopenmp=noopt -g. dbx allows the programmer to single-step into a PARALLEL region, set breakpoints in the body of an OpenMP construct, as well as print the values of shared, private, and other. variables for a given thread.
You can use the SUNW_MP_WARN environment variable to enable runtime error checking and the issuing of warning messages by the OpenMP runtime library.
You can check your OpenMP program for data races and deadlocks by using the Sun Studio Thread Analyzer tool. Refer to the Thread Analyzer manual and the tha(1) man page for details.