svcadm(8)을 검색하려면 섹션에서 8 을 선택하고, 맨 페이지 이름에 svcadm을 입력하고 검색을 누른다.
cc(1)
cc(1) User Commands cc(1)
NAME
cc - C compiler
SYNOPSIS
cc [-#] [-###] [-Aname[(tokens)]] [-ansi]
[-B[static|dy- namic]] [-C] [-c] [-D] [-d[y|n]] [-dalign]
[-E] [-errfmt[=[no%]error]] [-errhdr[=h]]
[-erroff[=t[,t...]]] [-errshort[=i]] [-errtags=a]
[-errwarn[=xtarget[,t...]]] [-fast] [-fcommon] [-fd] [-features=[a]] [-fexceptions] [-fno-exceptions]
[-flags] [-flteval[={any|2}]] [-fma[={none|fused}]]
[-fnonstd] [-fno-strict-aliasing] [-fno-common] [-fnoshort-enums] [-fns=[no|yes]] [-fopenmp] [-fprecision=p]
[-fround=r] [-fshort-enums] [-fsimple[=n]] [-fsingle] [-fstore] [-fstrict-aliasing]
[-ftrap[=t[,t...]]] [-fvisibility=v] [-G] [-g] [-g[n]] [-gz[=cmp-type]] [-H] [-hname]
[-I[-|dir]] [-i] [-include] [-KPIC] [-Kpic] [-keeptmp]
[-Ldir] [-lname] [-library=sunperf] [-m32|-m64] [-mc]
[-misalign] [-misalign2] [-mr[,string]] [-mt] [-native]
[-nofstore][-O] [-On] [-ofilename] [-P] [-p]
[-pedantic{[yes=|no]}] [-preserve_argvalues[=int|none]]
[-Qoption phase [,option...]] [-Q[y|n]] [-qp]
[-Rdir[:dir...]] [-S] [-s] [-shared] [-staticlib=[no%]sunperf]
[-std=value] [-temp=path] [-traceback[=list]] [-Uname]
[-V] [-v] [-Wc,arg] [-w] [-X[c|a|t|s]] [-Xlinker arg]
[-xaddr32[={yes|no}]] [-xalias_level[=a]]
[-xannotate] [-xarch=a] [-xatomic=a]
[-xautopar] [-xbuiltin[=a]] [-xCC]
[-xc99[=o]] [-xcache=c] [-xchar[=o]]
[-xchar_byte_order[=o]] [-xcheck=n] [-xchip=c]
[-xcode=v] [-xcsi] [-xcompress={[no%]debug}] [-xcompress_format=cmp-type] [-xdebugformat=dwarf]
[-xdebuginfo=a[,a...]] [-xdepend[={yes|no}]]
[-xdryrun] [-xdumpmacros[=v[,v...]]] [-xe] [-xF[=v]]
[-xglobalize[={yes|no}]] [-xhelp=f]
[-xhwcprof[={enable|disable}]] [-xinline=[v[,v...]]]
[-xinline_param=a[,a[,a]...]] [-xinline_report[=n]]
[-xinstrument=[no%]datarace] [-xipo[=n]]
[-xipo_archive[=a]] [-xipo_build=[yes|no]]
[-xivdep[=p]] [-xjobs={n|auto}]
[-xkeep_unref[={[no%]funcs,[no%]vars}]]
[-xkeepframe[=p]] [-xlang=language] [-xldscope=[v]]
[-xlibmieee] [-xlibmil] [-xlibmopt]
[-xlinkopt[=level]] [-xloopinfo] [-xM] [-xM1] [-xMD]
[-xMF] [-xMMD] [-xMerge] [-xmaxopt[=v]] [-xmemalign=ab]
[-xmodel=[a]] [-xnolib] [-xnolibmil] [-xnolibmopt]
[-xnorunpath] [-xOn] [-xopenmp[=i]] [-xP]
[-xpagesize=n] [-xpagesize_heap=n] [-xpagesize_stack=n]
[-xpatchpadding[={fix|patch|size}]] [-xpec] [-xpch=v]
[-xpchstop] [-xpentium] [-xpg] [-xprefetch[=val[,val]]]
[-xprefetch_auto_type=[a] [-xprefetch_level=l]
[-xprevise={yes|no}] [-xprofile=p] [-xprofile_ircache[=path]]
[-xprofile_pathmap=collect_prefix:use_prefix]
[-xreduction] [-xregs=r[,r...]] [-xrestrict[=f]]
[-xs[={yes|no}]] [-xsafe=mem] [-xsecure_code_analysis{=[yes|no]]
[-xsegment_align=n] [-xsfpconst]
[-xspace] [-xstrconst] [-xtarget=t] [-xtemp=path]
[-xthreadvar[=o] [-xthroughput[={yes|no}]] [-xtime]
[-xtransition] [-xtrigraphs[=[yes|no]]
[-xunboundsym={yes|no}] [-xunroll=n]
[-xustr={ascii_utf16_ushort|no}] [-xvector[=a]] [-xvis]
[-xvpara] [-Yc,dir] [-YA,dir] [-YI,dir] [-YP,dir]
[-YS,dir] [-Zll]
DESCRIPTION
Oracle Developer Studio 12.6 C Compiler version 5.14.
This man page details the options or flags that are available for the C
compiler in the Oracle Developer Studio 12.6 release.
Complete documentation for this release is available on the Oracle
Technical Network (OTN) Oracle Developer Studio website:
http://oracle.com/technetwork/server-storage/developerstudio
The OTN website is a complete resource for Oracle Developer Studio and
includes many technical articles detailing best practices and deep
dives into various programming technologies and other topics.
For the complete description of all new features and functionality in
the Oracle Developer Studio suite, see the What's New in the Oracle
Developer Studio
12.6
Release.
A man page, by definition, is a quick reference. For more detailed
information on the C compiler and its options, see the Oracle
Developer Studio
12.6:
C User's Guide.
Compiling for 64-bit Platforms
Use the -m32 and -m64 options to specify the data type model of the
target compilation, ILP32 or LP64 respectively.
The -xarch option no longer carries an implicit data type model defini‐
tion, and should be used only to specify the instruction set of the
target processor.
The ILP32 model specifies that C-language int, long, and pointer data
types are each 32-bits wide. The LP64 model specifies that long and
pointer data types are each 64-bits wide and int is 32-bits wide. The
Oracle Solaris and Linux OS also support large files and large arrays
under the LP64 data type model.
Special x86 Notes
There are some important issues to be aware of when compiling for x86
Oracle Solaris platforms.
Programs compiled with -xarch set to sse2, sse2a, or sse3 and beyond
must be run only on platforms that provide these extensions and fea‐
tures.
With this release, the default instruction set and the meaning of
-xarch=generic has changed to sse2. Now, compiling without specifying a
target platform option results in an sse2 binary incompatible with
older Pentium III or earlier systems.
If you compile and link in separate steps, always link using the com‐
piler and with same -xarch setting to ensure that the correct startup
routine is linked.
Numerical results can also differ between Oracle Solaris and Linux
because the intrinsic math libraries (for example, sin(x)) are not the
same.
Binary Compatibility Verification
Since the release of Oracle Solaris 10, the linker will automatically
check the compatibility of binary objects against the runtime hardware
platform.
Program binaries compiled and built using specialized -xarch hardware
flags are verified by the OS that they are being run on the appropriate
platform. Running programs compiled with specialized -xarch options on
platforms that are not enabled with the appropriate features or
instruction set extensions could result in segmentation faults or
incorrect results occurring without any explicit warning messages.
On Linux, however, there is no such verification check. Running binary
objects compiled by Oracle Developer Studio compilers on older hardware
platforms could result in runtime failures; on Linux it is the user's
responsibility to deploy these binaries on suitable hardware platforms.
This warning extends also to programs that employ .il inline assembly
language functions or __asm() assembler code that utilize SSE2, SSE2a,
and SSE3 (and beyond) instructions and extensions.
Overview of the C Compiler
The cc (1) manual page describes the ISO C compiler options that are
SVID compliant under current Oracle Solaris operating systems. Take
note that the C compiler recognizes by default some of the constructs
of the 2011 ISO/IEC C standard. Specifically, the supported features
are detailed in the Oracle Developer Studio
12.6:
C User's Guide. Use the -std flag to limit the compiler to
a specific version of the ISO/IEC C standard.
cc is the interface to the C compilation system. The compilation
process incorporates a preprocessor, compiler, code generator, opti‐
mizer, assembler, and link editor. cc processes the supplied options
and then executes the various components with the proper arguments. cc
accepts several types of files as arguments.
Files with .c suffix are taken to be C source files and may be prepro‐
cessed, compiled, optimized, instrumented for profiling, assembled, and
link edited. Although the preprocessor can be used as a macro proces‐
sor, this is not recommended, as its output is geared toward that which
would be acceptable as input to a valid C compiler. The compilation
process may be stopped after the completion of any pass if the appro‐
priate options are supplied.
If the compilation process runs through the assembler, then an object
file is produced in the current working directory with .o suffix sub‐
stituted for .c. However, the .o file is normally deleted if a single C
file is compiled and then immediately link edited.
Files with .s suffix are taken to be assembly source files; they may be
assembled and link edited.
Files with .S suffix are taken to be assembly source files; they may be
assembled and link edited. Such files are passed to the preprocessor
(/usr/ccs/lib/cpp on Oracle Solaris), and then to the assembler.
Files with an .i are taken to be preprocessed C source files, and may
be compiled, optimized, instrumented for profiling, assembled, and link
edited. Files whose names do not end in .c, .s, .S or .i are passed to
the link editor, which produces a dynamically linked executable whose
name by default is a.out.
See option -Yc, dir to change the default directories used for finding
libraries. dir is a colon-separated path list.
The default library search order can be seen by using the -### or
-xdryrun option and examining the -Y option of the ld invocation.
User-Supplied Default Compiler Options Startup File
The default compiler options file enables the user to specify a set of
default options that are applied to all compiles, unless otherwise
overridden. For example, the file could specify that all compiles
default at -xO2, or automatically include the file setup.il.
At startup, the compiler searches for a default options file listing
default options it should include for all compiles. The environment
variable SPRO_DEFAULTS_PATH specifies a colon-separated list of direc‐
tories to search for the the defaults file.
If the environment variable is not set, a standard set of defaults is
used. If the environment variable is set but is empty, no defaults are
used.
The defaults file name must be of the form compiler.defaults, where
compiler is one of the following: cc, c89, c99, CC, ftn, or lint. For
example, the defaults for the C compiler would be cc.defaults
If a defaults file for the compiler is found in the directories listed
in SPRO_DEFAULTS_PATH, the compiler will read the file and process the
options prior to processing the options on the command line. The first
defaults file found will be used and the search terminated.
System administrators may create system-wide default files in Studio-
install-path/lib/compilers/etc/config. If the environment variable is
set, the installed defaults file will not be read.
The format of a defaults file is similar to the command line. Each line
of the file may contain one or more compiler options separated by white
space. Shell expansions, such as wild cards and substitutions, will not
be applied to the options in the defaults file.
The value of the SPRO_DEFAULTS_PATH and the fully expanded command line
will be displayed in the verbose output produced by options -#, -###,
and -dryrun.
Options specified by the user on the command line will usually override
options read from the defaults file. For example, if the defaults file
specifies compiling with -xO4 and the user specifies -xO2 on the com‐
mand line, -xO2 will be used.
Some options appearing in the default options file will be appended
after the options specified on the command line. These are the pre‐
processor option -I, linker options -B, -L, -R, and -l, and all file
arguments, such as source files, object files, archives, and shared
objects.
The following is an example of how a user-supplied default compiler
option startup file might be used.
demo% cat /project/defaults/cc.defaults
-fast -I/project/src/hdrs -L/project/libs -llibproj -xvpara
demo% setenv SPRO_DEFAULTS_PATH /project/defaults
demo% cc -c -I/local/hdrs -L/local/libs -lliblocal tst.c
The compiler command is now equivalent to:
cc -fast -xvpara -c -I/local/hdrs -L/local/libs -lliblocal \
tst.c -I/project/src/hdrs -L/project/libs -llibproj
While the compiler defaults file provides a convenient way to set the
defaults for an entire project, it can become the cause of hard to
diagnose problems. Set the environment variable SPRO_DEFAULTS_PATH to
an absolute path rather than the current directory to avoid such prob‐
lems.
The interface stability of the default options file is uncommitted. The
order of option processing is subject to change in a future release.
OPTIONS
All platform-specific options are silently accepted on all platforms.
Any exceptions to this rule are noted under the specific option.
Options valid only on SPARC platforms are marked (SPARC). Options valid
only on x86/x64 platforms are marked (x86).
Deprecated options are marked (Obsolete) and should not be used going
forward. They are provided only for compatibility with earlier
releases. Use the indicated replacement option.
See ld(1) for linker options.
In general, processing of the compiler options is from left to right,
permitting selective overriding of macro options. This rule does not
apply to linker or preprocessor options.
In the syntax of the command-line options, items shown in square brack‐
ets ( [] ) are optional. Curly brackets enclose a bar-separated list of
literal items to be chosen, as in {yes | no | maybe }. The first item
in a list usually indicates the default value when the flag appears
without a value.
For example, -someoption[={no|yes}] implies -someoption is the same as
-someoption=no.
The following options are interpreted by cc:
-#
Turns on verbose mode, showing how command options expand. Shows
each component as it is invoked.
-###
Shows each component as it would be invoked, but does not actually
execute it. Also shows how command options would expand.
-Aname[(tokens)]
Associate name as a predicate with the specified tokens as if by a
#assert preprocessing directive.
Preassertions:system(unix)
machine(sparc) (SPARC)
machine(i386) (x86)
cpu(sparc) (SPARC)
cpu(i386) (x86)
The above are not predefined in -pedantic mode.
If -A is followed by a dash (-) only, it causes all predefined
macros (other than those that begin with __) and predefined asser‐
tions to be forgotten.
-ansi
Equivalent to -std=c89.
-B [static|dynamic]
Specifies whether bindings of libraries for linking are static or
dynamic, indicating whether libraries are non-shared or shared,
respectively. -B dynamic causes the link editor to
look for files named libx.so and then for files named libx.a when
given the -lx option. -B static causes the link edi‐
tor to look only for files named libx.a. This option may be speci‐
fied multiple times on the command line as a toggle.
This option and its argument are passed to ld.
-C
Prevents the C preprocessor from removing comments, other than
those on preprocessing directive lines.
-c
Compile and produce a .o file for each source file without linking.
You can explicitly name a single object file by using the -o
option. When the compiler produces object code for each or input
file, it always creates an object file in the current working
directory. If you suppress the linking step, you also suppress the
removal of the object files.
-Dname[(arg[,arg])] [=expansion]
Define a macro with optional arguments as if the macro is defined
by a #define preprocessing directive. If no =expansion is speci‐
fied, the compiler assumes =1.
Predefinitions:unix
sparc (SPARC)
sun
The above are not predefined in -pedantic mode.
These predefinitions are valid in all modes:
__BUILTIN_VA_ARG_INCR
__SUNPRO_C=0x5140
__SVR4 (Oracle Solaris)
__SVR4__ (Oracle Solaris)
__svr4__ (Oracle Solaris)
__db4 (Oracle Solaris)
__SunOS_5_10 (Oracle Solaris)
__SunOS_5_11 (Oracle Solaris)
__SunOS_RELEASE (Oracle Solaris)
__amd64 (x86 -m64)
__gnu__linux (linux)
__i386 (x86)
__i386__ (x86 -m32)
__linux (linux)
__linux__ (linux)
__sparc (SPARC)
__sparcv8 (SPARC)
__sparcv9 (SPARC -m64)
__sun (Oracle Solaris)
__unix
__`uname -s`_`uname -r | tr . _`
__x86_64 (x86 -m64)
linux (x86, linux)
_LP64 (-m64)
__LP64__ (-m64)
A hex value 0xRRrrmm representing the Oracle Solaris release, where
RR.rr is the output of the sysinfo (SI_RELEASE) system call, or of
the uname -r command, with leading zeros added when needed. The mm
digits are reserved for possible future "micro" releases. All the
digits are decimal. Example for Oracle Solaris 11, which is SunOS
5.11: __SunOS_RELEASE, has the value, 0x051100 . The value of
__SunOS_RELEASE for an older Oracle Solaris release is always less
than the value for a later release. Example of use:
#if __SunOS_RELEASE >= 0x051100 // Solaris 11 or later.
The following is predefined with any -std flag value when -pedantic
is not specified to indicate the availability of the _Restrict key‐
word:
__RESTRICT
The compiler also predefines the following object-like macro to
indicate the pragma will be recognized:
__PRAGMA_REDEFINE_EXTNAME
-d [y|n]
Allow or disallow dynamic linking.
-dy specifies dynamic linking, which is the default, in the link
editor. -dn specifies static linking in the link editor.
This option and its argument are passed to ld.
Note: This option causes fatal errors if you use it in combination
with dynamic libraries. Most system libraries are only available as
dynamic libraries.
-dalign
(SPARC) (Obsolete) You should not use this option. Use -xmema‐
lign=8s instead. For a complete list of obsolete options and flags,
see the Oracle Developer Studio
12.6:
C User's Guide. Ignored on x64/x86 platforms.
-E
Runs the source file through the preprocessor only and sends the
output to stdout. The preprocessor is built directly into the com‐
piler, except in -Xs mode, where /usr/ccs/lib/cpp is invoked.
Includes the preprocessor line numbering information. See also -P
option.
-errfmt[=[no%]error]
Use this option if you want to prefix the string "error:" to the
beginning of error messages so they are more easily distinguishable
from warning messages. The prefix is also attached to warnings that
are converted to errors by -errwarn.
error
Add the prefix "error:" to all error messages.
no%error
Do not add the prefix "error:" to any error messages.
If you do not use this option, the compiler sets it to
-errfmt=no%error. If you use specify -errfmt, but do not supply a
value, the compiler sets it to -errfmt=error.
-errhdr [=h]
Use this option to limit the warnings from header files to the
group of header files indicated by the following flags:
%all Check all used header files.
%none Check none of the header files.
%user Default. Checks all the user header files. Does not
check system include files, those in /usr/include and
its subdirectories. Does not check system header files
supplied by the compiler.
-erroff[=t[,t...] ]
Suppresses compiler warning messages but has no effect on error
messages. This option applies to all warning messages whether or
not they have been designated by -errwarn to cause a non-zero exit
status.
The -erroff values are members of a comma-separated list that con‐
sists of one or more of the following:
tag Suppresses the warning message specified by this tag.
You can display the tag for a message by using the
-errtags=yes option.
no%tag Enables the warning message specified by this tag.
%all Suppresses all warning messages.
%none Enables all warning messages. This is the default.
Order is important; for example, %all,no%tag suppresses all warning
messages except tag.
The default is -erroff=%none. Specifying -erroff is equivalent to
specifying -erroff=%all.
Only warning messages from the C compiler that display a tag when
the -errtags option is used can be suppressed with the -erroff
option. You can achieve finer control over error message suppres‐
sion by using #pragma error_messages.
-errshort[=i]
Use this option to control how much detail is in the error message
produced by the compiler when it discovers a type mismatch. This
option is particularly useful when the compiler discovers a type
mismatch that involves a large aggregate.
i can be one of the following:
short Error messages are printed in short form with no
expansion of types. Aggregate members are not
expanded, neither are function argument and return
types.
full Error messages are printed in full verbose form show‐
ing the full expansion of the mismatched types.
tags Error messages are printed with tag names for types
which have tag names. If there is no tag name, the
type is shown in expanded form.
If you do not use -errshort, the compiler sets the option to
-errshort=full. If you specify -errshort, but do not provide a
value, the compiler sets the option to -errshort=tags.
This option does not accumulate, it accepts the last value speci‐
fied on the command line.
-errtags=a
Displays the message tag for each warning message of the C compiler
that can be suppressed with the -erroff option or made a fatal
error with the -errwarn option. Messages from the C compiler driver
and other components of the C compilation system do not have error
tags, and cannot be suppressed with -erroff and made fatal with
-errwarn.
a can be either yes or no. The default is -errtags=no. Specifying
-errtags is equivalent to specifying -errtags=yes.
-errwarn[=t[,t...] ]
Use the -errwarn option to cause the C compiler to exit with a
failure status for the given warning messages.
t is a comma-separated list that consists of one or more of the
following: tag, no%tag, %all, %none. Order is important; for exam‐
ple %all,no%tag causes the C compiler to exit with a fatal status
if any warning except tag is issued.
The warning messages generated by the C compiler change from
release to release as the compiler error checking improves and fea‐
tures are added. Code that compiles using -errwarn=%all without
error may not compile without error in the next release of the com‐
piler.
Only warning messages from the C compiler that display a tag when
the -errtags option is used can be specified with the -errwarn
option to cause the C compiler to exit with a failure status.
The default is -errwarn=%none. If you specify -errwarn alone, it is
equivalent to -errwarn=%all.
The following table details the -errwarn values:
tag Cause cc to exit with a fatal status if the message
specified by tag is issued as a warning message. Has
no effect if tag in not issued.
no%tag Prevent cc from exiting with a fatal status if the
message specified by tag is issued only as a warning
message. Has no effect if tag is not issued. Use this
option to revert a warning message that was previously
specified by this option with tag or %all from causing
cc to exit with a fatal status when issued as a warn‐
ing message.
%all Cause cc to exit with a fatal status if any warning
messages are issued. %all can be followed by no%tag to
exempt specific warning messages from this behavior.
%none Prevents any warning messages from causing cc to exit
with a fatal status should any warning tag be issued.
This is the default.
-fast
This option is a macro that you can effectively use as a starting
point for tuning an executable for maximum runtime performance. The
expansion of -fast can change from one release of the compiler to
the next and includes options that are target platform specific.
Use the -# or the -xdryrun options to examine the expansion of
-fast, and incorporate the appropriate options of -fast into the
ongoing process of tuning the executable.
The expansion of -fast includes -xlibmopt option, which enables the
compiler to use a library of optimized math routines. For more
information, see the description of -xlibmopt in this man page.
The -fast option impacts the value of errno. See the NOTES section
at the end of this man page for more information.
Modules that are compiled with -fast must also be linked with
-fast. For a complete list of compiler options that must be speci‐
fied at both compile time and at link time, see the Oracle Devel‐
oper Studio
12.6:
C User's Guide.
The -fast option is unsuitable for programs that are intended to
run on a different target than the compilation machine. In such
cases, follow -fast with the appropriate -xtarget option. For exam‐
ple:
% cc -fast -xtarget=generic
For C modules depending on exception handling specified by SUID,
follow -fast by -xnolibmil -xbuiltin=%default
% cc -fast -xnolibmil -xbuiltin=%default
The -fast option acts like a macro expansion on the command line.
Therefore, you can override any of the expanded options by follow‐
ing -fast with the desired option.
If you combine -fast with other options, the last specification
applies.
These options are turned on for -fast:
-fma=fused (SPARC, x86)
-fns (SPARC, x86)
-fsimple=2 (SPARC, x86)
-fsingle (SPARC, x86)
-nofstore (x86)
-xalias_level=basic (SPARC, x86)
-xbuiltin=%all (SPARC, x86)
-xdepend (SPARC, x86)
-xlibmil (SPARC, x86)
-xlibmopt (SPARC, x86)
-xmemalign=8s (SPARC)
-xO5 (SPARC, x86)
-xregs=frameptr (x86)
-xtarget=native (SPARC, x86)
Note that this selection of component option flags is subject to
change with each release of the compiler. For details on the
options set by -fast, see the Oracle Developer Studio
12.6:
C User's Guide.
To determine the expansion of -fast on a running system, execute
the command:
cc -fast -xdryrun |& grep ###
Note: Some optimizations make certain assumptions about program
behavior. If the program does not conform to these assumptions, the
application may crash or produce incorrect results. Please refer to
the description of the individual options to determine if your pro‐
gram is suitable for compilation with -fast.
Do not use this option for programs that depend on IEEE standard
exception handling; you can get different numerical results, prema‐
ture program termination, or unexpected SIGFPE signals.
The -fast option on x86 includes -xregs=frameptr. Be sure to read
the discussion of -xregs=frameptr especially when compiling mixed
C, Fortran, and C++ source codes.
-fcommon
Reverses -fno-common if specified on the command line after -fno-
common.
-fd
Reports K&R function declarations and definitions.
-features=[a]
The compiler's treatment of extern inline functions conforms by
default to the behavior specified by the ISO/IEC 9899:1999 C stan‐
dard. Compile new codes with -features=no%extinl to obtain the same
treatment of extern inline functions as provided by versions 5.5,
or older, of the C and C++ compilers.
Old C and C++ objects (pre C/C++ 5.6) can be linked with new C and
C++ objects with no change of behavior for the old objects. To get
standard conforming behavior, old code must be recompiled using the
current compiler.
The following table lists the possible values for a. Prefix no%
disables a suboption.
[no%]conststrings
Enables or disables the placement of string literals in read-
only memory. The default is -features=conststrings which
replaces the deprecated -xstrconst option. Note that your pro‐
gram will fail to write to a string literal under the default
compilation mode just as if you had specified -xstrconst on the
command line.
[no%]extensions
Allows/disallows zero-sized struct/union declarations and void
function with return statements returning a value to work.
extinl
Generates extern inline functions as global functions. This is
the default, which conforms with the 1999 C standard.
[no%]extinl
Generates extern inline functions as static functions.
[no%]gcc_enums
The type of an enum will be a signed type if and only if at
least one enumerator has a negative value. Otherwise the enum
will be an unsigned type. Normally that means enums will be of
type unsigned int. However, if the value is too large to be
represented as a signed or unsigned int, then the type of the
enum will be signed or unsigned long long for -m32, or signed
or unsigned long for-m64. The default is no%gcc_enums where an
enum is a signed int.
[no%]iddollar
Allow a dollar symbol ($) as a noninitial identifier character.
The default is no%iddollar.
[no%]mergestrings
(SPARC) Causes the compiler to put string literals and other
suitable const or read-only data into a special section of the
binary where the linker removes duplicate strings.
The default is -features=no%mergestrings, and duplicate strings
are not removed.
-features=mergestrings is only effective when -features=const‐
strings is also in effect.
[no%]typeof
Enables/disables recognition of the typeof operator. The typeof
operator returns the type of its argument (either an expression
or a type). It is specified syntactically like the sizeof oper‐
ator, but it behaves semantically like a type defined with
typedef. Accordingly, it can be used anywhere a typedef can be
used. For example, it can be used in a declaration, a cast, or
inside of a sizeof or typeof. The default is -features=typeof.
[no%]zla
Allow an array to be declared with a size of 0, which is other‐
wise not allowed. The default is no%zla.
%none
The option -features=%none is deprecated and should be replaced
by -features=no% followed by the suboption.
Examples:
typeof(int) i;/* declares variable "i" to be type int*/
typeof(i+10) j;/* declares variable "j" to be type int,
the type of the expression */
i = sizeof(typeof(j)); /* sizeof returns the size of
the type associated with variable "j" */
int a[10];
typeof(a) b;/* declares variable "b" to be array of
size 10 */
The typeof operator can be especially useful in macro definitions,
where arguments may be of arbitrary type. For example:
#define SWAP(a,b)
{ typeof(a) temp; temp = a; a = b; b = temp; }
-fexceptions, -fno-exceptions
Generates (does not generate) extra code needed to propagate excep‐
tions. You might need to enable this option when compiling C code
that needs to interoperate properly with exception handlers written
in C++ using any of their gcc compatibility modes. For more infor‐
mation, see -std=v in Oracle Developer
Studio 12.6: C++ User's Guide.
The -fexceptions/-fno-exceptions flags are not available on x86
with the -m32 option.
-flags
Same as -xhelp=flags. Prints a one-line summary of available
options.
-flteval[={any|2}]
(Obsolete) The -flteval flag is obsolete and should no longer be
used.
(x86) Use this option to control how floating point expressions are
evaluated.
2 Floating point expressions are evaluated as long dou‐
ble.
any Floating point expressions are evaluated depending on
the combination of the types of the variables and con‐
stants that make up an expression.
-flteval=2 can no longer be used with any -xarch value. Specifying
-flteval=2 will result in a error message.
For more information, see 'Precision of Floating Point Evaluators'
in appendix E of the Oracle Developer Studio
12.6:
C User's Guide.
-fma[={none|fused}]
Enables automatic generation of floating-point fused multiply-add
instructions. -fma=none disables generation of these instructions.
-fma=fused allows the compiler to attempt to find opportunities to
improve the performance of the code by using floating-point fused
multiply-add instructions.
The default is -fma=none.
The minimum architecture requirement is -xarch=sparcfmaf on SPARC
and -xarch=avx2 on x86 to generate fused multiply-add instructions.
The compiler marks the binary program if fused multiply-add
instructions are generated in order to prevent the program from
executing on platforms that do not support fused multiply-add
instructions. When the minimum architecture is not used, then
-fma=fused has no affect.
Fused multiply-add instructions eliminate the intermediate rounding
step between the multiply and add. Consequently, programs may pro‐
duce different results when compiled with -fma=fused although pre‐
cision will tend to increase rather than decrease.
-fnonstd
Macro for -fns and -ftrap=common.
-fno-common
Places tentative definitions in .bss instead of .common.
Tentative definition are file scope uninitialized declarations
without extern. Examples:
int i;
long *lp;
Variables placed in .common are resolved to a single object by the
linker. Variables placed in .bss must be unique. So multiple ten‐
tative definitions can lead to linker errors about multiply defined
symbols.
-fnoshort-enums
Cancels out all -fshort-enums flags that appear earlier on the cc
command line. Whichever option (-fshort-enums or -fnoshort-enums)
occurs last on the command line takes effect.
-fno-strict-aliasing
-fno-strict-aliasing is equivalent to -xalias_level=any
-fns[=[no|yes]]
For SPARC, selects the SPARC nonstandard floating-point mode.
For x86, selects SSE flush-to-zero mode and, where available,
denormals-are-zero mode. This option causes subnormal results to be
flushed to zero on x86. Where available, this option also causes
subnormal operands to be treated as zero. This option has no effect
on traditional x86 floating-point operations that do not utilize
the SSE or SSE2 instruction set.
The default, -fns=no, is standard floating-point mode.
Optional use of =yes or =no provides a way of toggling the -fns
flag following some other macro flag that includes -fns, such as
-fast.
-fns is the same as -fns=yes. -fns=yes selects non-standard float‐
ing-point. -fns=no selects standard floating-point.
On some SPARC systems, the nonstandard floating point mode disables
"gradual underflow", causing tiny results to be flushed to zero
rather than producing subnormal numbers. It also causes subnormal
operands to be silently replaced by zero. On those SPARC systems
that do not support gradual underflow and subnormal numbers in
hardware, use of this option can significantly improve the perfor‐
mance of some programs.
When nonstandard mode is enabled, floating point arithmetic may
produce results that do not conform to the requirements of the IEEE
754 standard. See the Numerical Computation Guide for more informa‐
tion.
On SPARC systems, this option is effective only if used when com‐
piling the main program.
-fopenmp
Same as -xopenmp=parallel.
-fprecision=p
(x86) Initializes the rounding precision mode bits in the Floating-
point Control Word to p, which is one of single (24 bits), double
(53 bits), or extended (64 bits) respectively. The default float‐
ing-point rounding-precision mode is extended.
Note that on x86, only the precision, not exponent, range is
affected by the setting of floating-point rounding precision mode.
This option is effective only on x86 systems and only if used when
compiling the main program, but is ignored if compiling for 64-bit
platforms (-m64), or SSE2-enabled processors (-xarch=sse2). -fpre‐
cision is ignored on SPARC platforms.
-fround=r
Sets the IEEE 754 rounding mode that is established at runtime dur‐
ing the program initialization.
r must be one of: nearest, tozero, negative, positive.
The default is -fround=nearest.
The meanings are the same as those for the ieee_flags subroutine.
When r is tozero, negative, or positive, this flag causes the
rounding direction mode to be set to round-to-zero, round-to-nega‐
tive-infinity, or round-to-positive-infinity respectively when a
program begins execution. When r is nearest or the -fround flag is
not used, the rounding direction mode is not altered from its ini‐
tial value (round-to-nearest by default).
This option is effective only if used when compiling the main pro‐
gram.
Note that compiling with -xvector or -xlibmopt require default
rounding. Programs that link with libraries compiled with either
-xvector or -xlibmopt or both must ensure that default rounding is
in effect.
-fshort-enums
Sets the type of an enum to that of the smallest type capable of
holding all of the enumerator values. A signed type is used if and
only if at least one of the enumerators has a negative value. An
enum with this option in effect could become of type signed char,
unsigned char, signed short or unsigned short. Otherwise, the enum
type will be signed or unsigned as appropriate based on the enumer‐
ator values.
-fsimple[=n]
Allows the optimizer to make simplifying assumptions concerning
floating-point arithmetic.
The compiler defaults to -fsimple=0. Specifying -fsimple is equiva‐
lent to -fsimple=1.
If n is present, it must be 0, 1, or 2.
-fsimple=0
Permits no simplifying assumptions. Preserves strict IEEE 754
conformance.
-fsimple=1
Allows conservative simplifications. The resulting code does
not strictly conform to IEEE 754.
With -fsimple=1, the optimizer can assume the following:
o The IEEE 754 default rounding/trapping modes do not
change after process initialization.
o Computations producing no visible result other than
potential floating- point exceptions may be deleted
o Computations with Infinity or NaNs as operands need
not propagate NaNs to their results. For example,
x*0 may be replaced by 0.
o Computations do not depend on sign of zero.
With -fsimple=1, the optimizer is not allowed to
optimize completely without regard to roundoff or
exceptions. In particular, a floating-point computa‐
tion cannot be replaced by one that produces differ‐
ent results with rounding modes held constant at
runtime.
-fsimple=2
Includes all the functionality of -fsimple=1, and also enables
use of SIMD instructions to compute reductions when -xvec‐
tor=simd is in effect.
Also permits aggressive floating point optimizations that may
cause many programs to produce different numeric results due to
changes in rounding. For example, -fsimple=2 permits the opti‐
mizer to attempt replace all computations of x/y in a given
loop with x*z, where x/y is guaranteed to be evaluated at least
once in the loop, z=1/y, and the values of y and z are known to
have constant values during execution of the loop.
-fsimple=2 allows fp-transformations which may introduce fp
exceptions.
See also: Techniques for Optimizing Applications: High Performance
Computing by Rajat Garg and Ilya Sharapov for a more
detailed explanation of how optimization can impact precision. See
also articles on performance and precision on the OTN Oracle Devel‐
oper Studio website: oracle.com/technetwork/server-storage/develop‐
erstudio/
-fsingle
(-Xt and -Xs modes only) By default -Xs and -Xt follow the K&R C
rules for float expressions, by promoting them to double and evalu‐
ating them in double precision. Use the -fsingle flag when specify‐
ing -Xs or -Xt to cause the compiler to evaluate float expressions
as single precision.
-fstore
(x86) Causes the compiler to convert the value of a floating-point
expression or function to the type on the left-hand side of an
assignment, when that expression or function is assigned to a vari‐
able, or when the expression is cast to a shorter floating-point
type, rather than leaving the value in the register. Due to round‐
offs and truncation, the results may be different from those gener‐
ated from the register value. This is the default mode. To turn off
this option, use the -nofstore option.
-fstrict-aliasing
-fstrict-aliasing is equivalent to -xalias_level=strict
-ftrap[=t[,t...] ]
Sets the IEEE 745 trapping mode in effect at startup but does not
install a SIGFPE handler. You can use ieee_handler(3M) or
fex_set_handling(3M) to simultaneously enable traps and install a
SIGFPE handler. If you specify more than one value, the list is
processed sequentially from left to right.
Use prefix no% to remove a suboption from %all or common.
[no%]division Trap on division by zero.
[no%]inexact Trap on inexact result.
[no%]invalid Trap on invalid operation.
[no%]overflow Trap on overflow.
[no%]underflow Trap on underflow.
%all Trap on all the above.
%none Trap on none of the above.
common Trap on invalid, division by zero, and over‐
flow.
The default is -ftrap=%none.
Note that the [no%] form of the option is used only to modify the
meanings of the %all or common value and must be used with one of
these values, as shown in the example. The [no%] form of the option
by itself does not explicitly cause a particular trap to be dis‐
abled.
Example: -ftrap=%all,no%inexact means set all traps, except inex‐
act.
If you compile one routine with -ftrap=t, compile all routines of
the program with the same -ftrap=t option; otherwise, you can get
unexpected results.
Use the -ftrap=inexact trap with caution, as it will result in the
trap being issued whenever a floating-point value cannot be repre‐
sented exactly. For example, the following statement may generate
this condition:
x = 1.0 / 3.0;
-fvisibility=v
The -fvisibility=v option is equivalent to the -xldscope option as
follows:
-fvisibility=default -fvisibility=default is equivalent to
-xldscope=global
-fvisibility=internal -fvisibility=internal is equivalent to
-xldsdope=hidden
-fvisibility=protected -fvisibility=protected is equivalent to
-xldscope=symbolic
-fvisibility=hidden -fvisibility=hidden is equivalent to
-xldscope=hidden
-G
Produce a shared object rather than a dynamically linked exe‐
cutable. This option is passed to ld and cannot be used with the
-dn option.
When you use the -G option, the compiler does not pass any default
-l options to ld. If you want the shared library to have a depen‐
dency on another shared library, you must pass the necessary -l
option on the command line.
If you are creating a shared object by specifying -G along with
other compiler options that must be specified at both compile time
and link time, make sure that those same options are also specified
when you link with the resulting shared object.
When you create a shared object, all the object files that are com‐
piled for 64-bit SPARC architectures must also be compiled with an
explicit -xcode value as documented under the description of
-xcode.
For more information, see the -G option.
-g
See -g[n].
-g[n]
Produce additional symbol table information for dbx(1) and the Per‐
formance Analyzer analyzer(1).
If you specify -g, and the optimization level is -xO3 or lower, the
compiler provides best-effort symbolic information with almost full
optimization. Tail-call optimization and back-end inlining are dis‐
abled.
If you specify -g and the optimization level is -xO4, the compiler
provides best-effort symbolic information with full optimization.
Compile with the -g option to use the full capabilities of the Per‐
formance Analyzer. While some performance analysis features do not
require -g, you must compile with -g to view annotated source, some
function level information, and compiler commentary messages. See
the analyzer(1) man page and the Performance
Analyzer manual for more information.
The commentary messages that are generated with -g describe the
optimizations and transformations that the compiler made while com‐
piling your program. Use the er_src(1) command to display the mes‐
sages, which are interleaved with the source code.
If you compile and link your program in separate steps, then
including the -g option in one step and excluding it from the other
step will not affect the correctness of the program, but it will
affect the ability to debug the program. Any module that is not
compiled with -g but is linked with -g will not be prepared prop‐
erly for debugging. Note that compiling the module that contains
the function main with the -g option is usually necessary for
debugging.
-g is implemented as a macro that expands to various other, more
primitive, options. See -xdebuginfo for the details of the expan‐
sions.
Values:
-g Produce standard debugging information.
-gnone Do not produce any debugging information. This is the
default.
-g1 Produce file and line number as well as simple parame‐
ter information that is considered crucial during
post-mortem debugging.
-g2 Same as -g.
-g3 Produce additional debugging information, which cur‐
rently consists only of macro definition information.
This added information can result in an increase in
the size of the debug information in the resulting .o
and executable when compared to using only -g.
-gz[=cmp-type]
Equivalent of specifying -xcompress=debug -xcom‐
press_format=cmp-type.
-gz with no suboption is equivalent to -gz=zlib.
-H
Prints, one per line, the path name of each file included during
the current compilation to standard error.
-h name
Assigns a name to a shared dynamic library; allows you to keep dif‐
ferent versions of a library.
In general, the name after -h should be the same as the file name
given in the -o option. The space between -h and name is optional.
The linker assigns the specified name to the library and records
the name in the library file as the intrinsic name of the library.
If there is no -h name option, then no intrinsic name is recorded
in the library file.
When the runtime linker loads the library into an executable file,
it copies the intrinsic name from the library file into the exe‐
cutable, into a list of needed shared library files. Every exe‐
cutable has such a list. If there is no intrinsic name of a shared
library, then the linker copies the path of the shared library file
instead.
-I[-|dir]
-Idir adds dir to the list of directories that are searched for
#include files. -I values accumulate from left to right.
o For include statements of the form #include <foo.h>, the
preprocessor searches for the header file in the follow‐
ing order:
1. The directories named with the -I option, if any.
2. The compiler and system standard directories, usu‐
ally /usr/include.
o For include statements of the form #include "foo.h", the
compiler searches the directories in the following
order:
1. The current directory (that is, the directory that
contains the file which contains the include state‐
ment itself.
2. The directories named with -I options, if any.
3. The compiler and system standard directories, usu‐
ally /usr/include.
-I- changes the include-file search rules to the following:
o The compiler never searches the current directory,
unless the directory is listed explicitly in a -I direc‐
tive. This effect applies even for include statements of
the form #include "foo.h".
o For include files of the form #include "foo.h", search
the directories in the following order:
1. The directories named with -I options (both before
and after -I-).
2. The compiler and system standard directories, usu‐
ally /usr/include.
o For include files of the form #include <foo.h>, search
the directories in the following order:
1. The directories named with the -I options that
appear after -I- (that is, the compiler does not
search the -I directories that appear before -I-).
2. The compiler and system standard directories, usu‐
ally /usr/include.
Only the first -I- option on the command line works as described
above.
-Idir looks in dir, prior to usr/include, for included files whose
names do not begin with slash (/). Directories for multiple -I
options are searched in the order specified.
Warnings:
Never specify the compiler installation area, /usr/include, /lib,
/usr/lib, as search directories.
-i
Ignores the LD_LIBRARY_PATH and LD_LIBRARY_PATH_64 settings.
-include filename
This option causes the compiler to treat filename as if it appears
in the first line of a primary source file as a #include preproces‐
sor directive.
The first directory the compiler searches for filename is the cur‐
rent working directory and not the directory containing the main
source file, as is the case when a file is explicitly included. If
the compiler cannot find filename in the current working directory,
it searches the normal directory paths. If you specify multiple
-include options, the files are included in the order they appear
on the command line.
-KPIC
(SPARC) (Obsolete) You should not use this option. Use -xcode=pic32
instead. For a complete list of obsolete options and flags, see the
Oracle Developer Studio
12.6:
C User's Guide.
(x86) -KPIC is identical to -Kpic on x86 architectures.
-Kpic
(SPARC) (Obsolete) You should not use this option. Use -xcode=pic13
instead. For a complete list of obsolete options and flags, see the
Oracle Developer Studio
12.6:
C User's Guide.
(x86) Produces position-independent code. Use this option to com‐
pile source files when building a shared library. Each reference to
a global datum is generated as a dereference of a pointer in the
global offset table. Each function call is generated in pc-relative
addressing mode through a procedure linkage table.
-keeptmp
Retains temporary files created during compilation, instead of
deleting them automatically.
-Ldir
Adds dir to the list of directories searched for libraries by ld.
This option and its arguments are passed to ld.
Warnings:
Never specify the compiler installation area, /usr/include, /lib,
/usr/lib, as search directories.
-lname
Links with object library libname.so or libname.a (for ld(1)). The
order of libraries in the command line is important, as symbols are
resolved from left to right. This option must follow the source‐
file.
-library=sunperf
Link with the Oracle Developer Studio supplied performance
libraries.
-m32|-m64
Specifies the data type model for the compiled binary object.
Use -m32 to create 32-bit executables and shared libraries. Use
-m64 to create 64-bit executables and shared libraries.
Object files or libraries compiled with -m32 cannot be linked with
object files or libraries compiled with -m64.
When compiling applications with large amounts of static data using
-m64, -xmodel=medium may also be required. Be aware that some Linux
platforms do not support the medium model.
Modules that are compiled with -m32|-m64 must also be linked with
-m32|-m64. For a complete list of compiler options that must be
specified at both compile time and at link time, see the Oracle
Developer Studio
12.6:
C User's Guide.
Note that in previous compiler releases, the data type model, ILP32
or LP64, was implied by the choice of the instruction set with
-xarch. Starting with the Sun Studio 12 compilers, this is no
longer the case. On most platforms, just adding -m64 to the command
line is sufficient to create 64-bit objects.
-m64 is the default, except on Oracle Solaris 10 and 11 where -m32
is the default.
See also: -xarch.
-mc
Removes duplicate strings from the .comment section of an object
file. When you use the -mc flag, mcs -c is invoked.
-misalign
(SPARC) (Obsolete) You should not use this option. Use the -xmema‐
lign=1i option instead. For a complete list of obsolete options and
flags, see the Oracle
Developer Studio
12.6:
C User's Guide.
-misalign2
(SPARC) (Obsolete) You should not use this option. Use the -xmema‐
lign=2i option instead. For a complete list of obsolete options and
flags, see the Oracle
Developer Studio
12.6:
C User's Guide.
-mr[,string]
-mr removes all strings from the .comment section of an object
file. When you use the -mr flag, mcs -d is invoked.
-mr,string removes all strings from the .comment section and
inserts string in the .comment section of the object file. If
string contains embedded blanks, it must be enclosed in quotation
marks. If string is null, the .comment section will be empty. When
you use this flag, mcs -d -a is invoked.
-mt[={yes|no}]
Use this option to compile and link multithreaded code.
This option passes -D_REENTRANT to the preprocessor.
-mt=yes is the default behavior of the compiler. -mt is equivalent
to -mt=yes. If this behavior is not desired use the option -mt=no.
The -xopenmp option (for using the OpenMP shared-memory paral‐
lelization API) includes -mt=yes automatically.
Use this option consistently. If you compile and link one transla‐
tion unit with -mt, you must compile and link all units of the pro‐
gram with -mt.
To determine which system support libraries will be linked by
default, compile with the -dryrun option.
See also: -xnolib
-native
This option is a synonym for -xtarget=native.
-nofstore
(x86) Cancel -fstore on command line. Cancels forcing expressions
to have the precision of the destination variable as invoked by
-fstore.
-nofstore is invoked by -fast. The normal default is -fstore.
-O
Use default optimization level -xO3. However, -xO3 may be inappro‐
priate for programs that rely on all variables being automatically
considered volatile. Typical programs that might have this assump‐
tion are device drivers and older multi-threaded applications that
implement their own synchronization primitives. The work around is
to compile with -xO2 instead of -O.
-On
The same as -xOn.
-o filename
Names the output file filename, instead of the default a.out. file‐
name cannot be the same as sourcefile since cc does not overwrite
the source file.
filename must have an appropriate suffix. When used with -c, file‐
name specifies the target .o object file; with -G it specifies the
target .so library file. This option and its argument are passed to
ld.
-P
Preprocesses only the named C files and leaves the result in corre‐
sponding files suffixed .i. The output will not contain any prepro‐
cessing line directives, unlike -E.
-p
(Obsolete) See -xpg.
-pedantic{=[yes|no]}
Strict conformance with errors/warnings for non-ANSI constructs.
The -std flag can be used to specify which ANSI standard is in
effect. The -Xc, -Xa, -Xt, -Xs, and -xc99 flags cannot be specified
with the -pedantic flag. Doing so will result in an error being
issued by the compiler.
The option -pedantic is equivalent to pedantic=yes.
-pedantic=no is the default when no -pedantic option is specified.
-preserve_argvalues[=simple|none|complete]
(x86) Saves copies of register-based function arguments in the
stack.
When none is specified or if the -preserve_argvalues option is not
specified on the command line, the compiler behaves as usual.
When simple is specified, up to six integer arguments are saved.
When complete is specified, the values of all function arguments in
the stack trace are visible to the user in the proper order.
The values are not updated during the function lifetime on assign‐
ments to formal parameters.
-Qoption phase
option[,option...]
Passes option to the compilation phase.
To pass multiple options, specify them in order as a comma-sepa‐
rated list. Options that are passed to components with -Qoption can
be reordered. Options that the driver recognizes are kept in the
correct order. Do not use -Qoption for options that the driver
already recognizes.
The following table shows the possible values for phase and the
corresponding argument for -Wc,arg
Qoption
phase W<c>
===== ====
fbe a Assembler: (fbe), (gas)
cg c C code generator: (cg)(SPARC)
driver d cc driver (1)
ld l Link editor (ld)
mcs m mcs
ipo O (Capital letter 'O') Interprocedural optimizer
postopt o Postoptimizer
cpp p Preprocessor (cpp)
ube u C code generator (ube), (x86)
acomp 0 (The number zero) Compiler acomp
iropt 2 Optimizer: (iropt)
previse 3 Static error checking: (previse)
See also: -Wc,arg
-Q[y|n]
Emits or does not emit identification information to the output
file. If y is used, identification information about each invoked
compilation tool will be added to the output files (the default
behavior). This can be useful for software administration. -Qn sup‐
presses this information.
-qp
Same as -p.
-Rdir[:dir...]
A colon-separated list of directories used to specify library
search directories to the runtime linker. If present and not null,
it is recorded in the output object file and passed to the runtime
linker.
If both LD_RUN_PATH and the -R option are specified, the -R option
takes precedence.
-S
Compiles, but does not assemble or link edit the named C files. The
assembler-language output is left in corresponding files suffixed
.s.
-s
Removes all symbolic debugging information from the output object
file. This option is passed to ld(1). This option cannot be speci‐
fied with -g.
-shared
Produces a shared object rather than a dynamically-linked exe‐
cutable. This option is passed to ld (as -G), and cannot be used
with the -dm option.
When you use the -shared option, the compiler passes default -l
options to ld, which are the same options that would be passed if
you created an executable.
If you are creating a shared object by specifying the -shared
option along with other compiler options that are specified at both
compile time and link time, make sure that that those options are
also specified when you link with the resulting shared object.
When you create a shared object, all the object files that are com‐
piled for 64-bit SPARC architectures must also be compiled with an
explicit -xcode value as documented under the description of
-xcode.
For more information, see the -G option.
-staticlib=[no%]sunperf
When used with -library=sunperf, -staticlib=sunperf will link stat‐
ically with the Sun performance libraries. By default and when
-library=no%sunperf is specified, -library=sunperf results in
dynamic linking of the Sun performance libraries.
For compatibility with CC, %all and %none are also accepted values
for -staticlib, where %all is equivalent to sunperf and %none is
equivalent to no%sunperf.
-std=value
C language standard selection flag.
value is required and defined as one of the following:
c89 Equivalent to c90.
c90 C source language accepted is
that defined by the ISO C90
standard.
c99 C source language accepted is
that defined by the ISO C99
standard.
c11 C source language accepted is
that defined by the ISO C11
standard.
gnu89 Equivalent to gnu90.
gnu90 Allow for extensions with ISO
C90.
gnu99 Allow for extensions with ISO
C99.
gnu11 Allow for extensions with ISO
C11.
-std=iso9899:1990 Equivalent to -std=c90.
-std=iso9899:199409 Equivalent to -std=c90.
-std=c9x Equivalent to -std=c99.
-std=iso9899:1999 Equivalent to -std=c99.
-std=iso9899:199x Equivalent to -std=c99.
-std=c1x Equivalent to -std=c11.
-std=iso9899:2011 Equivalent to -std=c11.
-std=gnu9x Equivalent to -std=gnu99.
-std=gnu1x Equivalent to -std=gnu11.
-std defaults to c11.
The macro __STRICT_ANSI__ is predefined when the -std=c89,
-std=c90, -std=c99, or -std=c11 option is used. Some header files
may use this macro to restrict the declaration of functions and
definition of macros to those defined by the ISO C standard.
When any of the flags -Xc, -Xa, -Xt, or -xtransition are specified,
the -std default is not in effect and the compiler defaults to
-xc99=all,no_lib. When -Xs is specified, the -std default is not in
effect and the compiler defaults to -xc99=none. When -xc99 is spec‐
ified, the -std default is not in effect and the compiler is as
specified by the -xc99 flag.
The -Xc, -Xa, -Xt, -Xs, and -xc99 flags cannot be used if the -std
flag has been specified. Doing so will result in an error being
issued by the compiler.
If you compile and link in separate steps you must use the same
values for -std flag in both steps.
-temp=path
Defines the directory for temporary files.
This option sets path as the directory for the temporary files
which are generated during the compilation process. The compiler
gives precedence to the value set by -temp over the value of
TMPDIR.
See also: -keeptmp
-traceback[={%none|common|signals_list}]
Issue a stack trace if a severe error occurs in execution.
The -traceback option causes the executable to issue a stack trace
to stderr, dump core, and exit if certain signals are generated by
the program. If multiple threads generate a signal, a stack trace
will only be produced for the first one.
To use traceback, add the -traceback option to the compiler command
line when linking. The option is also accepted at compile-time but
is ignored unless an executable binary is generated. Using -trace‐
back with -G to create a shared library is an error.
%none or none
Disables traceback.
common
Specifies that a stack trace should be issued if any of a set
of common signals is generated: sigill, sigfpe, sigbus,
sigsegv, and sigabrt.
signals_list
Specifies a comma-separated list of names of signals which
should generate a stack trace, in lower case. The following
signals (those that cause the generation of a core file) can be
caught: sigquit, sigill, sigtrap, sigabrt, sigemt, sigfpe, sig‐
bus, sigsegv, sigsys, sigxcpu, and sigxfsz.
Any of these can be preceeded with no% to disable catching the
signal.
For example: -traceback=sigsegv,sigfpe will produce a stack
trace and core dump if either sigsegv or sigfpe is generated.
If the option is not specified, the default is -traceback=%none.
-traceback without any = sign implies -traceback=common.
If the core dump is not wanted, users may set the coredumpsize
limit to zero using:
% limit coredumpsize 0
The -traceback option has no effect on runtime performance.
-Uname
Causes any definition of name to be undefined. This option removes
any initial definition of the preprocessor symbol name created by
-D on the same command line including those placed by the command-
line driver.
-U has no effect on any preprocessor directives in source files.
You can supply multiple -U options on the command line.
If the same name is specified for both -D and -U, name is not
defined, regardless of the order of the options.
-V
Causes each invoked tool to print its version information on the
standard error output.
-v
Causes the compiler to perform more and stricter semantic checks,
and to enable certain lint-like checks on the named C files.
-Wc,arg
Passes the argument arg to c. Each argument must be separated from
the preceding by only a comma. (A comma can be part of an argument
by escaping it by an immediately preceding backslash (\) character;
the backslash is removed from the resulting argument.) All -W argu‐
ments are passed after the regular command-line arguments.
c can be one of the following:
a Assembler: (fbe), (gas)
c C code generator: (cg)(SPARC)
d cc driver (1)
l Link editor (ld)
m mcs
O (Capital letter 'O') Interprocedural optimizer
o Postoptimizer
p Preprocessor (cpp)
u C code generator (ube), (x86)
0 (The number zero) Compiler (acomp)
2 Optimizer: (iropt)
3 Static error checking: (previse)
(1) Note: You cannot use -Wd to pass the cc options listed in this
man page to the C compiler.
For example, -Wa,-o,objfile passes -o and objfile to the assembler,
in that order; also -Wl,-I,name causes the linking phase to over‐
ride the default name of the dynamic linker, /usr/lib/ld.so.1.
The order in which the argument(s) are passed to a tool with
respect to the other specified command line options may change.
-w
Suppress compiler warning messages.
The option is equivalent to the option -erroff=%all.
-X[c|a|t|s]
(Obsolete) The -Xc, -Xa, -Xt, -Xs options will be removed in a
future release.
The -Xc, -Xa, -Xt, and -Xs flags cannot be used if the -std or
-xlang flag has been specified.
When not using the -std flag, the -X options specify varying
degrees of compliance to the 1990 and 1999 ISO C standard. The
value of -xc99 affects which version of the ISO C standard the -X
option applies.
c (conformance)
Strictly conformant ISO C, without K&R C compatibility exten‐
sions. The compiler issues errors and warnings for programs
that use non-ISO C constructs.
(Obsolete) The -Xc option will be removed in a future release.
Use the -std flag to choose the C language dialect, and then
use -pedantic in place of -Xc to specify strict conformance.
a
ISO C plus K&R C compatibility extensions, with semantic
changes required by ISO C. Where K&R C and ISO C specify dif‐
ferent semantics for the same construct, the compiler uses the
ISO C interpretation. If the -Xa option is used in conjunction
with the -xtransition option, the compiler issues warnings
about the different semantics.
t (transition) (Obsolete)
The -Xt option will be removed in a future release. It is rec‐
ommended that C code that requires -Xt to build and compile
correctly be migrated to conform with at least the C99 dialect
of the ISO C standard, that is, compilable with -std=c99.
This option uses ISO C plus K&R C compatibility extensions
without semantic changes required by ISO C. Where K&R C and ISO
C specify different semantics for the same construct, the com‐
piler uses the K&R C interpretation. If you use the -Xt option
in conjunction with the -xtransition option, the compiler
issues warnings about the different semantics.
s (K&R C) (Obsolete)
The -Xs option will require the -E in a future release. It is
recommended that C code that requires -Xs to build and compile
correctly be migrated to conform with at least the C99 dialect
of the ISO C standard, that is, compilable with -std=c99.
The compiler tries to warn about all language constructs that
have differing behavior between Oracle Developer Studio ISO C
and the K&R C.
All warning messages about differing behavior can be eliminated
through appropriate coding; for example, use of casts can eliminate
the integral promotion change warnings.
-Xlinker arg
Passes arg to linker, ld(1).
-xaddr32[={yes|no}]
(x86/x64) The -xaddr32=yes compilation flag restricts the resulting
executable or shared object to a 32-bit address space.
An executable that is compiled in this manner results in the cre‐
ation of a process that is restricted to a 32-bit address space.
When -xaddr32=no is specified a usual 64 bit binary is produced.
If the -xaddr32 option is not specified, -xaddr32=no is assumed.
If only -xaddr32 is specified -xaddr32=yes is assumed.
This option is only applicable to -m64 compilations and only on
Oracle Solaris platforms supporting SF1_SUNW_ADDR32 software capa‐
bility.
Since Linux kernel does not support addres space limitation this
option is not available on Linux. The -xaddr32 option is ignored on
Linux.
When linking, if a single object file was compiled with
-xaddr32=yes the whole output file is assumed to be compiled with
-xaddr32=yes.
A shared object that is restricted to a 32-bit address space must
be loaded by a process that executes within a restricted 32-bit
mode address space.
For more information refer to the SF1_SUNW_ADDR32 software capabil‐
ities definition, described in the Linker and Libraries Guide.
-xalias_level[=a]
a must be one of:any, basic, weak, layout, strict, std, strong. Use
this flag to place the indicated alias level into effect for the
whole translation unit. In other words, the alias level you select
is applied to all of the memory references in the translation unit.
If you do not supply -xalias_level, the compiler assumes
-xalias_level=any. If you supply -xalias_level without a value, the
compiler assumes -xalias_level=layout.
any
The compiler assumes that all memory references can alias at
this level. There is no type-based alias anaylysis.
basic
If you use the -xalias_level=basic option, the compiler assumes
that memory references that involve different C basic types do
not alias each other. The compiler also assumes that references
to all other types can alias each other as well as any C basic
type. The compiler assumes that references using char * can
alias any other type.
weak
If you use the -xalias_level=weak option, the compiler assumes
that any structure pointer can point to any structure type. Any
structure or union type that contains a reference to any type
that is either referenced in an expression in the source being
compiled or is referenced from outside the source being com‐
piled, must be declared prior to the expression in the source
being compiled.
You can satisfy this restriction by including all the header
files of a program that contain types that reference any of the
types of the objects referenced in any expression of the source
being compiled.
At the level of -xalias_level=weak, the compiler assumes that
memory references that involve different C basic types do not
alias each other. The compiler assumes that references using
char * alias memory references that involve any other type.
layout
The compiler assumes that memory references that involve types
with the same sequence of types in memory can alias each other.
The compiler assumes that two references with types that do not
look the same in memory do not alias each other. The compiler
assumes that any two memory accesses through different struct
types alias if the initial members of the structures look the
same in memory. However, at this level, you should not use a
pointer to a struct to access some field of a dissimilar struct
object that is beyond any of the common initial sequence of
members that look the same in memory between the two structs.
This is because the compiler assumes that such references do
not alias each other.
At the level of -xalias_level=layout the compiler assumes that
memory references that involve different C basic types do not
alias each other. The compiler assumes that references using
char * can alias memory references involving any other type.
strict
The compiler assumes that memory references, that involve types
such as structs or unions, that are the same when tags are
removed, can alias each other. Conversely, the compiler assumes
that memory references involving types that are not the same
even after tags are removed do not alias each other. However,
any structure or union type that contains a reference to any
type that is part of any object referenced in an expression in
the source being compiled, or is referenced from outside the
source being compiled, must be declared prior to the expression
in the source being compiled.
You can satisfy this restriction by including all the header
files of a program that contain types that reference any of the
types of the objects referenced in any expression of the source
being compiled.
At the level of -xalias_level=strict the compiler assumes that
memory references that involve different C basic types do not
alias each other. The compiler assumes that references using
char * can alias any other type.
std
The compiler assumes that types and tags need to be the same to
alias, however, references using char * can alias any other
type. This rule is the same as the restrictions on the derefer‐
encing of pointers that are found in the 1999 ISO C standard.
Programs that properly use this rule will be very portable and
should see good performance gains under optimization.
strong
The same restrictions apply as at the std level, but addition‐
ally, the compiler assumes that pointers of type char * are
used only to access an object of type char. Also, the compiler
assumes that there are no interior pointers. An interior
pointer is defined as a pointer that points to a member of a
struct.
See also: -xprefetch_auto_type
-xannotate[={yes|no}]
Instructs the compiler to create binaries that can later be used by
the optimization and observability tools binopt(1), code-ana‐
lyzer(1), discover(1), collect(1), and uncover(1).
The default on Oracle Solaris is -xannotate=yes. The default on
Linux is -xannotate=no. Specifying -xannotate without a value is
equivalent to -xannotate=yes.
For optimal use of the optimization and observability tools, -xan‐
notate=yes must be in effect at both compile and link time.
Compile and link with -xannotate=no to produce slightly smaller
binaries and libraries when optimization and observability tools
will not be used.
-xarch=isa
Specifies the target architecture instruction set (ISA).
This option limits the code generated by the compiler to the
instructions of the specified instruction set architecture by
allowing only the specified set of instructions. This option does
not guarantee use of any target-specific instructions. However, use
of this option can affect the portability of a binary program. See
the Notes and Warnings sections at the end of this entry.
Note: Use the -m64 or -m32 option to specify the intended data type
model, LP64 (64-bits) or ILP32 (32-bits) respectively. The -xarch
flag no longer indicates the data type model, except for compati‐
bility with previous releases, as indicated below.
Note: The compiler and linker will mark .o files and executables
that require a particular instruction set architecture (ISA) so
that the executable will not be loaded at runtime if the running
system does not support that particular ISA.
Code using _asm statements or inline templates (.il files) that use
architecture-specific instructions might require compiling with the
appropriate -xarch values to avoid compilation errors.
If you compile and link in separate steps, make sure you specify
the same value for -xarch in both steps.
Values for all platforms:
generic This option uses the instruction set common to most
processors. This is the default and is equivalent to
-xarch=sse2 on x86 platforms and -xarch=sparcvis2 on
SPARC platforms.
native Compile for good performance on this system.
The compiler chooses the appropriate setting for the
current system processor it is running on.
Values specific to SPARC platforms:
sparc
Compile for the SPARC-V9 ISA.
Compile for the V9 ISA, but without the Visual Instruction Set
(VIS), and without other implementation-specific ISA exten‐
sions. This option enables the compiler to generate code for
good performance on the V9 ISA.
sparcvis
Compile for the SPARC-V9 ISA plus VIS.
Compile for SPARC-V9 plus the Visual Instruction Set (VIS) ver‐
sion 1.0, and with UltraSPARC extensions. This option enables
the compiler to generate code for good performance on the
UltraSPARC architecture.
sparcvis2
Compile for the SPARC-V9 ISA with UltraSPARC III extensions.
Enables the compiler to generate object code for the UltraSPARC
architecture, plus the Visual Instruction Set (VIS) version
2.0, and with UltraSPARC III extensions.
sparcvis3
Compile for the SPARC-V9 ISA with UltraSPARC III and VIS 3
extensions.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, including the
Visual Instruction Set (VIS) version 1.0, the UltraSPARC-III
extensions, including the Visual Instruction Set (VIS) version
2.0, the fused multiply-add instructions, and the Visual
Instruction Set (VIS) version 3.0
sparcfmaf
Compile for the sparcfmaf version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, including the
Visual Instruction Set (VIS) version 1.0, the UltraSPARC-III
extensions, including the Visual Instruction Set (VIS) version
2.0, and the SPARC64 VI extensions for floating-point multiply-
add.
Note that you must use -xarch=sparcfmaf in conjunction with
-fma=fused and some optimization level to get the compiler to
attempt to find opportunities to use the multiply-add instruc‐
tions automatically.
sparc4
Compile for the SPARC4 version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, which includes
VIS 1.0, the UltraSPARC-III extensions, which includes VIS2.0,
the fused floating-point multiply-add instructions, VIS 3.0,
and SPARC4 instructions.
sparc4b
Compile for the SPARC4B version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, which includes
VIS 1.0, the UltraSPARC-III extensions, which includes VIS2.0,
the SPARC64 VI extensions for floating-point multiply-add, the
SPARC64 VII extensions for integer multiply-add, and the PAUSE
and CBCOND instructions from the SPARC T4 extensions.
sparc4c
Compile for the SPARC4C version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, which includes
VIS 1.0, the UltraSPARC-III extensions, which includes VIS2.0,
the SPARC64 VI extensions for floating-point multiply-add, the
SPARC64 VII extensions for integer multiply-add, the VIS3B sub‐
set of the VIS 3.0 instructions a subset of the SPARC T3 exten‐
sions, called the VIS3B subset of VIS 3.0, and the PAUSE and
CBCOND instructions from the SPARC T4 extensions.
sparc5
Compile for the SPARC5 version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the extensions, which includes VIS 1.0,
the Ultra SPARC-III extensions, which includes VIS2.0, the
fused floating-point multiply-add instructions, VIS 3.0,
SPARC4, and SPARC5 instructions.
sparcace
Compile for the sparcace version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, including the
Visual Instruction Set (VIS) version 1.0, the UltraSPARC-III
extensions, including the Visual Instruction Set (VIS) version
2.0, the SPARC64 VI extensions for floating-point multiply-add,
the SPARC64 VII extensions for integer multiply-add, and the
SPARC64 X extensions for SPARCACE floating-point.
sparcaceplus
Compile for the sparcaceplus version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, including the
Visual Instruction Set (VIS) version 1.0, the UltraSPARC-III
extensions, including the Visual Instruction Set (VIS) version
2.0, the SPARC64 VI extensions for floating-point multiply-add,
the SPARC64 VII extensions for integer multiply-add, the
SPARC64 X extensions for SPARCACE floating-point, and the
SPARC64 X+ extensions for SPARCACE floating-point.
sparcace2
Compile for the sparcace2 version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, including the
Visual Instruction Set (VIS) version 1.0, the UltraSPARC-III
extensions, including the Visual Instruction Set (VIS) version
2.0, the SPARC64 VI extensions for floating-point multiply-add,
the SPARC64 VII extensions for integer multiply-add, the
SPARC64 X extensions for SPARCACE floating-point, the SPARC64
X+ extensions for SPARCACE floating-point, and the SPARC64 XII
extensions for SPARCACE floating-point.
sparcima
Compile for the sparcima version of the SPARC-V9 ISA.
Enables the compiler to use instructions from the SPARC-V9
instruction set, plus the UltraSPARC extensions, including the
Visual Instruction Set (VIS) version 1.0, the UltraSPARC-III
extensions, including the Visual Instruction Set (VIS) version
2.0, the SPARC64 VI extensions for floating-point multiply-add,
and the SPARC64 VII extensions for integer multiply-add.
v9
Is equivalent to -m64 -xarch=sparc Legacy makefiles and scripts
that use -xarch=v9 to obtain the 64-bit data type model need
only use -m64.
v9a
Is equivalent to -m64 -xarch=sparcvis and is provided for com‐
patibility with earlier releases.
v9b
Is equivalent to -m64 -xarch=sparcvis2 and is provided for com‐
patibility with earlier releases.
Notes:
Object binary files (.o) compiled with generic, sparc, sparcvis2,
sparcvis3, sparcfmaf, and sparcima can be linked and can execute
together but can only run on a processor supporting all the
instruction sets linked.
For any particular choice, the generated executable could run much
more slowly on earlier architectures. Also, although quad-precision
floating-point instructions are available in many of these instruc‐
tion set architectures, the compiler does not use these instruc‐
tions in the code it generates.
Values specific to x86 platforms:
avx512
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, SSSE3, SSE4.1,
SSE4.2, AES, PCLMULQDQ, AVX, FSGSBASE, RDRND, F16C, AVX2, BMI1,
BMI2, LZCNT, INVPCID, FMA, ADX, RDSEED, PREFETCHW, PREFETCHWT1,
AVX512F, AVX512CDI, AVX512VLI, AVX512BW and AVX512DQ instruc‐
tions.
avx2_i
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, SSSE3, SSE4.1,
SSE4.2, AES, PCLMULQDQ, AVX, FSGSBASE, RDRND, F16C, AVX2, BMI1,
BMI2, LZCNT, INVPCID, FMA, ADX, RDSEED, PREFETCHW and
PREFETCHWT1 instructions.
avx2
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, SSSE3, SSE4.1,
SSE4.2, AES, PCLMULQDQ, AVX, FSGSBASE, RDRND, F16C, AVX2, BMI1,
BMI2, LZCNT, INVPCID, and FMA instructions.
avx_i
May use 386, pentium_pro, MMX, SSE, SSE2, SSE3, SSSE3, SSE4.1,
SSE4.2, AES, PCLMULQDQ, FSGSBASE, RDRND, and F16C instructions.
avx
May use 386, pentium_pro, MMX, SSE, SSE2, SSE3, SSSE3, SSE4.1,
SSE4.2, AES, and PCLMULQDQ instructions.
aes
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, SSSE3, SSE4.1,
SSE4.2, AES, and PCLMULQDQ instructions.
sse4_2
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, SSSE3, SSE4.1,
and SSE4.2 instructions.
sse4_1
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, SSSE3, and
SSE4.1 instructions.
ssse3
May use 386, MMX, Pentium_pro, SSE, SSE2, SSE3, and SSSE3
instructions.
sse3
May use 386, MMX, Pentium_pro, SSE, SSE2, and SSE3 instruc‐
tions.
sse2
May use 386, MMX, Pentium_pro, SSE, and SSE2 instructions.
sse
Obsolete. Use -xarch=generic instead.
ssea
May use 386, MMX, Pentium_pro, SEE, and AMD extension: 3DNow!,
3DNow! extension instructions for AMD processors.
pentium_pro
Obsolete. Use -xarch=generic instead.
generic
Uses the instruction set common to most processor.
native
Uses the instructions available on the current system processor
the compiler is running on.
Notes:
If any part of a program is compiled or linked on an x86 platform
with -m64, then all parts of the program must be compiled with one
of these options as well.
For details on the various Intel instruction set architectures
(SSE, SSE2, SSE3, SSSE3, and so on) refer to the Intel-64 and IA-32
Intel Architecture Software Developer's Manual.
Defaults:
If -xarch=isa is not specified, the defaults are: -xarch=generic on
SPARC platforms -xarch=generic on x86/x64 platforms.
Interactions:
Although this option can be used alone, it is part of the expansion
of the -xtarget option and can be used to override the -xarch value
that is set by a specific -xtarget option.
For example, -xtarget=T3 expands to -xarch=sparcvis3 -xchip=T3
-xcache=8/16/4:6144/64/24. In the following command -xarch=sparc4
overrides the -xarch=sparcvis3 that is set by the expansion of
-xtarget=T3.
example% cc -xtarget=T3 -xarch=sparc4 foo.c
Warnings:
If this option is used with optimization, the appropriate choice
can provide good performance of the executable on the specified
architecture. An inappropriate choice, however, might result in
serious degradation of performance or in in a binary program that
is not executable on all intended target platforms.
-xatomic=a
Specify which atomics support runtime library is linked.
a must be one of the following:
studio Link with the libstatomic library bundled with Oracle
Developer Studio.
gcc Link with the libatomic library in /usr/lib.
none Do not link with any atomics support library.
The option -xatomic=none is the default when neither -latomic nor
-xatomic is specified.
-latomic will be automatically translated to -xatomic=studio.
An explicit -xatomic option should override the presence of
-latomic regardless of the order on the command line. A warning
message will be emitted if the setting of -xatomic is conflict with
-latomic.
When the Oracle Solaris operating system includes a compatible
standard interface and the Linux bundled library conforms to a
standard interface, the need for the -xatomic option will be redun‐
dant.
-xautopar
Turns on automatic loop parallelization. Analyzes loops for inter-
iteration data dependence and does loop restructuring. If optimiza‐
tion is not at -xO3 or higher, optimization is raised to -xO3 and a
warning is issued.
Note that -xautopar does not enable the recognition of OpenMP prag‐
mas. To enable the recognition of OpenMP pragmas, use the -xopenmp
compiler option.
Use the OMP_NUM_THREADS environment variable to specify the number
of threads to use when running a program automatically parallelized
by the -xautopar compiler option. If OMP_NUM_THREADS is not set,
the default number of threads used is a multiple of the number of
cores per socket (that is, cores per processor chip), which is less
than or equal to the total number of cores or 32, whichever is
less. You can specify a different number of threads by setting the
OMP_NUM_THREADS environment variable. For best performance, the
number of threads used should not exceed the number of hardware
threads (or virtual processors) available on the machine. On Oracle
Solaris systems, this number can be determined by using the
psrinfo(1M) command. See the Oracle Developer Studio
12.6:
OpenMP API User's Guide for more information.
If you compile and link in separate steps, specify -xautopar in
both the compilation step and the link step. When used with the
link step, the -xautopar option will link with the OpenMP runtime
support library, libmtsk.so.
-xbuiltin[={%all|%default|%none}]
Use the -xbuiltin option to improve the optimization of code that
calls standard library functions. This option lets the compiler
substitute intrinsic functions or inline system functions where
profitable for performance. See the er_src(1) man page to learn how
to read compiler commentary output to determine which functions
were substituted by the compiler.
With -xbuiltin=%all, substitutions can cause the setting of errno
to become unreliable. If your program depends on the value of
errno, avoid this option.
-xbuiltin=%default only inlines functions that do not set errno.
The value of errno is always correct at any optimization level, and
can be checked reliably. With -xbuiltin=%default at -xO3 or lower,
the compiler will determine which calls are profitable to inline,
and not inline others.
The -xbuiltin=%none option turns off all substitutions of library
functions.
If you do not specify -xbuiltin, the default is -xbuiltin=%default
when compiling with an optimization level -xO1 and higher, and
-xbuiltin=%none at -xO0. If you specify -xbuiltin without an argu‐
ment, the default is -xbuiltin=%all and the compiler substitutes
intrinsics or inlines standard library functions much more aggres‐
sively.
Compiling with -fast adds -xbuiltin=%all.
Note: The -xbuiltin option only inlines global functions defined in
system header files, never static functions defined by the user.
User code that attempts to interpose on global functions may result
in undefined behavior.
-xCC
When you specify -std=c89 , c90, gnu89, or gnu99 and -xCC, the
compiler accepts the C++-style comments. In particular, the "//"
can be used to indicate the start of a comment.
-xc99[=o]
The -xc99 flag controls compiler recognition of the implemented
features from the C99 standard (ISO/IEC 9899:1999, Programming Lan‐
guage - C).
o can be a comma separated list comprised of the following:
[no_]lib
(Oracle Solaris) Enable the 1999 C standard library semantics
of routines that appeared in both the 1990 and 1999 C standard.
no_lib limits semantics to the 1990 C standard. This flag has
no effect on linux.
all
Turn on recognition of supported C99 language features and
enable the 1999 C standard library semantics of routines that
appear in both the 1990 and 1999 C standard.
none
Turn off recognition of C99 language features, and do not
enable the 1999 C standard library semantics of routines that
appeared in both the 1990 and 1999 C standard.
If you do not specify -xc99, the compiler defaults to
-xc99=all,no_lib.
If you specify -xc99 without any values, the option is set to
-xc99=all.
The -xc99 flag cannot be used if the -std or -xlang flag has been
specified.
-xcache=c
Define cache properties for use by optimizer.
c must be one of the following:
o generic
o native
o s1/l1/a1[/t1]
o s1/l1/a1[/t1]:s2/l2/a2[/t2]
o s1/l1/a1[/t1]:s2/l2/a2[/t2]:s3/l3/a3[/t3]
The si, li, ai, and ti, are defined as follows:
si The size of the data cache at level i, in kilobytes
li The line size of the data cache at level i, in bytes
ai The associativity of the data cache at level i
ti The number of hardware threads sharing the cache at
level i The ti parameters are optional. A value of 1
is used if not present.
This option specifies the cache properties that the optimizer can
use. It does not guarantee that any particular cache property is
used.
Although this option can be used alone, it is part of the expansion
of the -xtarget option; its primary use is to override a value sup‐
plied by the -xtarget option.
The -xcache values are:
generic
Define the cache properties for good performance on most plat‐
forms. This is the default.
native
Define the cache properties for good performance on this host
platform.
s1/l1/a1[/t1]
Define level 1 cache properties.
s1/l1/a1[/t1]:s2/l2/a2[/t2]
Define levels 1 and 2 cache properties.
s1/l1/a1[/t1]:s2/l2/a2[/t2]:s3/l3/a3[/t3]
Define levels 1, 2, and 3 cache properties.
-xchar=o
The option is provided solely for the purpose of easing the migra‐
tion of code from systems where the char type is defined as
unsigned. Unless you are migrating from such a system, do not use
this option. Only code that relies on the sign of a char type needs
to be rewritten to explicitly specify signed or unsigned. You can
substitute one of the following values for o:
signed Treat character constants and variables declared as
char as signed. This impacts the behavior of compiled
code, it does not affect the behavior of library rou‐
tines.
s Equivalent to signed.
unsigned Treat character constants and variables declared as
char as unsigned. This impacts the behavior of compiled
code, it does not affect the behavior of library rou‐
tines.
u Equivalent to unsigned.
If you do not specify -xchar, the compiler assumes -xchar=s. If you
specify -xchar, but do not specify a value, the compiler assumes
-xchar=s.
The -xchar option changes the range of values for the type char
only for code compiled with -xchar. This option does not change the
range of values for type char in any system routine or header file.
In particular, the value of CHAR_MAX and CHAR_MIN, as defined by
limits.h, do not change when this option is specified. Therefore,
CHAR_MAX and CHAR_MIN no longer represent the range of values
encodable in a plain char.
If you use -xchar, be particularly careful when you compare a char
against a predefined system macro because the value in the macro
may be signed. This is most common for any routine that returns an
error code which is accessed through a macro. Error codes are typi‐
cally negative values so when you compare a char against the value
from such a macro, the result is always false. A negative number
can never be equal to any value of an unsigned type.
It is strongly recommended that you never use -xchar to compile
routines for any interface exported through a library. The Oracle
Solaris ABI specifies type char as signed, and system libraries
behave accordingly. The effect of making char unsigned has not been
extensively tested with system libraries. Instead of using this
option, modify your code that it does not depend on whether type
char is signed or unsigned. The sign of type char varies among com‐
pilers and operating systems.
-xchar_byte_order=o
Produce an integer constant by placing the characters of a multi-
character character-constant in the specified byte order. You can
substitute one of the following values for o:
low Place the characters of a multi-character character-con‐
stant in low-to-high byte order.
high Place the characters of a multi-character character-con‐
stant in high-to-low byte order.
default Place the characters of a multi-character character-con‐
stant in an order determined by the compilation mode
-X[a|c|s|t].
-xcheck[=n]
Performs a runtime check for stack overflow of the main thread in a
singly-threaded program as well as slave-thread stacks in a multi‐
threaded program. If a stack overflow is detected, a SIGSEGV is
generated. If your application needs to handle a SIGSEGV caused by
a stack overflow differently than it handles other address-space
violations, see sigaltstack(2).
n must be one of the following values.
%all
Perform all -xcheck checks.
%none
Do not perform any of the -xcheck checks.
stkovf[action]
Generate code to detect stack overflow errors at runtime,
optionally specifying an action to be taken when a stack over‐
flow error is detected.
A stack overflow error occurs when a thread's stack pointer is
set beyond the thread's allocated stack bounds. The error may
not be detected if the new top of stack address is writable.
A stack overflow error is detected if a memory access violation
occurs as a direct result of the error, raising an associated
signal (usually SIGSEGV). The signal thus raised is said to be
associated with the error.
An undetected stack overflow error may result in silent data
corruption. Preventing undetected stack overflow errors
requires compiler and runtime support.
If -xcheck=stkovf[action] is specified, the compiler generates
code to detect stack overflow errors in cases involving stack
frames larger than the system page size. The code includes a
library call to force a memory access violation instead of set‐
ting the stack pointer to an invalid but potentially mapped
address (see _stack_grow(3C)).
The optional action, if specified, must be one of the follow‐
ing:
:detect
If action is :detect, a detected stack overflow error is
handled by executing the signal handler normally associated
with the error.
On SPARC Solaris, -xcheck=stkovf:detect is enabled by
default. This prevents silent corruption of the stack due
to stack overflow. It can be disabled by specifying
-xcheck=no%stkovf.
:diagnose
If action is :diagnose, a detected stack overflow error is
handled by catching the associated signal and calling
stack_violation(3C) to diagnose the error. This is the
default behavior if no action is specified.
If a memory access violation is diagnosed as a stack over‐
flow error, the following message is printed to stderr:
ERROR: stack overflow detected: pc=<inst_addr>,
sp=<sp_addr>
where <inst_addr> is the address of the instruction where
the error was detected, and <sp_addr> is the value of the
stack pointer at the time that the error was detected.
After checking for stack overflow and printing the above
message if appropriate, control passes to the signal han‐
dler normally associated with the error.
-xcheck=stkovf:detect adds a stack bounds check on entry to
routines with stack frames larger than system page size (see
_stack_grow(3C)). The relative cost of the additional bounds
check should be negligible in most applications.
-xcheck=stkovf:diagnose adds a system call to thread creation
(see sigaltstack(2)). The relative cost of the additional sys‐
tem call depends on how frequently the application creates and
destroys new threads.
-xcheck=stkovf is supported only on Oracle Solaris. The C run‐
time library on Linux does not support stack overflow
detection.
no%stkovf
Turns off stack-overflow checking.
init_local
Initialize local variables. See the Oracle Developer Studio
12.6:
C User's Guide description of this option
for a list of the predefined values used by the compiler to
initialize variables.
Exercise caution when using -xcheck with a large amount of
local data, such as arrays with more than 10,000 elements. This
can cause the compiler's internal representation of the program
to become very large when that local date is initialized, which
can result in significantly longer compilation times, espe‐
cially when combined with optimization levels greater than -02.
no%init_local
Do not initialize local variables.
noreturn
Inform the compiler to add code to cause a runtime error if a
routine which has been described as "do not return" returns.
A routine can be described as "do not return" by any of the
following:
o __attribute__ ((noreturn))
o #pragma does_not_return
o using the C11 qualifier _Noreturn
Undefined behaviour will result if a routine returns after
being described as not returning. The -xcheck=noreturn flag
tells the compiler to add an illegal instruction after every
call to a function marked as does not return to force the tar‐
get application to abort if that function returns.
If you do not specify -xcheck, the compiler defaults to
-xcheck=%none and if you specify -xcheck without any arguments, the
compiler defaults to -xcheck=%all, unless you are on an Oracle
Solaris system for SPARC, in which case, the compiler will default
to -xcheck=stkovf:detect for both cases.
The -xcheck option does not accumulate on the command line. The
compiler sets the flag in accordance with the last occurrence of
the command.
-xchip=c
Specifies the target processor for use by the optimizer.
c must be one of the values listed below.
Although this option can be used alone, it is part of the expansion
of the -xtarget option; its primary use is to override a value sup‐
plied by the -xtarget option.
This option specifies timing properties by specifying the target
processor.
Some effects are:
o The ordering of instructions, that is, scheduling
o The way the compiler uses branches
o The instructions to use in cases where semantically
equivalent alternatives are available
The -xchip values for SPARC platforms are:
generic
Set the parameters for the best performance over most SPARC
platform architectures. This is the default.
native
Set the parameters for the best performance on the host envi‐
ronment.
sparc64vi (Obsolete)
Optimize for the SPARC64 VI processor.
sparc64vii (Obsolete)
Optimize for the SPARC64 VII processor.
sparc64viiplus
Optimize for the SPARC64 VII plus processor.
sparc64x
Optimize for the SPARC64 X processor.
sparc64xplus
Optimize for the SPARC64 X+ processor.
sparc64xii
Optimize for the SPARC64 XII processor.
ultraT1 (Obsolete)
Optimize for the UltraSPARC T1 processor.
ultraT2 (Obsolete)
Optimize for the UltraSPARC T2 processor.
ultraT2plus (Obsolete)
Optimize for the UltraSPARC T2+ processor.
T3 (Obsolete)
Optimize for the SPARC T3 processor.
T4
Optimize for the SPARC T4 processor.
T5
Optimize for the SPARC T5 processor.
T7
Optimize for the SPARC T7 processor.
T8
Optimize for the SPARC T8 processor.
M5
Optimize for the SPARC M5 processor.
M6
Optimize for the SPARC M6 processor.
M7
Optimize for the SPARC M7 processor.
M8 Optimize for the SPARC M8 processor.
The -xchip values for x86 platforms are:
generic
Optimize for most x86 platforms.
native
Optimize for this host processor.
core2
Optimize for the Intel Core2 processor.
nehalem
Optimize for the Intel Nehalem processor.
penryn
Optimize for the Intel Penryn processor.
pentium
Obsolete. Use -xchip=generic instead.
pentium_pro
Obsolete. Use -xchip=generic instead.
pentium3
Obsolete. Use -xchip=generic instead.
pentium4
Optimize for the Intel Pentium 4 style processor.
sandybridge
Optimize for the Intel Sandy Bridge processor.
ivybridge
Optimize for the Intel Ivy Bridge processor.
haswell
Optimize for the Intel Haswell processor.
westmere
Optimize for the Intel Westmere processor.
amdfam10
Obsolete. Use -xchip=generic instead.
broadwell
Optimize for the Intel Broadwell processor.
skylake
Optimize for the Intel Skylake processor.
-xcode=v
(SPARC) Specify code address space.
Note: It is highly recommended that you build shared objects by
specifying -xcode=pic13 or -xcode=pic32. It is possible to build
workable shared objects with -m64 -xcode=abs64, but these will be
inefficient. Shared objects built with -m64 xarch=v9
-xcode=abs32 or -m64 -xcode=abs44 will not work.
The values for -xcode are:
abs32
This is the default for 32-bit systems. Generates 32-bit abso‐
lute addresses. Code + data + bss size is limited to 2**32
bytes.
abs44
This is the default for 64-bit systems. Generates 44-bit abso‐
lute addresses. Code + data + bss size is limited to 2**44
bytes. Available only on 64-bit architectures.
abs64
Generates 64-bit absolute addresses. Available only on 64-bit
architectures.
pic13
Generates position-independent code for use in shared libraries
(small model). Equivalent to -Kpic. Permits references to at
most 2**11 unique external symbols on 32-bit architectures,
2**10 on 64-bit.
pic32
Generates position-independent code for use in shared libraries
(large model). Equivalent to -KPIC. Permits references to at
most 2**30 unique external symbols on 32-bit architectures,
2**29 on 64-bit.
The default is -xcode=abs32 for 32-bit architectures. The default
is -xcode=abs44 for 64-bit architectures.
When building shared dynamic libraries, the default -xcode value of
abs44 (not abs32) will not work with 64-bit architectures. Specify
-xcode=pic13 or -xcode=pic32 instead.
To determine whether to use -xcode=pic13 or -xcode=pic32, check the
size of the Global Offset Table (GOT) by using elfdump -c (see the
elfdump(1) man page for more information) and to look for the sec‐
tion header, sh_name: .got. The sh_size value is the size of the
GOT. If the GOT is less than 8,192 bytes, specify -xcode=pic13,
otherwise specify -xcode=pic32.
In general, use the following guidelines to determine how you
should use -xcode:
o If you are building an executable you should not use
-xcode=pic13 or -xcode=pic32.
o If you are building an archive library only for linking
into executables you should not use -xcode=pic13 or
-xcode=pic32.
o If you are building a shared library, start with
-xcode=pic13 and once the GOT size exceeds 8,192 bytes,
use -xcode=pic32.
o If you are building an archive library for linking into
shared libraries you should just use -xcode=pic32.
-xcsi
This option allows the C compiler to accept source code written in
locales that do not conform to the ISO C source character code
requirements. These locales include ja_JP.PCK.
Note: The compiler translation phases required to handle such
locales may result in significantly longer compile times. You
should only use this option when you compile source files that con‐
tain source characters from one of these locales.
The compiler does not recognize source code written in locales that
do not conform to the ISO C source character code requirements
unless you specify -xcsi.
-xcompress={[no%]debug}
Compresses debug sections using the format specified by the -xcom‐
press_format option if supported by the underlying Operating Sys‐
tem. A sub-option is required. The option is ignored with a warning
when Operating System support is unavailable.
-xcompress_format=cmp-type
When -xcompress=debug is in effect, this options specifies how the
debug section is to be compressed.
The following values for cmp-type are recognized:
none No compression of the debug section is done.
zlib Compresses the debug section using ZLIB compression.
zlib-gnu Compresses the section using ZLIB compression, using
the GNU section compression format.
On Oracle Solaris, when compilation involves linking, the debug
sections are compressed using the ld option -z compress-sec‐
tions=cmp-type. For more information, see the ld(1) man page.
On Oracle Solaris, when compiling to an object file (.o), the debug
sections are compressed using elfcompress -t cmp-type. For more
information, see the elfcompress(1) man page.
On Linux, the objcopy command is used to compress debug sections of
each .o file using theobjcopy --compress-debug-sec‐
tions. For more information, see the objcopy(1g) man page.
The option is ignored with a warning when Operating System support
is unavailable.
-xdebugformat=dwarf
-xdebugformat=dwarf generates debugging information using the dwarf
standard format. This is the default. The option is obsolete.
See also the dwarfdump (1) man page for more information.
-xdebuginfo=a[,a...]
Control how much debugging and observability information is emit‐
ted.
The term tagtype refers to tagged types: structs, unions, enums,
and classes.
The following list contains the possible values for suboptions a.
The prefix no% applied to a suboption disables that suboption. The
default is -xdebuginfo=%none. Specifying -xdebuginfo without a sub-
option is forbidden.
%none
No debugging information is generated. This is the default.
[no%]line
Emit line number and file information.
[no%]param
Emit location list info for parameters. Emit full type informa‐
tion for scalar values (for example, int, char *) and type
names but not full definitions of tagtypes.
[no%]variable
Emit location list information for lexically global and local
variables, including file and function statics but excluding
class statics and externs. Emit full type information for
scalar values such as int and char * and type names but not
full definitions of tagtypes.
[no%]decl
Emit information for function and variable declarations, member
functions, and static data members in class declarations.
[no%]tagtype
Emit full type definitions of tagtypes referenced from param
and variable datasets, as well as template definitions.
[no%]macro
Emit macro information.
[no%]codetag
Emit DWARF codetags (also known as Stabs N_PATCH). This is
information regarding bitfields, structure copy, and spills
used by RTC and discover.
[no%]hwcprof
Generate information critical to hardware counter profiling.
This information includes ldst_map, a mapping from ld/st
instructions to the symbol table entry being referenced, and
branch_target table of branch-target addresses used to verify
that backtracking did not cross a branch-target. See -xhwcprof
for more information.
Note: ldst_map requires the presence of tagtype information.
The driver will issue an error if this requirement is not met.
These are macros which expand to combinations of -xdebuginfo and
other options as follows:
-g = -g2
-gnone =
-xdebuginfo=%none
-xglobalize=no
-xpatchpadding=fix
-xkeep_unref=no%funcs,no%vars
-g1 =
-xdebuginfo=line,param,codetag
-xglobalize=no
-xpatchpadding=fix
-xkeep_unref=no%funcs,no%vars
-g2 =
-xdebuginfo=line,param,decl,variable,tagtype,codetag
-xglobalize=yes
-xpatchpadding=fix
-xkeep_unref=funcs,vars
-g3 =
-xdebuginfo=line,param,decl,variable,tagtype,codetag,macro
-xglobalize=yes
-xpatchpadding=fix
-xkeep_unref=funcs,vars
-xdepend[=[yes|no]]
Analyzes loops for inter-iteration data dependencies and performs
loop restructuring. Loop restructuring includes loop interchange,
loop fusion, scalar replacement, and elimination of "dead" array
assignments.
On SPARC, -xdepend is turned on for all optimization levels -xO3
and above, and is off for lower opt levels. Also, an explicit set‐
ting of -xdepend overrides any implicit setting.
On x86, if optimization is not at -xO3 or higher, the compiler
raises the optimization to -xO3 and issues a warning.
If you do not specify -xdepend, the default is -xdepend=no which
means the compiler does not analyze loops for data dependencies. If
you specify -xdepend but do not specify an argument, the compiler
sets the option to -xdepend=yes which means the compiler analyzes
loops for data dependencies.
Dependency analysis is included in -xautopar. The dependency analy‐
sis is done at compile time.
Dependency analysis may help on single-processor systems. However,
if you try -xdepend on single-processor systems, you should not
also specify -xautopar , otherwise the -xdepend optimization is
done for multiple-processor systems.
See also: -xprefetch_auto_type
-xdryrun
This option is a macro for -###.
-xdumpmacros[=value[,value...]]
Use this option when you want to see how macros are behaving in
your program. This option provides information such as macro
defines, undefines, and instances of usage. It prints output to the
standard error (stderr), based on the order macros are processed.
The -xdumpmacros option is in effect until the end of the file or
until it is overridden by the dumpmacros or end_dumpmacros pragma.
Values:
The prefix no% applied to a suboption disables that suboption.
[no%]defs
Print all macro defines.
[no%]undefs
Print all macro undefines.
[no%]use
Print information about macros used.
[no%]loc
Print location (path name and line number) also for defs,
undefs, and use.
[no%]conds
Print use information for macros used in conditional direc‐
tives.
[no%]sys
Print all macros defines, undefines, and use information for
macros in system header files.
%all
Sets the option to -xdumpmacros=defs,undefs,use,loc,conds,sys.
A good way to use this argument is in conjunction with the
[no%] form of the other arguments. For example, -xdump‐
macros=%all,no%sys would exclude system header macros from the
output but still provide information for all other macros.
%none
Do not print any macro information.
The option values accumulate so specifying -xdumpmacros=sys
-xdumpmacros=undefs has the same effect as -xdumpmacros=undefs,sys.
Note: The sub-options loc, conds, and sys are qualifiers for defs,
undefs and use options. By themselves, loc, conds, and sys have no
effect. For example, -xdumpmacros=loc,conds,sys has no effect.
Defaults:
If you specify -xdumpmacros without any arguments, it means -xdump‐
macros=defs,undefs,sys. If you do not specify -xdumpmacros, it
defaults to -xdumpmacros=%none.
-xe
Performs only syntax and semantic checking on the source file, but
does not produce any object or executable file.
-xF[=v]
The -xF option enables the optimal reordering of functions and
variables by the linker.
This option instructs the compiler to place functions and/or data
variables into separate section fragments, which enables the
linker, using directions in a mapfile specified by the linker's -M
option, to reorder these sections to optimize program performance.
Generally, this optimization is only effective when page fault time
constitutes a significant fraction of program runtime.
Reordering functions and variables for optimal performance requires
the following operations:
1. Compiling and linking with -xF.
2. Following the instructions in the Performance
Analyzer manual regarding how to gen‐
erate a mapfile for functions or following the instruc‐
tions in the Linker and Libraries
Guide regarding how to generate a map‐
file for data.
3. Relinking with the new mapfile by using the linker's -M
option.
4. Re-executing under the Analyzer to verify improvement.
v can be one of the following values. Prefix no% disables the sub‐
option.
[no%]func
Fragment functions into separate sections.
[no%]gbldata
Fragment global data (variables with external linkage) into
separate sections.
%all
Fragment functions and global data.
%none
Fragment nothing.
If you do not specify -xF, the default is -xF=%none. If you specify
-xF without any arguments, the default is -xF=%none,func.
See also: analyzer(1), ld(1)
-xglobalize[={yes|no}]
Control globalization of function-level or file-level static vari‐
ables.
Globalization is a technique needed by fix and continue functional‐
ity in the debugger whereby function-level or file-level static
symbols are promoted to globals while a prefix is added to the name
to keep identically named symbols distinct.
The default is -xglobalize=no. Specifying -xglobalize is equivalent
to specifying -xglobalize=yes.
Interactions:
See -xpatchpadding.
-xhelp=flags
Displays a summary of the compiler options.
-xhelp=gccflags
Displays a summary of addtional gcc flags accepted by Studio that
is not shown by the -xhelp=flags.
-xhwcprof[={enable|disable}]
Use the -xhwcprof option to enable compiler support for dataspace
profiling.
When -xhwcprof is enabled, the compiler generates information that
helps tools associate profiled load and store instructions with the
data-types and structure members (in conjunction with symbolic
information produced with -g) to which they refer. It associates
profile data with the data space of the target, rather than the
instruction space, and provides insight into behavior that is not
easily obtained from only instruction profiling.
You can compile a specified set of object files with -xhwcprof how‐
ever, -xhwcprof is most useful when applied to all object files in
the appli`xhwcprof without any arguments is the equivalent to
-xhwcprof=enable.
-xhwcprof requires that optimization be turned on and that the
debug data format be set to dwarf (-xdebugformat=dwarf), which is
the default with current Oracle Developer Studio compilers.
-xhwcprof uses -xdebuginfo to automatically enable the minimum
amount of debugging information it needs, so -g is not required.
The combination of -xhwcprof and -g increases compiler temporary
file storage requirements by more than the sum of the increases due
to -xhwcprof and -g specified alone.
-xhwcprof is implemented as a macro that expands to various other,
more primitive, options as follows:
-xhwcprof
-xdebuginfo=hwcprof,tagtype,line
-xhwcprof=enable
-xdebuginfo=hwcprof,tagtype,line
-xhwcprof=disable
-xdebuginfo=no%hwcprof,no%tagtype,no%line
The following command compiles example.c and specifies support for
hardware counter profiling and symbolic analysis of data types and
structure members using DWARF symbols:
example% cc -c -O -xhwcprof -g -xdebugformat=dwarf example.c
For more information on hardware counter-based profiling, see the
Performance Analyzer manual.
-xinline[=v[,v]...]
v can be [{%auto,func_name,no%func_name}].
-xinline tries to inline only those functions specified in the
list. The list is comprised of either a comma-separated list of
function names, or a comma separated list of no%func_name values,
or the value %auto. If you specify %nofunc_name, the compiler is
not to inline the named function. If you specify %auto, the com‐
piler is to attempt to automatically inline all functions in the
source files.
The list of values accumulates from left to right. So for a speci‐
fication of -xinline=%auto,no%foo the compiler attempts to inline
all functions except foo. For a specification of -xin‐
line=%bar,%myfunc,no%bar the compiler only tries to inline myfunc.
When you compile with optimization set at -xO4 or above, the com‐
piler normally tries to inline all references to functions defined
in the source file. You can restrict the set of functions the com‐
piler attempts to inline by specifying the -xinline option. If you
specify only -xinline=, that is you do not name any functions or
auto, this indicates that none of the routines in the source files
are to be inlined. If you specify a list of func_name and
no%func_name without specifying %auto, the compiler only attempts
to inline those functions specified in the list. If %auto is speci‐
fied in the list of values with the -xinline option at optimization
level set at -xO4 or above, the compiler attempts to inline all
functions that are not explicitly excluded by no%func_name.
A function is inlined if any of the following apply:
o Optimization is set at -xO3 or higher.
o Inlining the funciton is judged to be profitable and
safe.
o The source for the function is in the file being com‐
piled or the function is in a file that was compiled
with -xipo[=1|2].
If you specify multiple -xinline options on the command line, they
do not accumulate. The last -xinline on the command line specifies
what functions the compiler attempts to inline.
See also: -xldscope.
-xinline_param=a[,a[,a]...]
Use this option to manually change the heuristics used by the com‐
piler for deciding when to inline a function call.
This option only has an effect at -O3 or higher. The following sub-
options have an effect only at -O4 or higher when automatic inlin‐
ing is on.
In the following sub-options n must be a positive integer; a can be
one of the following:
default
Set the values of all the sub-options to their default values.
max_inst_hard[:n]
Automatic inlining only considers functions smaller than n
pseudo instructions (counted in compiler's internal representa‐
tion) as possible inline candidates.
Under no circumstances will a function larger than this be con‐
sidered for inlining.
max_inst_soft[:n]
Set inlined function's size limit to n pseudo instructions
(counted in compiler's internal representation).
Functions of greater size than this may sometimes be inlined.
When interacting with max_inst_hard, the value of max_inst_soft
should be equal to or smaller than the value of max_inst_hard,
i.e, max_inst_soft <= max_inst_hard.
In general, the compiler's automatic inliner only inlines calls
whose called function's size is smaller than the value of
max_inst_soft. In some cases a function may be inlined when its
size is larger than the value of max_inst_soft but smaller than
that of max_inst_hard. An example of this would be if the
parameters passed into a function were constants.
When deciding whether to change the value of max_inst_hard or
max_inst_soft for inlining one specific call site to a func‐
tion, use -xinline_report=2 to report detailed inlining message
and follow the suggestion in the inlining message.
max_function_inst[:n]
Allow functions to increase due to automatic inlining by up to
n pseudo instructions (counted in compiler's internal represen‐
tation).
max_growth[:n]
The automatic inliner is allowed to increase the size of the
program by up to n% where the size is measured in pseudo
instructions.
min_counter[:n]
The minimum call site frequency counter as measured by profil‐
ing feedback (-xprofile) in order to consider a function for
automatic inlining.
This option is valid only when the application is compiled with
profiling feedback (-xprofile=use).
level[:n]
Use this sub-option to control the degree of automatic inlining
that is applied. The compiler will inline more functions with
higher settings for -xinline_param=level.
n must be one of 1, 2, or 3.
The default value of n is 2 when this option is not specified,
or when the options is specified without :n.
Specify the level of automatic inline
level:1 basic inlining
level:2 medium inlining (default)
level:3 aggressive inlining
The level decides the specified values for the combination of
the following inlining parameters:
max_growth
+ max_function_inst
+ max_inst
+ max_inst_call
When level = 1, all the parameters are half the values of the
default. When level = 2, all the parameters are the default
value. When level = 3, all the parameters are double the values
of the default.
max_recursive_depth[:n]
When a function calls itself either directly or indirectly, it
is said to be making a recursive call.
This sub-option allows a recursive call to be automatically
inlined up to n levels.
max_recursive_inst[:n]
Specifies the maximum number of pseudo instructions (counted in
compiler's internal representation) the caller of a recursive
function can grow to by performing automatic recursive inlin‐
ing.
When interactions between max_recursive_inst and max_recur‐
sive_depth occur, recursive function calls will be inlined
until either the max_recursive_depth number of recursive calls,
or until the size of the function being inlined into exceeds
max_recursive_inst. The settings of these two parameters con‐
trol the degree of inlining of small recursive functions.
If -xinline_param=default is specified, the compiler will set all
the values of the sub-opitons to the default values.
If the option is not specified, the default is -xin‐
line_param=default.
The list of values and options accumulate from left to right. So
for a specification of -xin‐
line_param=max_inst_hard:30,..,max_inst_hard:50, the value
max_inst_hard:50 will be passed to the compiler.
If multiple -xinline_param options are specified on the command
line, the list of sub-options likewise accumulate from left to
right. For example, the effect of
-xinline_param=max_inst_hard:50,min_counter:70 ...
-xinline_param=max_growth:100,max_inst_hard:100
will be the same as that of
-xinline_param=max_inst_hard:100,min_counter:70,max_growth:100
-xinline_report[=n]
This option generates a report written to standard output on the
inlining of functions by the compiler. The type of report depends
on the value of n, which must be 0, 1, or 2.
0 No report is generated.
1 A summary report of default values of inlining parame‐
ters is generated.
2 A detailed report of inlining messages is generated,
showing which callsites are inlined and which are not,
with a short reason for not inlining a callsite. In
some cases, this report will include suggested values
for -xinline_param that can be used to inline a call‐
site that is not inlined.
When -xinline_report is not specified, the default value for n is
0. When -xinline_report is specified without =n, the default value
is 1.
When -xlinkopt is present, the inlining messages about the call‐
sites that are not inlined might not be accurate.
-xinstrument=[no%]datarace]
Specify this option to compile and instrument your program for
analysis by the Thread Analyzer. For more information on the Thread
Analyzer, see tha(1) for details.
You can then use the Performance Analzyer to run the instrumented
program with collect -r races to create a data-race-detection
experiment. You can run the instrumented code standalone but it
runs more slowly.
You can specify -xinstrument=no%datarace to turn off preparation of
source code for the thread analyzer. This is the default.
It is illegal to specify -xinstrument without an argument.
If you compile and link in seperate steps, you must specify -xin‐
strument=datarace in both the compilation and linking steps.
This option defines the preprocessor token __THA_NOTIFY. You can
specify #ifdef __THA_NOTIFY to guard calls to libtha(3) routines.
This option also sets -g.
Interactions:
-xinstrument cannot be used together with -xlinkopt.
-xipo[=n]
The compiler performs partial-program optimizations by invoking an
interprocedural analysis pass. It performs optimizations across all
object files in the link step, and is not limited to just the
source files on the compile command. However, whole-program opti‐
mizations performed with -xipo do not include assembly (.s) source
files.
You must specify -xipo both at compile time and at link time. For a
complete list of compiler options that must be specified at both
compile time and at link time, see the Oracle Developer
Studio
12.6:
C User's Guide.
Analysis and optimization is limited to the object files compiled
with -xipo, and does not extend to object files or libraries. -xipo
is multiphased, so you need to specify -xipo for each step if you
compile and link in separate steps.
The -xipo option generates significantly larger object files due to
the additional information needed to perform optimizations across
files. However, this additional information does not become part of
the final executable binary file. Any increase in the size of the
executable program is due to the additional optimizations per‐
formed. The object files created in the compilation steps have
additional analysis information compiled within them to permit
crossfile optimizations to take place at the link step.
n is 0, 1, or 2. -xipo without any arguments is equivalent to
-xipo=1. -xipo=0 is the default setting and turns off -xipo.
With -xipo=1, the compiler performs inlining across all source
files. At -xipo=2, the compiler performs interprocedural aliasing
analysis as well as optimization of memory allocation and layout to
improve cache performance.
Here are some important considerations for -xipo:
o It requires an optimization level of at least -xO4.
o Objects that are compiled without -xipo can be linked
freely with objects that are compiled with -xipo.
In this example, compilation and linking occur in a single step:
cc -xipo -xO4 -o prog part1.c part2.c part3.c
In this example, compilation and linking occur in separate steps:
cc -xipo -xO4 -c part1.c part2.c
cc -xipo -xO4 -c part3.c
cc -xipo -xO4 -o prog part1.o part2.o part3.o
The object files created in the compilation steps have additional
analysis information compiled within them to permit crossfile opti‐
mizations to take place at the link step.
If you have .o files compiled with the -xipo option from different
compiler versions, mixing these files can result in failure with an
error message about "IR version mismatch". When using the -xipo
option, all the files should be compiled with the same version of
the compiler.
A restriction is that libraries, even if compiled with -xipo do not
participate in crossfile interprocedural analysis, as shown in this
example:
cc -xipo -xO4 one.c two.c three.c
ar -r mylib.a one.o two.o three.o
cc -xipo -xO4 -o myprog main.c four.c mylib.a
Here interprocedural optimizations are performed between one.c,
two.c and three.c, and between main.c and four.c, but not between
main.c or four.c and the routines on mylib.a. (The first compila‐
tion may generate warnings about undefined symbols, but the inter‐
procedural optimizations are performed because it is a compile and
link step.)
When Not To Use -xipo=2 Interprocedural Analysis:
The compiler tries to perform whole-program analysis and optimiza‐
tions as it works with the set of object files in the link step.
The compiler makes the following two assumptions for any function
(or subroutine) foo() defined in this set of object files:
1. foo() is not called explicitly by another routine that
is defined outside this set of object files at runtime.
2. The calls to foo() from any routine in the set of object
files are not interposed upon by a different version of
foo() defined outside this set of object files.
Do not compile with -xipo=2 if assumption (1) is not true for the
given application.
Do not compile with either -xipo=1 or -xipo=2 if assumption (2) is
not true.
As an example, consider interposing on the function malloc() with
your own version and compiling with -xipo=2. Consequently, all the
functions in any library that reference malloc() that are linked
with your code have to be compiled with -xipo=2 also and their
object files need to participate in the link step. Since this might
not be possible for system libraries, do not compile your version
of malloc() with -xipo=2.
As another example, suppose that you build a shared library with
two external calls, foo() and bar() inside two different source
files. Furthermore, suppose that bar() calls foo(). If there is a
possibility that foo() could be interposed at runtime, then do not
compile the source file for foo() or for bar() with -xipo=1 or
-xipo=2. Otherwise, foo() could be inlined into bar(), which could
cause incorrect results.
See also: -xjobs and -xipo_archive
-xipo_archive[=a]
The -xipo_archive option enables the compiler to optimize object
files that are passed to the linker with object files that were
compiled with -xipo and that reside in the archive library (.a)
before producing an executable. Any object files contained in the
library that were optimized during the compilation are replaced
with their optimized version.
a is one of the following:
writeback
The compiler optimizes object files passed to the linker with
object files compiled with -xipo that reside in the archive
library (.a) before producing an executable. Any object files
contained in the library that were optimized during the compi‐
lation are replaced with an optimized version.
For parallel links that use a common set of archive
libraries,each link should create its own copy of archive
libraries to be optimized before linking.
readonly
The compiler optimizes object files passed to the linker with
object files compiled with -xipo that reside in the archive
library (.a) before producing an executable.
The option -xipo_archive=readonly enables cross-module inlining
and interprocedural data flow analysis of object files in an
archive library specified at link time. However, it does not
enable cross-module optimization of the archive library's code
except for code that has been inserted into other modules by
cross module inlining.
To apply cross-module optimization to code within an archive
library, -xipo_archive=writeback is required. Note that doing
so modifies the contents of the archive library from which the
code was extracted.
none
Default. There is no processing of archive files. The compiler
does not apply cross-module inlining or other cross-module
optimizations to object files compiled using -xipo and
extracted from an archive library at link time. To do that,
both -xipo and either -xipo_archive=readonly or -xipo_ar‐
chive=writeback must be specified at link time.
It is illegal to specify -xipo_archive without a flag.
-xipo_build=[yes|no]
Building -xipo without -xipo_build involves two passes through the
compiler -- once when producing the object files, and then again
later at link time when performing the cross file optimization.
Setting -xipo_build reduces compile time by avoiding optimizations
during the initial pass and optimizing only at link time. Optimiza‐
tion is not needed for the object files, as with -xipo it will be
performed at link time. If unoptimized object files built with
-xipo_build are linked without including -xipo to perform optimiza‐
tion, the application will fail to link with an unresolved symbol
error.
Examples:
The following example performs a fast build of .o files, followed
by crossfile optimization at link time:
% cc -O -xipo -xipo_build -o code1.o -c code1.c
% cc -O -xipo -xipo_build -o code2.o -c code2.c
% cc -O -xipo -o a.out code1.o code2.o
The -xipo_build will turn off -O when creating the .o files, to
build these quickly. Full -O optimization will be performed at link
time as part of -xipo crossfile optimization.
The following example links without using -xipo.
% cc -O -o a.out code1.o code2.o
If either code1.o or code2.o were generated with -xipo_build, the
result will be a link-time failure indicating the symbol __unopti‐
mized_object_file is unresolved.
When building .o files separately, the default behavior is
-xipo_build=no. However, when the executable or library is built in
a single pass from source files, -xipo_build will be implicitly
enabled. For example:
% cc -fast -xipo a.c b.c c.c
will implicitly enable -xipo_build=yes for the first passes that
generate a.o, b.o, and c.o. Include the option -xipo_build=no to
disable this behavior.
-xivdep[=p]
Disable or set interpretation of ivdep pragmas.
The ivdep pragmas tell a compiler to ignore some or all loop-car‐
ried dependences on array references that it finds in a loop for
purposes of optimization. This enables a compiler to perform vari‐
ous loop optimizations such as microvectorization, distribution,
software pipelining, etc., which would not be otherwise possible.
It is used in cases where the user knows either that the depen‐
dences do not matter or that they never occur in practice.
The interpretation of #pragma ivdep directives depend upon the
value of the -xivdep option.
The following values for p are interpreted as follows:
loop Ignore assumed loop-carried vector dependences.
loop_any Ignore all loop-carried vector dependences.
back Ignore assumed backward loop-carried vector depen‐
dences.
back_any Ignore all backward loop-carried vector dependences.
none Do not ignore any dependences (disables ivdep pragmas).
These interpretations are provided for compatibility with other
vendor's interpretations of the ivdep pragma.
-xjobs={n|auto}
Compile with multiple processes. If this flag is not specified, the
default behavior is -xjobs=auto.
Specify the -xjobs option to set how many processes the compiler
creates to complete its work. This option can reduce the build time
on a multi-cpu machine. Currently, -xjobs works only with the -xipo
option. When you specify -xjobs=n, the interprocedural optimizer
uses n as the maximum number of code generator instances it can
invoke to compile different files.
Generally, a safe value for n is 1.5 multiplied by the number of
available processors. Using a value that is many times the number
of available processors can degrade performance because of context
switching overhead among spawned jobs. Also, using a very high num‐
ber can exhaust the limits of system resources such as swap space.
When -xjobs=auto is specified, the compiler will automatically
choose the appropriate number of parallel jobs.
You must always specify -xjobs with a value. Otherwise an error
diagnostic is issued and compilation aborts.
If -xjobs is not specified, the default behavior is -xjobs=auto.
This can be overridden by adding -xjobs=n to the command line. Mul‐
tiple instances of -xjobs on the command line override each other
until the rightmost instance is reached.
Examples:
The following example links with up to 3 parallel processes for
-xipo:
% cc -xipo -xO4 -xjobs=3 t1.o t2.o t3.o
The following example links serially with a single process for
-xipo:
% cc -xipo -xO4 -xjobs=1 t1.o t2.o t3.o
The following example links in parallel, with the compiler choosing
the number of jobs for -xipo:
% cc -xipo -xO4 t1.o t2.o t3.o
Note that this is exactly the same behavior as when explicitly
specifying -xjobs=auto:
% cc -xipo -xO4 -xjobs=auto t1.o t2.o t3.o
-xkeep_unref[={[no%]funcs, [no%]vars}]
Keep definitions of unreferenced functions and variables. The no%
prefix allows the compiler to potentially remove the definitions.
The default is no%funcs,no%vars. Specifying -xkeep_unref is equiva‐
lent to specifying -xkeep_unref=funcs,vars, meaning that
-keep_unref keeps everything.
-xkeepframe[=[%all,%none,function_name,no%function_name]]
Prohibit stack related optimizations for the named functions.
Specifying %all prohibits stack-related optimizations for all the
code. Specifying %none allows stack-related optimizations for all
the code.
If not specified on the command line, the compiler assumes -xkeep‐
frame=%none.
If specified on the command line without a value, the compiler
assumes -xkeepframe=%all.
This option is accumulative and can appear on the command line mul‐
tiple times. For example,
-xkeepframe=%all -xkeepframe=no%func1
indicates that the stack frame should be kept for all functions
except func1. Also, -xkeepframe overrides -xregs=frameptr. For
example,
-xkeepframe=%all -xregs=frameptr
indicates that the stack should be kept for all functions, but the
optimizations for -xregs=frameptr would not be done.
-xlang=language
(Oracle Solaris) The -xlang flag can be used to override the
default libc behavior as specified by the -std flag. language must
be one of the following:
c89 Specify runtime library behavior of libc to be in con‐
formance with the C90 standard.
c99 Specify runtime library behavior of libc be in confor‐
mance with the C99 standard.
c11 Equivalent to c99. The runtime library behavior of
libc for c99 and c11 are identical.
When -xlang is not specified, it defaults to the ISO C runtime
library behavior as the -std flag. For example, for -std=c11,
-xlang defaults to -xlang=c11, for -std=gnu89 -xlang defaults to
-std=c89.
The -Xc, -Xa, -Xt, -Xs, and -xc99 flags cannot be used if -xlang
has been specified. Doing so will result in an error being issued
by the compiler.
If you compile and link in separate steps you must use the same
values for -xlang in both steps.
To determine which driver to use for mixed-language linking, use
the following language hierarchy:
C++
Use the CC command. See CC(1) for details.
Fortran 95 (or Fortran 90)
Use the f95 command. See f95(1) for details.
Fortran 77
Use f95 -xlang=f77. See f95(1) for details.
C
Use the cc command.
This flag is available only on Oracle Solaris and is silently
ignored on Linux.
-xldscope={v}
Changes the default linker scoping for the definition of extern
symbols. Changing the default can result in faster and safer shared
libraries because the implementation will be better hidden.
v must be one of the following:
global
Global linker scoping is the least restrictive linker scoping.
All references to the symbol bind to the definition in the
first dynamic module that defines the symbol. This linker scop‐
ing is the current linker scoping for extern symbols.
symbolic
Symbolic linker scoping and is more restrictive than global
linker scoping. All references to the symbol from within the
dynamic module being linked bind to the symbol defined within
the module. Outside of the module, the symbol appears as though
it were global. This linker scoping corresponds to the linker
option -Bsymbolic.
hidden
Hidden linker scoping is more restrictive than symbolic and
global linker scoping. All references within a dynamic module
bind to a definition within that module. The symbol will not be
visible outside of the module.
If you do not specify -xldscope, the compiler assumes -xld‐
scope=global. It is not legal to specify -xldscope without any
arguments. The compiler issues an error if you specify -xldscope
without an argument. Multiple instances of this option on the com‐
mand line override each other until the rightmost instance is
reached.
If you intend to allow a client to override a function in a
library, you must be sure that the function is not generated inline
during the library build. The compiler inlines a function if you
specify the function name with -xinline, if you use #pragma inline,
if you compile at -xO4 or higher in which case inlining can happen
automatically, if you use the inline specifier, or if you are using
cross-file optimization.
For example, suppose library ABC has a default allocator function
that can be used by library clients, and is also used internally in
the library:
void* ABC_allocator(size_t size) { return malloc(size); }
If you build the library at -xO4 or higher, the compiler inlines
calls to ABC_allocator that occur in library components. If a
library client wants to replace ABC_allocator with a customized
version, the replacement will not occur in library components that
called ABC_allocator. The final program will include different ver‐
sions of the function.
Library functions declared with the __hidden or __symbolic speci‐
fiers can be generated inline when building the library. They are
not supposed to be overridden by clients. For more information, see
chapter 2 "C-Compiler Implementation Specific Information" in the
Oracle Developer Studio
12.6:
C User's Guide.
Library functions declared with the __global specifier, should not
be declared inline, and should be protected from inlining by use of
the -xinline compiler option.
See also:
-xinline, -xO, ld(1).
-xlibmieee
Forces IEEE 754 style return values for math routines in excep‐
tional cases. In such cases, no exception message will be printed,
and errno should not be relied on.
-xlibmil
Inlines some library routines for faster execution. This option
selects the appropriate assembly language inline templates for the
floating-point option and platform for your system. -xlibmil
inlines a function regardless of any specification of the function
as part of the -xinline flag.
However, these substitutions can cause the setting of errno to
become unreliable. If your program depends on the value of errno,
avoid this option. See the NOTES section at the end of this man
page for more information.
-xlibmopt[={%none,archive,shared}]
Controls whether the compiler uses a library of optimized math rou‐
tines or the standard system math routines. The possible argument
values are:
%none
Do not link with the optimized math library. (This is the
default when no -xlibmopt option is specified.)
archive
Link with the optimized math library in static archive form.
(This is the default when -xlibmopt is specified with no argu‐
ment.)
shared
(Oracle Solaris) Link with the optimized math library in shared
object form.
The rightmost instance of this option on the command line overrides
all previous instances. The order of this option relative to other
libraries specified on the command line is not significant.
The optimized math library includes selected math routines normally
found in libm. The optimized routines typically run faster than
their libm counterparts. The results may be slightly different from
those produced by the libm routines, although in most cases they
differ only in the least significant bit. When the static archive
form of the optimized library is used, the compiler selects rou‐
tines that are optimized for the instruction set indicated by the
-xarch value specified when linking. When the shared object form is
used, the most appropriate routines are selected at runtime based
on the instruction set supported by the system being used.
NOTE: The shared object form is available only on Oracle Solaris.
The routines in the optimized math library depend on the default
round-to-nearest floating point rounding mode. If you use the opti‐
mized math library, you must ensure that round-to-nearest mode is
in effect when any of these routines is called. These routines also
do not modify errno. Do not link with the optimized math library if
your program depends on math functions setting errno in response to
error conditions. See the NOTES section at the end of this man page
for more information.
Interactions:
-xlibmopt=archive is implied by the -fast option. To disable link‐
ing with the optimized math library when -fast is used, add -xlib‐
mopt=%none following -fast on the command line:
example% cc -fast -xlibmopt=%none ...
See also:
-fast
-xlinkopt[=level]
(Oracle Solaris) Instructs the compiler to perform link-time opti‐
mizations on relocatable object files.
The post-optimizer performs a number of advanced performance opti‐
mizations on the binary object code at link-time. The value level
sets the level of optimizations performed, and must be 0, 1, or 2.
The optimization levels are:
0 The post-optimizer is disabled. (This is the default.)
1 Perform optimizations based on control flow analysis,
including instruction cache coloring and branch opti‐
mizations, at link time.
2 Perform additional data flow analysis, including dead-
code elimination and address computation simplifica‐
tion, at link time.
Specifying -xlinkopt without the level parameter implies
-xlinkopt=1.
These optimizations are performed at link time by analyzing the
object binary code. The object files are not rewritten but the
resulting executable code may differ from the original object
codes.
This option is most effective when you use it to compile the whole
program, and with profile feedback.
If you compile in separate steps, -xlinkopt must appear on both
compile and link steps:
example% cc -c -xlinkopt a.c b.c
example% cc -o myprog -xlinkopt=2 a.o
For a complete list of compiler options that must be specified at
both compile time and at link time, see the Oracle
Developer Studio
12.6:
C User's Guide.
Note that the level parameter is only used when the compiler is
linking. In the example above, the post-optimization level used is
2 even though the object binaries were compiled with an implied
level of 1.
Do not use the -zcombreloc linker option when you compile with
-xlinkopt.
You must use -xlinkopt on at least some of the compilation commands
for -xlinkopt to be useful at link time. The optimizer can still
perform some limited optimizations on object binaries not compiled
with -xlinkopt.
-xlinkopt optimizes code coming from static libraries that appear
on the compiler command line, but it skips and does not optimize
code coming from shared (dynamic) libraries that appear on the com‐
mand line. You can also use -xlinkopt when you build shared
libraries (compiling with -G ).
The link-time post-optimizer is most effective when you use it with
runtime profile feedback. Profiling reveals the most and least used
parts of the code and directs the optimizer to focus its effort
accordingly. This is particularly important with large applications
where optimal placement of code performed at link time can reduce
instruction cache misses. Typically, this would be compiled as fol‐
lows:
example% cc -o progt -xO5 -xprofile=collect:profdir file.c
example% progt
example% cc -o prog -xO5 -xprofile=use:profdir -xlinkopt file.c
For details on using profile feedback, see -xprofile.
Note that compiling with this option increases link time slightly.
Object file sizes also increase, but the size of the executable
remains the same. Compiling with -xlinkopt and -g increases the
size of the excutable by including debugging information.
Interactions:
-xlinkopt cannot be used together with -xinstrument.
-xloopinfo
Shows which loops are parallelized and which are not. This option
is normally for use with the -xautopar option.
-xM
Runs only the preprocessor on the named C programs, requesting that
it generate makefile dependencies and send the result to the stan‐
dard output (see make (1) for details about makefiles
and dependencies).
-xM1
Same as -xM except that -xM1 is not supported in -Xs mode nor does
-xM1 report dependencies for /usr/include header files. For exam‐
ple:
example% more hello.c
#include <stdio.h>
main()
{
(void) printf ("hello\n");
}
example% cc -xM hello.c
hello.o: hello.c
hello.o: /usr/include/stdio.h
Compiling with -xM1 does not report header file dependencies:
example% cc -xM1 hello.c
hello.o: hello.c
-xMD
Generates makefile dependencies like -xM but compilation continues.
-xMD generates an output file for the makefile-dependency informa‐
tion derived from the -o output filename, if specified, or the
input source filename, replacing (or adding) the filename suffix
with .d . If you specify -xMD and -xMF, the preprocessor writes all
makefile dependency information to the file specified with -xMF.
Compiling with -xMD -xMF or -xMD -o filename with
more than one source file is not allowed and generates an error.
The dependency file is overwritten if it already exists.
-xMF filename
Use this option to specify a file for the makefile- dependency out‐
put. There is no way to specify individual filenames for multiple
input files with -xMF on one command line. Compiling with -xMD
-xMF or -xMMD -xMF with more than one source file is not allowed
and generates an error. The dependency file is overwritten if it
already exists.
This option cannot be used with -xM or -xM1.
-xMMD
Use this option to generate makefile dependencies excluding system
header files. This is the same functionality as -xM1, but compila‐
tion continues. -xMMD generates an output file for the makefile-
dependency information derived from the -o output filename, if
specified, or the input source filename, replacing (or adding) the
filename suffix with .d . If you specify -xMF, the compiler uses
the filename you provide instead. Compiling with -xMMD -xMF or
-xMMD -o filename with more than one source file is not allowed
and generates an error. The dependency file is overwritten if it
already exists.
-xMerge
Directs cc to merge the data segment with the text segment. Data
initialized in the object file produced by this compilation is
read-only and (unless linked with ld -N) is shared between pro‐
cesses.
-xMerge, -ztext, and -xprofile=collect should not be used together.
While -xMerge forces statically initialized data into read-only
storage, -ztext prohibits position-dependent symbol relocations in
read-only storage, and -xprofile=collect generates statically ini‐
tialized, position-dependent symbol relocations in writable stor‐
age.
-xmaxopt[=v]
This command limits the level of pragma opt to the level specified.
The default value is -xmaxopt=off which causes pragma opt to be
ignored. If you specify -xmaxopt without supplying an argument,
that is the equivalent of specifying -xmaxopt=5.
If you specify both -xO and -xmaxopt, the optimization level set
with -xO must not exceed the -xmaxopt value.
-xmemalign=ab
(SPARC) Use the -xmemalign option to control the assumptions the
compiler makes about the alignment of data. By controlling the code
generated for potentially misaligned memory accesses and by con‐
trolling program behavior in the event of a misaligned access, you
can more easily port your code to SPARC.
Specify the maximum assumed memory alignment and behavior of mis‐
aligned data accesses. There must be a value for both a (alignment)
and b (behavior). a specifies the maximum assumed memory alignment
and b specifies the behavior for misaligned memory accesses.
For memory accesses where the alignment is determinable at compile
time, the compiler generates the appropriate load/store instruction
sequence for that alignment of data.
For memory accesses where the alignment cannot be determined at
compile time, the compiler must assume an alignment to generate the
needed load/store sequence.
If actual data alignment at runtime is less than the specified
alignment, the misaligned access attempt (a memory read or write)
generates a trap. The two possible responses to the trap are as
follows:
o The OS converts the trap to a SIGBUS signal. If the pro‐
gram does not catch the signal, the program aborts. Even
if the program catches the signal, the misaligned access
attempt will not have succeeded.
o The OS handles the trap by interpreting the misaligned
access and returning control to the program as if the
access had succeeded normally.
Accepted values for a are:
1 Assume at most 1 byte alignment.
2 Assume at most 2 byte alignment.
4 Assume at most 4 byte alignment.
8 Assume at most 8 byte alignment.
16 Assume at most 16 byte alignment.
Accepted values for b are:
i Interpret access and continue execution.
s Raise signal SIGBUS.
f Equivalent to specifying i when a=1, 2, or 4, and s
when a=8 or 16.
You must also specify -xmemalign whenever you want to link to an
object file that was compiled with the value of b set to either i
or f. For a complete list of compiler options that must be speci‐
fied at both compile time and at link time, see the Oracle Devel‐
oper Studio
12.6:
C User's Guide.
Defaults:
The default for 64-bit SPARC programs (-m64) is -xmemalign=8s.
The default for 32-bit SPARC programs (-m32) is -xmemalign=8i.
If you do specify -xmemalign but do not provide a value, the
default is -xmemalign=1i for all platforms.
-xmodel=[a]
(x86) The -xmodel option determines the data address model for
shared objects on the Oracle Solaris x64 platforms and should only
be specified for the compilation of such objects.
This option is invalid when specified with -m32.
a is one of the following:
small
This option generates code for the small model in which the
virtual address of code executed is known at link time and all
symbols are known to be located in the virtual addresses in the
range from 0 to 2^31 - 2^24 - 1.
kernel
Generates code for the kernel model in which all symbols are
defined to be in the range from 2^64 - 2^31 to 2^64 - 2^24.
medium
Generates code for the medium model in which no assumptions are
made about the range of symbolic references to data sections.
Size and address of the text section have the same limits as
the small code model. Applications with large amounts of static
data might require -xmodel=medium when compiling with -m64.
This option is not cumulative so the compiler sets the model value
according to the rightmost instance of -xmodel on the command-line.
If you do not specify -xmodel, the compiler assumes -xmodel=small.
Specifying -xmodel without an argument is an error.
It is not necessary to compile all translation units with this
option. You can compile select files as long as you ensure the
object you are accessing is within reach.
Be aware that not all Linux system support the medium model.
-xnolib
Does not link any libraries by default; that is, no -l options are
passed to the linker ld. Normally, the cc driver passes -lc to ld.
When you use -xnolib, you must pass all -l options explicitly your‐
self.
-xnolibmil
Does not inline math library routines. Use -xnolibmil after the
-fast option, as follows:
cc -fast -xnolibmil ...
-xnolibmopt
(Obsolete). Use -xlibmopt=%none instead. See -xlibmopt.
Use this option after the -fast option on the command line, as in:
example% cc -fast -xnolibmopt ...
-xnorunpath
Do not build a runtime search path for shared libraries into the
executable.
Normally cc does not pass any -R path to the linker. There are a
few options that do pass -R path to the linker such as
-library=sunperf and -xopenmp. The -xnorunpath option can be used
to prevent this.
This option is recommended for building executables that will be
shipped to customers who may have a different path for the shared
libraries that are used by the program.
-xOn
Specifies optimization level (n). (Note the uppercase letter O,
followed by a digit 1, 2, 3, 4, or 5)
Generally, the higher the level of optimization with which a pro‐
gram is compiled, the better runtime performance obtained. However,
higher optimization levels may result in increased compilation time
and larger executable files.
There are five levels that you can use with -xOn. The actual opti‐
mizations performed by the compiler at each level may change with
each compiler release. They are only summarized here.
If the optimizer runs out of memory, it attempts to proceed over
again at a lower level of optimization, resuming compilation of
subsequent routines at the original level.
Values:
-xO1 Do only the basic local optimizations.
-xO2 Do basic local and global optimization. This level
usually gives minimum code size.
-xO3 Adds global optimizations at the function level, and
automatic inlining of functions whose body is smaller
than the overhead of calling the function. In general,
this level, and -xO4, usually result in the minimum
code size when used with the -xspace option.
-xO4 Adds automatic inlining of functions in the same file.
In general, -xO4 results in larger code unless com‐
bined with -xspace.
See -inline to control which routines are inlined.
-xO5 Does the highest level of optimization, suitable only
for the small fraction of a program that uses the
largest fraction of computer time. Uses optimization
algorithms that take more compilation time or that do
not have as high a certainty of improving execution
time. Optimization at this level is more likely to
improve performance if it is done with profile feed‐
back. See -xprofile=collect|use.
The default is no optimization. However, this is only possible if
you do not specify an optimization level. If you specify an opti‐
mization level, there is no option for turning optimization off.
If you are trying to avoid setting an optimization level, be sure
not to specify any option that implies an optimization level. For
example, -fast is a macro option that sets optimization at -xO5.
All other options that imply an optimization level give a warning
message that optimization has been set. The only way to compile
without any optimization is to delete all options from the command
line or make file that specify an optimization level.
If you use -g and the optimization level is -xO3 or lower, the com‐
piler provides best-effort symbolic information with almost full
optimization. Tail-call optimization and back-end inlining are dis‐
abled.
If you use -g and the optimization level is -xO4 or higher, the
compiler provides best-effort symbolic information with full opti‐
mization.
Debugging with -g does not suppress -xOn, but -xOn limits -g in
certain ways. For example, the optimization options reduce the
utility of debugging so that you cannot display variables from dbx,
but you can still use the dbx where command to get a symbolic
traceback. For more information, see Debugging a Program With dbx.
If you specify both -xO and -xmaxopt, the optimization level set
with -xO must not exceed the -xmaxopt value.
See also:
-xldscope, -fast, -xprofile=p, csh(1) man page
Performance Analyzer discusses the effects of the different levels
of optimization on the Analyzer's data.
-xopenmp[={parallel|noopt|none}]
Enable explicit parallelization with OpenMP directives.
The following details the -xopenmp values:
parallel
Enables recognition of OpenMP pragmas. The optimization level
under -xopenmp=parallel is -xO3. The compiler raises the opti‐
mization level to -xO3 if necessary and issues a warning.
This flag also defines the preprocessor macro _OPENMP. The
_OPENMP macro is defined to have the decimal value yyyymm where
yyyy and mm are the year and month designations of the version
of the OpenMP API that the implementation supports. Refer to
the Oracle Developer Studio
12.6:
OpenMP API User's Guide for the value of
the _OPENMP macro for a particular release.
noopt
Enables recognition of OpenMP pragmas. The compiler does not
raise the optimization level if it is lower than -xO3. If you
explicitly set the optimization lower than -xO3, as in cc -xO2
-xopenmp=noopt, the compiler issues an error. If you do not
specify an optimization level with -xopenmp=noopt, the OpenMP
pragmas are recognized, the program is parallelized accord‐
ingly, but no optimization is done. This flag also defines the
preprocessor macro _OPENMP.
none
Does not enable the recognition of OpenMP pragmas, makes no
change to the optimization level of your program, and does not
define any preprocessor macros. This is the default when
-xopenmp is not specified.
If you specify -xopenmp, but do not specify a value, the compiler
assumes -xopenmp=parallel. If you do not specify -xopenmp at all,
the compiler assumes -xopenmp=none.
If you are debugging an OpenMP program with dbx, compile with -g
-xopenmp=noopt so you can breakpoint within parallel regions and
display the contents of variables.
The default for -xopenmp might change in a future release. You can
avoid warning messages by explicitly specifying an appropriate
optimization level.
Use the OMP_NUM_THREADS environment variable to specify the number
of threads to use when running an OpenMP program. If
OMP_NUM_THREADS is not set, the default number of threads used is a
multiple of the number of cores per socket (that is, cores per pro‐
cessor chip), which is less than or equal to the total number of
cores or 32, whichever is less. You can specify a different number
of threads by setting the OMP_NUM_THREADS environment variable, or
by calling the omp_set_num_threads() OpenMP runtime routine, or by
using the num_threads clause on the parallel region directive. For
best performance, the number of threads used to execute a parallel
region should not exceed the number of hardware threads (or virtual
processors) available on the machine. On Oracle Solaris systems,
this number can be determined by using the psrinfo(1M) command. On
Linux systems, this number can be determined by inspecting the file
/proc/cpuinfo. See the Oracle Developer Studio
12.6:
OpenMP API User's Guide for more information.
Nested parallelism is disabled by default. To enable nested paral‐
lelism, you must set the OMP_NESTED environment variable to TRUE.
See the Oracle Developer Studio
12.6:
OpenMP API User's Guide for details.
If you compile and link in seperate steps, specify -xopenmp in both
the compilation step and the link step. When used with the link
step, the -xopenmp option will link with the OpenMP runtime support
library, libmtsk.so.
For up-to-date functionality and performance, make sure that the
latest patch of the OpenMP runtime library, libmtsk.so, is
installed on the system.
For more information about the OpenMP Fortran 95, C, and C++ appli‐
cation program interface (API) for building multithreaded applica‐
tions, see the Oracle Developer Studio
12.6:
OpenMP API User's Guide.
For information that is specific to the C implementation of OpenMP,
see the Oracle Developer Studio
12.6:
C User's Guide.
-xP
Performs only syntax and semantic checking on the source file in
order to print prototypes for all K&R C functions. This option does
not produce any object or executable code.
-xpagesize=n
Set the preferred page size for the stack and the heap.
The n value must be one of the following:
On SPARC: 4K, 8K, 64K, 512K, 2M, 4M, 32M, 256M, 2G, 16G, or
default.
On x86/x64: 4K, 2M, 4M, 1G, or default.
You must specify a valid page size for the target platform. If you
do not specify a valid pagesize, the request is silently ignored at
runtime.
Use the pagesize(1) Oracle Solaris command to determine the number
of bytes in a page. The operating system offers no guarantee that
the page size request will be honored. However, appropriate segment
alignment can be used to increase the likelihood of obtaining the
requested page size. See the -xsegment_align option on how to set
the segment alignment. You can use pmap(1) or meminfo(2) to deter‐
mine page size of the target platform.
The -xpagesize option has no effect unless you use it at compile
time and at link time. For a complete list of compiler options that
must be specified at both compile time and at link time, see the
Oracle Developer Studio
12.6:
C User's Guide.
If you specify -xpagesize=default, the operating system sets the
page size.
This option is a macro for -xpagesize_heap and -xpagesize_stack.
These two options accept the same arguments as -xpagesize. You can
set them both with the same value by specifying -xpagesize=n or you
can specify them individually with different values.
Compiling with this option has the same effect as setting the
LD_PRELOAD environment variable to mpss.so.1 with the equivalent
options, or running the Oracle Solaris command ppgsz(1) with the
equivalent options before running the program. See the Oracle
Solaris man pages for details.
The libhugetlbfs library is required for -xpagesize to work on
Linux. See the Linux libhugetlbfs(7) man page for more information.
-xpagesize_heap=n
Set the page size in memory for the heap.
The n value is the same as for -xpagesize.
You must specify a valid page size for the target platform. If you
do not specify a valid pagesize, the request is silently ignored at
runtime.
See -xpagesize for details.
-xpagesize_stack=n
Set the page size in memory for the stack.
The n value is the same as described for -xpagesize.
You must specify a valid page size for the Oracle Solaris operating
system on the target platform. If you do not specify a valid page‐
size, the request is silently ignored at runtime.
See -xpagesize for details.
-xpatchpadding[={fix|patch|size}]
Reserve an area of memory before the start of each function. If fix
is specified, the compiler will reserve the amount of space
required by fix and continue. This is the default. If either patch
or no value is specified, the compiler will reserve a platform-spe‐
cific default value. A value of -xpatchpadding=0 will reserve 0
bytes of space. The maximum value for size on x86 is 127 bytes and
on SPARC is 2048 bytes.
-xpch=v
This compiler option activates the precompiled-header feature. v
can be auto, autofirst, collect:pch_filename, or use:pch_filename.
You can take advantage of this feature through the -xpch and -xpch‐
stop options in combination with the #pragma hdrstop directive.
Use the -xpch option to create a precompiled-header file and
improve your compilation time. The precompiled-header file is
designed to reduce compile time for applications whose source files
share a common set of include files containing a large amount of
source code. A precompiled header works by collecting information
about a sequence of header files from one source file, and then
using that information when recompiling that source file, and when
compiling other source files that have the same sequence of head‐
ers.
You can let the compiler generate the precompiled-header file for
you automatically. Choose between one of the following two ways to
do this. One way is for the compiler to create the precompiled-
header file from the first include file it finds in the source
file. The other way is for the compiler to select from the set of
include files found in the source file starting with the first
include file and extending through a well-defined point that deter‐
mines which include file is the last one. Use one of the following
two flags to determine which method the compiler uses to automati‐
cally generate a precompiled header:
-xpch=auto
The contents of the precompiled-header file is based on the
longest viable prefix (see the following section for an expla‐
nation of how a viable prefix is identified) that the compiler
finds in the source file. This flag produces a precompiled
header file that consists of the largest possible number of
header files.
-xpch=autofirst
This flag produces a precompiled-header file that contains only
the first header found in the source file.
If you decide to create your precompiled-header file manually, you
must start by first using -xpch and specifying the collect mode.
The compilation command that specifies -xpch=collect must only
specify one source file. In the following example, the -xpch option
creates a precompiled-header file called header.cpch based on the
source file a.c:
cc -xpch=collect:myheader a.cc
A valid precompiled-header filename always has the suffix .cpch.
When you specify pch_filename, you can add the suffix or let the
compiler add it for you. For example, if you specify cc -xpch=col‐
lect:foo a.c, the precompiled-header file is called foo.cpch.
If the compiler cannot use the precompiled-header file, under
-xpch=auto and -xpch=autofirst, it will generate a new precompiled-
header file. If the compiler cannot use the precompiled-header file
under -xpch=use, a warning is issued and the compilation is done
using the real headers.
You can also direct the compiler to use a specific precompiled
header. Specify -xpch=use:pch_filename to do this. You can specify
any number of source files with the same sequence of include files
as the source file used to create the precompiled-header file. For
example, your command in use mode could look like this:
cc -xpch=use:foo.cpch foo.c bar.c foobar.c
You should only use an existing precompiled-header file if the fol‐
lowing is true. If any of the following is not true, you should
recreate the precompiled-header file:
o The compiler that you are using to access the precom‐
piled-header file is the same as the compiler that cre‐
ated the precompiled-header file. A precompiled-header
file created by one version of the compiler may not be
usable by another version of the compiler.
o Except for the -xpch option, the compiler options you
specify with -xpch=use must match the options that were
specified when the precompiled-header file was created.
o The set of included headers you specify with -xpch=use
is identical to the set of headers that were specified
when the precompiled header was created.
o The contents of the included headers that you specify
with -xpch=use is identical to the contents of the
included headers that were specified when the precom‐
piled header was created.
o The current directory (that is, the directory in which
the compilation is occurring and attempting to use a
given precompiled-header file) is the same as the direc‐
tory in which the precompiled-header file was created.
o The initial sequence of pre-processing directives,
including #include directives, in the file you specified
with -xpch=collect are the same as the sequence of pre-
processing directives in the files you specify with
-xpch=use.
To share a precompiled-header file across multiple source files,
those source files must share a common set of include files as
their initial sequence of tokens. A token is a keyword, name or
punctuation mark. Comments and code that is excluded by #if direc‐
tives are not recognized by the compiler as tokens. This initial
sequence of tokens is known as the viable prefix. In other words,
the viable prefix is the top portion of the source file that is
common to all source files. The compiler uses this viable prefix as
the basis for creating a precompiled-header file and thereby deter‐
mining which header files from the source are pre-compiled.
The viable prefix that the compiler finds during the current compi‐
lation must match the viable prefix that it used to create the pre‐
compiled-header file. In other words, the viable prefix must be
interpreted consistently by the compiler across all the source
files that use the same precompiled-header file.
The viable prefix consists of any of the following pre-processor
directives:
o #include
o #if/ifdef/ifndef/else/elif/endif
o #define/undef
o #ident
o #pragma
Any of these may reference macros. The #else, #elif, and #endif
directives must match within the viable prefix. Comments are
ignored.
The compiler determines the end point of the viable prefix automat‐
ically when you specify -xpch=auto or -xpch=autofirst and is
defined as follows. For -xpch=collect or -xpch=use, the viable pre‐
fix ends with a #pragma hdrstop.
o The first declaration/definition statement
o The first #line directive
o A #pragma hdrstop directive
o After the named include file if you specify -xpch=auto
and -xpchstop
o The first include file if you specify -xpch=autofirst
Note: An end point within a conditional statement generates a warn‐
ing and disables the automatic creation of a precompiled-header
file. Also, if you specify both the #pragma hdrstop and the -xpch‐
stop option, then the compiler uses the earlier of the two stop
points to terminate the viable prefix.
Within the viable prefix of each file that shares a precompiled-
header file, each corresponding #define and #undef directive must
reference the same symbol (in the case of #define, each one must
reference the same value). Their order of appearance within each
viable prefix must be the same as well. Each corresponding pragma
must also be the same and appear in the same order across all the
files sharing a precompiled header.
A header file is precompileable when it is interpreted consistently
across different source files. Specifically, when it contains only
complete declarations. That is, a declaration in any one file must
stand alone as a valid declaration. Incomplete type declarations,
such as struct S;, are valid declarations. The complete type decla‐
ration can appear in some other file. Consider these example header
files:
file a.h
struct S {
#include "x.h" /* not allowed */
};
file b.h
struct T; // ok, complete declaration
struct S {
int i;
[end of file, continued in another file] /* not allowed */
A header file that is incorporated into a precompiled-header file
must not violate the following. The results of compiling a program
that violate any of these constraints is undefined.
o The header file must not use __DATE__ and __TIME__.
o The header file must not contain #pragma hdrstop.
When the compiler creates a precompiled-header file automatically,
the compiler writes it to the SunWS_cache directory. This directory
always resides in the location where the object file is created.
Updates to the file are performed under a lock so that it works
properly under dmake.
If you need to force the compiler to rebuild automatically-gener‐
ated precompiled-header files, you can clear the precompiled-header
file cache-directory with the CCadmin tool. See the CCadmin(1) man
page for more information.
The compiler generates dependency information for precompiled-
header files when you specify -xpch=collect. You need to create the
appropriate rules in your make files to take advantage of these
dependencies. Consider this sample make file:
%.o : %.cc shared.cpch
$(cc) -xpch=use:shared -xpchstop=foo.h -c $<
default : a.out
foo.o + shared.cpch : foo.c
$(cc) -xpch=collect:shared -xpchstop=foo.h foo.c -c
a.out : foo.o bar.o foobar.o
$(c) foo.o bar.o foobar.o
clean :
rm -f *.o shared.cpch .make.state a.out
These make rules, along with the dependencies generated by the com‐
piler, force a manually created precompiled-header file to be
recreated if any source file you used with -xpch=collect, or any of
the headers that are part of the precompiled-header file, have
changed. This prevents the use of an out of date precompiled-header
file.
For -xpch=auto or -xpch=autofirst, you do not have to create any
additional make rules in your makefiles.
Warnings:
Do not specify conflicting -xpch flags on the command line. For
example, specifying both -xpch=collect and -xpch=auto, or specify‐
ing both -xpch=autofirst with -xpchstop=<include> generates an
error.
If you specify -xpch=autofirst or you specify -xpch=auto without
-xpchstop, any declaration, definition, or #line directive that
appears prior to the first include file, or appears prior to the
include file that is specified with -xpchstop for -xpch=auto, gen‐
erates a warning and disables the automatic generation of the pre‐
compiled-header file.
A #pragma hdrstop before the first include file under -xpch=aut‐
ofirst or -xpch=auto disables the automatic generation of the pre‐
compiled-header file.
See also: -xpchstop
-xpchstop=[file|<include>]
file is the last include file to be considered in creating a pre‐
compiled-header file. Using -xpchstop on the command line is equiv‐
alent to placing a hdrstop pragma (see the Oracle Developer Studio
12.6:
C User's Guide) after the first include-directive
that references file in each of the source files that you specify
with the cc command.
Use -xpchstop=<include> with -xpch=auto to create a precompiled-
header file that is based on header files up through and including
<include>. This flag overrides the default -xpch=auto behavior of
using all header files contained in the entire viable prefix.
See also: -xpch
-xpec[={yes|no}]
(Oracle Solaris) Generates a Portable Executable Code (PEC) binary.
This option puts the program intermediate representations in the
object file and the binary. This binary may be used later for tun‐
ing and troubleshooting.
A binary that is built with -xpec is usually five to ten times
larger than if it is built without -xpec.
If you do not specify -xpec, the compiler sets it to -xpec=no. If
you specify -xpec, but do not supply a flag, the compiler sets it
to -xpec=yes.
-xpentium
Obsolete. Use -xchip=generic instead.
-xpg
Prepares the object code to collect data for profiling with
gprof(1). Invokes a runtime recording mechanism that produces a
gmon.out file (at normal termination).
Note: There is no advantage for -xprofile if you specify -xpg. The
two do not prepare or use data provided by the other.
Profiles are generated by using prof or gprof on 64-bit Oracle
Solaris platforms or just gprof on 32-bit Oracle Solaris platforms
include approximate user CPU times. These times are derived from PC
sample data (see pcsample(2)) for routines in the main executable
and routines in shared libraries specified as linker arguments when
the executable is linked. Other shared libraries (libraries opened
after process startup using dlopen(3C)) are not profiled.
On 32-bit Oracle Solaris systems, profiles generated using prof(1)
are limited to routines in the executable. 32-bit shared libraries
can be profiled by linking the executable with -xpg and using
gprof(1).
Current Oracle Solaris releases do not include system libraries
compiled with -p. As a result, profiles collected on current Oracle
Solaris platforms do not include call counts for system library
routines.
Note: On x86 systems, -xpg is incompatible with -xregs=frameptr
because the gprof runtime library requires a valid frame pointer to
determine the return address of a profiled routine. Note also that
compiling with -fast on x86 systems will invoke -xregs=frameptr.
Compile with the following instead:
-fast -xregs=no%frameptr -xpg
If you specify -xpg at compile time, you must also specify it at
link time. See the Oracle Developer
Studio
12.6:
C User's Guide for a complete list of options that
must be specified at both compile time and link time.
Note: Binaries compiled with -xpg for gprof profiling should not be
used with binopt(1), as they are incompatible and can result in
internal errors.
-xprefetch[=val[,val]]
Enables prefetch instructions on those architectures that support
prefetch. You must compile with optimization level 3 or greater
with this option.
val must be one of the following:
auto
Enable automatic generation of prefetch instructions.
no%auto
Disable automatic generation.
explicit
Enable explicit prefetch macros.
Explicit prefetching should only be used under special circum‐
stances that are supported by measurements.
no%explicit
Disable explicit prefetch macros.
latx:factor
(SPARC) You can only combine this option with -xprefetch=auto.
Adjust the compiler's assumed prefetch-to-load and prefetch-to-
store latencies by the specified factor. The factor must be a
positive number of the form n.n.
The prefetch latency is the hardware delay between the execu‐
tion of a prefetch instruction and the time the data being
prefetched is available in the cache.
The compiler assumes a prefetch latency value when determining
how far apart to place a prefetch instruction and the load or
store instruction that uses the prefetched data.
Note: the assumed latency between a prefetch and a load may not
be the same as the assumed latency between a prefetch and a
store.
The compiler tunes the prefetch mechanism for optimal perfor‐
mance across a wide range of machines and applications. This
tuning may not always be optimal. For memory-intensive applica‐
tions, especially applications intended to run on large multi‐
processors, you may be able to obtain better performance by
increasing the prefetch latency values. To increase the values,
use a factor that is greater than 1 (one). A value between .5
and 2.0 will most likely provide the maximum performance.
For applications with datasets that reside entirely within the
external cache, you may be able to obtain better performance by
decreasing the prefetch latency values. To decrease the values,
use a factor that is less than one.
To use the latx:factor suboption, start with a factor value
near 1.0 and run performance tests against the application.
Then increase or decrease the factor, as appropriate, and run
the performance tests again. Continue adjusting the factor and
running the performance tests until you achieve optimum perfor‐
mance. When you increase or decrease the factor in small steps,
you will see no performance difference for a few steps, then a
sudden difference, then it will level off again.
yes
(Obsolete) Do not use. Use -xprefetch=auto,explicit instead.
no
(Obsolete) Do not use. Use -xprefetch=no%auto,no%explicit
instead.
Defaults:
If you do not specify -xprefetch, the default is now
-xprefetch=auto,explicit, not -xprefetch=yes. If you specify
-xprefetch without a value, it is also equivalent to
-xprefetch=auto,explicit. This change adversely affects applica‐
tions that have essentially non-linear memory access patterns. To
disable the change, specify -xprefetch=no%auto,no%explicit.
The sun_prefetch.h header file provides the macros that you can use
to specify explicit prefetch instruction. The prefetches will be
approximately at the place in the executable that corresponds to
where the macros appear.
-xprefetch_auto_type=[a]
a is [no%]indirect_array_access.
Use this option to determine whether or not the compiler generates
indirect prefetches for the loops indicated by the option
-xprefetch_level in the same fashion the prefetches for direct mem‐
ory accesses are generated.
If you do not specify a setting for -xprefetch_auto_type, the com‐
piler sets it to -xprefetch_auto_type=no%indirect_array_access.
Options such as -xdepend, -xrestrict, and -xalias_level can affect
the aggressiveness of computing the indirect prefetch candidates
and therefore the aggressiveness of the automatic indirect prefetch
insertion due to better memory alias disambiguation information.
-xprefetch_level=l
Use this option to control the aggressiveness of automatic inser‐
tion of prefetch instructions as determined with -xprefetch=auto.
l must be 1, 2, or 3.
Prefetch levels 2 and 3 may not be effective on older SPARC and x86
platforms.
-xprefetch_level=1 enables automatic generation of prefetch
instructions. -xprefetch_level=2 enables additional generation
beyond level 1 and -xprefetch=3 enables additional generation
beyond level 2.
You must compile with optimization level 3 or greater and generate
code for a platform that supports prefetch.
The default is -xprefetch_level=1 when you specify -xprefetch=auto.
-xprevise={yes|no}
Compile with this option to produce a static analysis of the source
code that can be viewed using the Code Analyzer.
When compiling with -xprevise=yes and linking in a separate step,
include -xprevise=yes also on the link step.
The default is -xprevise=no.
On Linux, -xprevise=yes needs to be specified along with -xanno‐
tate.
See the Oracle Developer Studio Code Analyzer documentation for
further information.
-xprofile=p
Collects data for a profile or use a profile to optimize.
p must be collect[:profdir], use[:profdir], or tcov[:profdir]
This option causes execution frequency data to be collected and
saved during execution, then the data can be used in subsequent
runs to improve performance. Profile collection is safe for multi‐
threaded applications. That is, profiling a program that does its
own multitasking ( -mt ) produces accurate results. This option is
only valid when you specify -xO2 or greater level of optimization.
If compilation and linking are performed in separate steps, the
same -xprofile option must appear on the compile as well as the
link step. See the Oracle Developer Studio
12.6:
C User's Guide for a complete list of options that
must be specified at both compile time and link time.
collect[:profdir]
Collects and saves execution frequency for later use by the
optimizer with -xprofile=use. The compiler generates code to
measure statement execution-frequency.
-xMerge, -ztext, and -xprofile=collect should not be used
together. While -xMerge forces statically initialized data into
read-only storage, -ztext prohibits position-dependent symbol
relocations in read-only storage, and -xprofile=collect gener‐
ates statically initialized, position-dependent symbol reloca‐
tions in writable storage.
The profile directory name profdir, if specified, is the path‐
name of the directory where profile data are to be stored when
a program or shared library containing the profiled object code
is executed. If the pathname is not absolute, it is interpreted
relative to the current working directory when the program is
compiled with the option -xprofile=use:profdir.
If no profile directory name is specified with -xprofile=col‐
lect:prof_dir or -xprofile=tcov:prof_dir, profile data are
stored at runtime in a directory named program.profile where
program is the basename of the profiled process's main program.
In this case, the environment variables SUN_PROFDATA and
SUN_PROFDATA_DIR can be used to control where the profile data
are stored at runtime. If set, the profile data are written to
the directory given by $SUN_PROFDATA_DIR/$SUN_PROFDATA.
If a profile directory name is specified at compilation time,
SUN_PROFDATA_DIR and SUN_PROFDATA have no effect at runtime.
These environment variables similarly control the path and
names of the profile data files written by tcov, as described
in the tcov(1) man page.
If these environment variables are not set, the profile data is
written to the directory profdir.profile in the current direc‐
tory, where profdir is the name of the executable or the name
specified in the -xprofile=collect:profdir flag. -xprofile does
not append .profile to profdir if profdir already ends in .pro‐
file. If you run the program several times, the execution fre‐
quency data accumulates in the profdir.profile directory; that
is, output from prior executions is not lost.
Example[1]: to collect and use profile data in the directory
myprof.profile located in the same directory where the program
is built:
cc -xprofile=collect:myprof.profile -xO5 prog.c -o prog
./prog
cc -xprofile=use:myprof.profile -xO5 prog.c -o prog
Example[2]: to collect profile data in the directory
/bench/myprof.profile and later use the collected profile data
in a feedback compilation at optimization level -xO5:
cc -xprofile=collect:/bench/myprof.profile -xO5 prog.c -o prog
...run prog from multiple locations...
cc -xprofile=use:/bench/myprof.profile -xO5 prog.c -o prog
If you are compiling and linking in separate steps, make sure
that any object files compiled with -xprofile=collect are also
linked with -xprofile=collect.
See also the ENVIRONMENT VARIABLES section of this man page
below for descriptions of environment variables that control
asynchronous profile collections.
use[:profdir]
Uses execution frequency data collected from code compiled with
-xprofile=collect[:profdir] or -xprofile=tcov[:profdir] to
optimize for the work performed when the profiled code was exe‐
cuted. profdir is the pathname of a directory containing pro‐
file data collected by running a program that was compiled with
-xprofile=collect[:profdir] or -xprofile=tcov[:profdir].
To generate data that can be used by both tcov and -xpro‐
file=use[:profdir], the same profile directory must be speci‐
fied at compilation time, using the option -xpro‐
file=tcov[:profdir]. To minimize confusion, specify profdir as
an absolute pathname.
The profdir is optional. If profdir is not specified, the name
of the executible binary is used. a.out is used if -o is not
specified. The compiler looks for profdir.profile/feedback, or
a.out.profile/feedback without profdir specified. For example:
cc -xprofile=collect -o myexe prog.c
cc -xprofile=use:myexe -xO5 -o myexe prog.c
The program is optimized by using the execution frequency data
previously generated and saved in the feedback files written by
a previous execution of the program compiled with -xpro‐
file=collect.
Except for the -xprofile option, the source files and other
compiler options must be exactly the same as those used for the
compilation that created the compiled program which in turn
generated the feedback file. The same version of the compiler
must be used for both the collect build and the use build as
well.
If compiled with -xprofile=collect:profdir, the same profile
directory name profdir must be used in the optimizing compila‐
tion: -xprofile=use:profdir.
See also -xprofile_ircache for speeding up compilation between
collect and use phases.
tcov[:profdir]
Instrument object files for basic block coverage analysis using
tcov(1).
If the optional :profdir argument is specified, the compiler
will create a profile directory at the specified location. The
data stored in the profile directory can be used either by
tcov(1) or by the compiler with -xprofile=use:profdir.
If the optional :profdir argument is omitted, a profile direc‐
tory will be created when the profiled program is executed. The
data stored in the profile directory can only be used by
tcov(1). The location of the profile directory can be con‐
trolled using environment variables SUN_PROFDATA and SUN_PROF‐
DATA_DIR. See ENVIRONMENT below.
If the location specified by :profdir is not absolute, it is
interpreted relative to the current working directory when the
program is compiled.
If :profdir is specified for any object file, the same location
must be specified for all object files in the same program. The
directory whose location is specified by :profdir must be
accessible from all machines where the profiled program is to
be executed. The profile directory should not be deleted until
its contents are no longer needed, because data stored there by
the compiler cannot be restored except by recompilation.
Example 1: If object files for one or more programs are com‐
piled with -xprofile=tcov:/test/profdata, a directory named
/test/profdata.profile will be created by the compiler and used
to store data describing the profiled object files. The same
directory will also be used at execution time to store execu‐
tion data associated with the profiled object files.
Example 2: If a program named "myprog" is compiled with -xpro‐
file=tcov and executed in the directory /home/joe, the direc‐
tory /home/joe/myprog.profile will be created at runtime and
used to store runtime profile data.
-xprofile_ircache[=path]
(SPARC) Use -xprofile_ircache[=path] with -xprofile=collect|use to
improve compilation time during the use phase by reusing compila‐
tion data saved from the collect phase.
With large programs, compilation time in the use phase can improve
significantly because the intermediate data is saved. Note that the
saved data could increase disk space requirements considerably.
When you use -xprofile_ircache[=path], path overrides the location
where the cached files are saved. By default, these files are saved
in the same directory as the object file. Specifying a path is use‐
ful when the collect and use phases happen in two different direc‐
tories.
Here's a typical sequence of commands:
example% cc -xO5 -xprofile=collect -xprofile_ircache t1.c t2.c
example% a.out // run collects feedback data
example% cc -xO5 -xprofile=use -xprofile_ircache t1.c t2.c
-xprofile_pathmap=collect_prefix:use_prefix
(SPARC) Use the -xprofile_pathmap option when you are also specify‐
ing the -xprofile=use command. Use -xprofile_pathmap when both of
the following are true and the compiler is unable to find profile
data for an object file that is compiled with -xprofile=use.
o You are compiling the object file with -xprofile=use in
a directory that is different from the directory in
which the object file was previously compiled with
-xprofile=collect.
o Your object files share a common basename in the profile
but are distinguished from each other by their location
in different directories.
The collect-prefix is the prefix of the UNIX pathname of a direc‐
tory tree in which object files were compiled using -xprofile=col‐
lect.
The use-prefix is the prefix of the UNIX pathname of a directory
tree in which object files are to be compiled using -xprofile=use.
If you specify multiple instances of -xprofile_pathmap, the com‐
piler processes them in the order of their occurrence. Each use-
prefix specified by an instance of -xprofile_pathmap is compared
with the object file pathname until either a matching use-prefix is
identified or the last specified use-prefix is found not to match
the object file pathname.
-xreduction
Analyzes loops for reduction in automatic parallelization. This
option is valid only if -xautopar is also specified. Otherwise the
compiler issues a warning.
When a reduction recognition is enabled, the compiler parallelizes
reductions such as dot products, maximum and minimum finding. These
reductions yield different roundoffs from those obtained by unpar‐
allelized code.
-xregs=r[,r...]
Specify the usage of registers for the generated code.
r is a comma-separated list of one or more of the following subop‐
tions: appl, float, frameptr.
Prefixing a suboption with no% disables that suboption.
Example: -xregs=appl,no%float
Note that -xregs suboptions are restricted to specific hardware
platforms.
appl (SPARC)
Allow the compiler to generate code using the application reg‐
isters as scratch registers. The application registers are g2,
g3, and g4 on 32-bit platforms) and g2 and g3 on 64-bit plat‐
forms.
It is strongly recommended that all system software and
libraries be compiled using -xregs=no%appl. System software
(including shared libraries) must preserve these registers'
values for the application. Their use is intended to be con‐
trolled by the compilation system and must be consistent
throughout the application.
In the SPARC ABI, these registers are described as application
registers. Using these registers can increase performance
because fewer load and store instructions are needed. However,
such use can conflict with some old library programs written in
assembly code.
For more information on SPARC instruction sets, see -xarch.
float (SPARC)
Allow the compiler to generate code by using the floating-point
registers as scratch registers for integer values. Floating-
point values may use these registers regardless of this option.
To generate binary code free of all references to floating
point registers, use -xregs=no%float and make sure your source
code does not in any way use floating point types.
float (X86)
Allow the compiler to generate code by using the floating-point
registers as scratch registers. Floating-point values may use
these registers regardless of this option. To generate binary
code free of all references to floating point registers, use
-xregs=no%float and make sure your source code does not in any
way use floating point types. During code generation the com‐
pilers will attempt to diagnose code that results in the use of
floating point, simd, or x87 instructions.
frameptr (x86)
Allow the compiler to use the frame-pointer register (%ebp on
IA32, %rbp on x86 64-bit platforms) as a general-purpose regis‐
ter.
The default is -xregs=no%frameptr.
The C++ compiler ignores -xregs=frameptr unless exceptions are
also disabled with -features=no%except. Note also that
-xregs=frameptr is part of -fast, but is ignored by the C++
compiler unless -features=no%except is also specified.
With -xregs=frameptr the compiler is free to use the frame-
pointer register to improve program performance. However, some
features of the debugger and performance measurement tools may
be limited. Stack tracing, debuggers, and performance analyzers
cannot report on functions compiled with -xregs=frameptr.
Also, C++ calls to Posix pthread_cancel() will fail trying to
find cleanup handlers.
Mixed C, Fortran, and C++ code should not be compiled with
-xregs=frameptr if a C++ function, called directly or indi‐
rectly from a C or Fortran function, can throw an exception. If
compiling such mixed source code with -fast, add
-xregs=no%frameptr after the -fast option on the command line.
With more available registers on 64-bit platforms, compiling
with -xregs=frameptr has a better chance of improving 32-bit
code performance than 64-bit code.
Note: -xregs=frameptr is ignored and a warning is issued by the
compiler if you also specify -xpg.
Also, -xkeepframe overrides -xregs=frameptr.
The SPARC default is -xregs=appl,float. The x86 default is
-xregs=no%frameptr,float. -xregs=frameptr is included in the expan‐
sion of -fast on x86.
It is strongly recommended that you compile code intended for
shared libraries that will link with applications, with
-xregs=no%appl,float. At the very least, the shared library should
explicitly document how it uses the application registers so that
applications linking with those libraries are aware of these regis‐
ter assignments.
For example, an application using the registers in some global
sense (such as using a register to point to some critical data
structure) would need to know exactly how a library with code com‐
piled without -xregs=no%appl is using the application registers in
order to safely link with that library.
-xrestrict[=f]
Treats pointer-valued function parameters as restricted pointers. f
is %all, %none or a comma-separated list of one or more function
names. This command-line option can be used on its own, but is best
used with optimization of -xO3 or greater.
If a function list is specified with this option, pointer parame‐
ters in the specified functions are treated as restricted; if -xre‐
strict=%all is specified, all pointer parameters in the entire C
file are treated as restricted.
The default is %none. Specifying -xrestrict is equivalent to speci‐
fying -xrestrict=%all.
See also: 'Restricted Pointers' in the Oracle Developer Studio
12.6:
C User's Guide.
-xs[={yes|no}]
(Oracle Solaris) Link debug information from object files into exe‐
cutable.
-xs is the same as -xs=yes. The default for -xdebugformat=dwarf is
the same as -xs=yes.
This option controls the trade-off of executable size versus the
need to retain object files in order to debug. For dwarf, use
-xs=no to keep the executable small but depend on the object files.
For stabs, use -xs or -xs=yes to avoid dependence on the object
files at the cost of a larger executable. This option has almost no
effect on dbx performance or the runtime performance of the pro‐
gram.
When the compile command forces linking (that is, -c is not speci‐
fied) there will be no object file(s) and the debug information
must be placed in the executable. In this case, -xs=no (implicit or
explicit) will be ignored.
The feature is implemented by having the compiler adjust the sec‐
tion flags and/or section names in the object file that it emits,
which then tells the linker what to do for that object file's debug
information. It is therefore a compiler option, not a linker
option. It is possible to have an executable with some object files
compiled -xs=yes and others compiled -xs=no.
Linux compilers accept but ignore -xs. Linux compilers do not
accept -xs={yes|no}.
-xsafe=mem
(SPARC) Allow the compiler to assume that no memory protection vio‐
lations occur.
This option allows the compiler to use the non-faulting load
instruction in 64-bit SPARC architecture.
Because non-faulting loads do not cause a trap when a fault such as
address misalignment or segmentation violation occurs, you should
use this option only for programs in which such faults cannot
occur. Because few programs incur memory-based traps, you can
safely use this option for most programs. Do not use this option
for programs that explicitly depend on memory-based traps to handle
exceptional conditions.
This option takes effect only when used with optimization level
-xO5 and one of the following -xarch values: sparc, sparcvis, spar‐
cvis2, or sparcvis3 for both -m32 and -m64.
-xsecure_code_analysis{=[yes|no]}
Enable or disable compiler secure code analysis to find and display
possible memory safety violations at compile time. Secure code
analysis runs in parallel with the compilation process and may
result in increased compile time.
If -xsecure_code_analysis is not specified or if it is specified
without a yes|no argument, the default is -xsecure_code_analy‐
sis=yes.
Use -xsecure_code_analysis=no to disable secure code analysis.
-xsegment_align=n
(Oracle Solaris) This option causes the driver to include a special
mapfile on the link line. The mapfile aligns the text, data, and
bss segments to the value specified by n. When using very large
pages, it is important that the heap and stack segments are aligned
on an appropriate boundary. If these segments are not aligned,
small pages will be used up to the next boundary, which could cause
a performance degradation. The mapfile ensures that the segments
are aligned on an appropriate boundary.
The n value must be one of the following:
SPARC: The following values are valid: 8K, 64K, 512K, 2M, 4M, 32M,
256M, 1G, and none.
x86: The following values are valid: 4K, 8K, 64K, 512K, 2M, 4M,
32M, 256M, 1G, and none.
The default for both SPARC and x86 is none.
Recommended usage is as follows:
SPARC 32-bit compilation: -xsegment_align=64K
SPARC 64-bit compilation: -xsegment_align=4M
x86 32-bit compilation: -xsegment_align=8K
x86 64-bit compilation: -xsegment_align=4M
The driver will include the appropriate mapfile. For example, if
the user specifies -xsegment_align=4M, the driver adds -M install-
directory/lib/compilers/mapfiles/map.4M.align to the link line,
where install-directory is the installation directory. The afore‐
mentioned segments will then be aligned on a 4M boundary.
-xsfpconst
Represents unsuffixed floating-point constants as single precision,
instead of the default mode of double precision. Not valid with
-pedantic.
-xspace
Does no optimizations that increase code size. Does not parallelize
loops if it increases code size. Example: Does not unroll loops.
-xstrconst
This option may be deprecated in a future release. Use -fea‐
tures=[no%]conststrings instead.
The -xstrconst option inserts string literals into the read-only
data section of the text segment instead of the default data seg‐
ment. Duplicate strings will be eliminated and the remaining copy
shared amongst references in the code.
-xtarget=t
Specifies the target system for the instruction set and optimiza‐
tion.
t must be one of: native, generic, or system-name.
Each specific value for -xtarget expands into a specific set of
values for the -xarch, -xchip, and -xcache options.
Use the -xdryrun option to determine the expansion of -xtar‐
get=native on a running system.
For example, -xtarget=T3 is equivalent to -xchip=T3
-xcache=8/16/4:6144/64/24 -xarch=sparcvis3.
cc -dryrun -xtarget=T3 |& grep ###
### command line files and options (expanded):
### -dryrun -xchip=T3 -xcache=8/16/4:6144/64/24 -xarch=sparcvis3
The data type model, either 32-bit or 64-bit, is indicated by the
-m32|-m64 option. To specify the 64-bit data type model, use the
-m64 option as follows:
-xtarget=<value> ... -m64
To specify the 32-bit data type model, use the -m32 option as fol‐
lows:
-xtarget=<value> ... -m32
See also the -m32|-m64 option for a discussion of the default data
type model.
The expansion of -xtarget for a specific host system might not
expand to the same -xarch, -xchip, or -xcache settings as -xtar‐
get=native when compiling on that system.
The following values for t are valid on all systems:
native
Equivalent to
âxarch=native âxchip=native âxcache=native
to give best performance on the host system.
generic
Equivalent to
âxarch=generic âxchip=generic âxcache=generic
to give best performance on most systems. This is the default.
system-name
Get the best performance for the specified system.
Select a system name from the following lists that represents
the actual system you are targeting.
Valid SPARC system names are: sparc64vi (Obsolete), sparc64vii
(Obsolete), sparc64viiplus, sparc64x, sparc64xplus, sparc64xii,
ultraT1 (Obsolete), ultraT2 (Obsolete), ultraT2plus, T3 (Obso‐
lete), T4, T5, T7, M5, M6, and M7.
Valid x86 system names are: skylake, haswell, ivybridge,
nehalem, barcelona (Obsolete), pentium (Obsolete), pentium_pro
(Obsolete), pentium3 (Obsolete), pentium4, penryn, sandybridge,
westmere, woodcrest, and broadwell.
-xtemp=path
Equivalent to -temp=path.
-xthreadvar[=o]
Works in conjunction with the __thread declaration specifier to
take advantage of the compiler's thread-local storage facility.
After you declare the thread variables with the __thread specifier,
use -xthreadvar to enable the use of thread-local storage with
position dependent code (non-PIC code) in dynamic (shared)
libraries. For more information on how to use __thread, see the
Oracle Developer Studio
12.6:
C User's Guide.
o must be the following:
[no%]dynamic
Compile variables for dynamic loading. Prefix no% disables the
option. Access to thread variables is significantly faster when
-xthreadvar=no%dynamic but you cannot use the object file
within a dynamic library. That is, you can only use the object
file in an executable file.
If you do not specify -xthreadvar, the default used by the compiler
depends upon whether or not position-independent code is enabled.
If position-independent code is enabled, the option is set to
-xthreadvar=dynamic. If position-independent code is disabled, the
option is set to -xthreadvar=no%dynamic.
If you specify -xthreadvar but do not specify any arguments, the
option is set to -xthreadvar=dynamic.
If there is non-position-independent code within a dynamic library,
you must specify -xthreadvar.
The linker cannot support the thread-variable equivalent of non-PIC
code in dynamic libraries. Non-PIC thread variables are signifi‐
cantly faster, and hence should be the default for executables.
If there is non-position-independent code within a dynamic library,
you must specify -xthreadvar.
Using thread variables on different versions of Oracle Solaris
software requires different options on the command line.
See also: -xcode, -KPIC, -Kpic
-xthroughput[={yes|no}]
The -xthroughput option tells the compiler that the application
will be run in situations where many processes are simultaneously
running on the system.
If -xthroughput=yes, the compiler will favor optimizations that
slightly reduce performance for a single process while improving
the amount of work achieved by all the processes on the system. As
an example, the compiler might choose to be less aggressive in
prefetching data. Such a choice would reduce the memory bandwidth
consumed by the process, and as such the process may run slower,
but it would also leave more memory bandwidth to be shared among
other processes.
The default is -xthroughput=no.
-xtime
Reports the time and resources used by each compilation.
-xtransition(obsolete)
Issues warnings for differences between K&R C and ISO C. The
-xtransition option issues messages in conjunction with the -Xa and
-Xt options. You can eliminate all warning messages about differing
behavior through appropriate coding. The -xtransition option will
be removed in a future release.
-xtrigraphs[=[yes|no]]
Enables or disables recognition of trigraph sequences as defined by
the ISO C standard.
-xtrigraphs=yes enables recognition of trigraph sequences in the
source code.
-xtrigraphs=no disables recognition of trigraph sequences in the
source code.
Defaults:
If the -xtrigraphs option is not specified, -xtrigraphs=no is
assumed.
If only -xtrigraphs is specified -xtrigraphs=yes is assumed.
-xunboundsym={yes|no}
Specify whether the program contains references to dynamically
bound symbols.
-xunboundsym=yes means the program contains references dynamically
bound symbols.
-xunboundsym=no means the program does not contain references to
dynamically bound symbols.
The default is -xunboundsym=no.
-xunroll=n
Specifies whether or not the compiler optimizes (unrolls) loops. n
is a positive integer. When n is 1, it is a command and the com‐
piler unrolls no loops. When n is greater than 1, -xunroll=n allows
the compiler to unroll loops n times.
-xustr={ascii_utf16_ushort|no}
Specify -xustr=ascii_utf16_ushort if you need to support an inter‐
nationalized application that uses ISO10646 UTF-16 string literals.
In other words, use this option if your code contains string liter‐
als that you want the compiler to convert to UTF-16 strings in the
object file. Without this option, the compiler neither produces nor
recognizes sixteen-bit character string literals. This option
enables recognition of the U"ASCII_string" string literals as an
array of unsigned short int. Since such strings are not yet part of
any standard, this option enables recognition of non-standard C.
You can turn off compiler recognition of U"ASCII_string" string
literals by specifying -xustr=no. The rightmost instance of this
option on the command line overrides all previous instances.
The default is -xustr=no. If you specify -xustr without an argu‐
ment, the compiler won't accept it and instead issues a warning.
The default can change if the C or C++ standards define a meaning
for the syntax.
It is not an error to specify -xustr=ascii_ustf16_ushort without
also specifying a U"ASCII_string" string literal.
When specifying the flag -xustr=ascii_utf16_ushort, one of the fol‐
lowing options must also be specified: -Xc, -Xa, -Xt, -Xs, -xc99,
-std=c99, -std=c89, -std=c90, -std=gnu89, -std=gnu90, -std=gnu99
or -ansi.
Not all files have to be compiled with this option.
The following example shows a string literal in quotes that is
prepended by U. It also shows a command line that specifies -xustr.
example% cat file.c
const unsigned short *foo = U"foo";
const unsigned short bar[] = U"bar";
const unsigned short *fun() { return
example% cc -xustr=ascii_utf16_ushort file.c -c
-xvector[=a]
Enables automatic generation of calls to the vector library or the
generation of the SIMD (Single Instruction Multiple Data) instruc‐
tions on processors that support SIMD. You must use default round‐
ing mode by specifying -fround=nearest when you use this option.
The -xvector option requires optimization level -xO3 or greater.
The option is silently ignored if the optimization level is lower
than -xO3.
a is the equivalent of the following. Prefix no% disables a subop‐
tion.
[no%]lib
(Oracle Solaris) Enables the compiler to transform math library
calls within loops into single calls to the equivalent vector
math routines when such transformations are possible. This
could result in a performance improvement for loops with large
loop counts. Use no%lib to disable this option.
[no%]simd
(SPARC) For -xarch=sparcace, -xarch=sparcaceplus and
-xarch=sparcace2, directs the compiler to use floating point
and integral SIMD instructions to improve the performance of
certain loops. Contrary to that of the other SPARC -xarch val‐
ues under -xarch=sparcace, -xarch=sparcaceplus and
-xarch=sparcace2, -xvector=simd is in effect unless -xvec‐
tor=none or -xvector=no%simd has been specified. In addition
-xO4 or greater is required for -xvector=simd, otherwise -xvec‐
tor=simd is ignored.
For all other -xarch values, directs the compiler to use the
Visual Instruction Set [VIS1, VIS2, ViS3, etc.] SIMD instruc‐
tions to improve the performance of certain loops. Basically
with explicit -xvector=simd option, the compiler will perform
loop transformation enabling the generation of special vector‐
ized SIMD instructions to reduce the number of loop iterations.
In addition to the optimization level requirement noted below,
the -xvector=simd option is effective only if -xarch=sparcvis3
and above.
[no%]simd
(x86) Directs the compiler to use the native x86 SSE SIMD
instructions to improve performance of certain loops. Streaming
extensions are used on x86 by default at optimization level 3
and above where beneficial. Use no%simd to disable this option.
The compiler will use SIMD only if streaming extensions exist
in the target architecture; that is, if target ISA is at least
SSE2. For example, you can specify -xtarget=woodcrest,
-xarch=generic, -xarch=sse2, -xarch=sse3,
or -fast on a modern platform to use it. If the target ISA has
no streaming extensions, the suboption will have no effect.
%none
Disables this option entirely.
yes
This option is deprecated, specify -xvector=lib instead.
no
This option is deprecated, specify -xvector=%none instead.
On x86, the default is -xvector=simd. On SPARC, the default is
-xvector=simd under -xarch=sparcace, -xarch=sparcaceplus and
--xarch=sparcace2, and -xvector=%none on other SPARC -xarch values.
If you specify -xvector without a suboption, the compiler assumes
-xvector=simd,lib on x86 Oracle Solaris, -xvector=lib on SPARC Ora‐
cle Solaris, and -xvector=simd on Linux platforms.
This option overrides previous instances so -xvector=%none undoes a
previously specified -xvector=lib.
The compiler includes the libmvec libraries in the load step.
Note: -xvector=%none should be used when compiling Oracle Solaris
kernel code for x86 platforms.
If you compile and link with separate commands, be sure to use the
same option for both compilation and linking.
-xvis[={yes|no}]
(SPARC) Compile with -xvis=yes when including the <vis.h> header to
generate VIS instructions, or when using assembler inline code
(.il) that uses VIS instructions. The default is -xvis=no. Specify‐
ing -xvis is equivalent to specifying -xvis=yes.
The VIS[tm] instruction set is an extension to the SPARC V9
instruction set. Even though the UltraSPARC processors are 64-bit,
there are many cases, especially in multimedia applications, when
the data are limited to eight or 16 bits in size. The VIS instruc‐
tions can process four 16-bit data with one instruction so they
greatly improve the performance of applications that handle new
media such as imaging, linear algebra, signal processing, audio,
video and networking.
-xvpara
Issues warnings about potential parallel-programming related prob‐
lems that may cause incorrect results when using OpenMP. Use with
-xopenmp and OpenMP API directives.
The compiler issues warnings when it detects the following situa‐
tions:
o Loops are parallelized using MP directives when there
are data dependencies between different loop iterations
o OpenMP data-sharing attributes-clauses are problematic.
For example, declaring a variable "shared" whose
accesses in an OpenMP parallel region may cause data
race, or declaring a variable "private" whose value in a
parallel region is used after the parallel region.
No warnings appear if all parallelization directives are processed
without problems.
Example:
cc -xopenmp -xvpara any.c
-Yc, dir
Specifies a new directory dir for the location of component c. c
can consist of any of the characters representing tools listed
under the -W option.
If the location of a tool is being specified, then the new path
name for the tool will be dir/tool. If more than one -Y option is
applied to any one item, then the last occurrence holds.
-YA, dir
Specifies a directory dir to search for all compiler components. If
a component is not found in dir, the search reverts to the direc‐
tory where the compiler is installed.
-YI, dir
Changes default directory searched for include files.
-YP, dir
Changes default directory for finding libraries files.
-YS, dir
Changes default directory for startup object files.
cc recognizes -a, -e, -r, -t, -u, and -z and passes these options and
their arguments to ld. cc also passes any unrecognized options to ld
with a warning.
NOTES
errno
Certain floating-point math library routines will return error status
in the errno variable (defined in errno.h). With options -fast ,
-xbuiltin, -xlibmieee, -xlibmil, and -xlibmopt, the compiler is free to
replace calls to floating point functions with equivalent optimized
code that does not set the errno variable. Further, -fast also defines
the macro __MATHERR_ERRNO_DONTCARE, which allows the compiler to assume
that math functions need not set errno. As a result, user code that
relies on the value of errno or a floating-point exception being raised
after a floating point function call could produce inconsistent
results.
One way around this problem is to avoid compiling such codes with
-fast.
However, if -fast optimization is required and the code depends on the
value of errno being set properly or an appropriate floating-point
exception being raised after floating-point library calls, you should
compile with the options
-xbuiltin=none -U__MATHERR_ERRNO_DONTCARE \
-xlibmopt=%none -xnolibmil
following -fast on the command line to inhibit the compiler from opti‐
mizing out such library calls and to to ensure that calls to math func‐
tions set errno as documented.
New Shared Libraries
For Solaris release 10, new shared libraries libxprof.so.1, libx‐
prof_audit.so.1, and libtdf.so.1 must be installed in order to use the
-xprofile option. These libraries are pre-installed on the latest Ora‐
cle Solaris releases.
FLT_ROUNDS
The implementation of FLT_ROUNDS supplied with Studio C for SPARC Linux
behaves as specified in the C standard. It returns the appropriate
value for the current rounding mode. It does not always return the
value 1 specified in the manpage that describes the functions defined
in the standard C header <fenv.h>.
Predefined Identifier __STDC__
On Oracle Solaris, the predefined macro __STDC__ has the value 0 when
one of the flags -Xt, -Xa or -std without -pedantic flag has been spec‐
ified, and 1 when either the -Xc or -pedantic flag has been specified.
__STDC__ is not defined for -Xs.
On Linux, __STDC__ has the value 1.
PRAGMAS
The following #pragmas are recognized by the compilation system:
#pragma align
#pragma c99
#pragma does_not_read_global_data
#pragma does_not_return
#pragma does_not_write_global_data
#pragma error_messages
#pragma fini
#pragma hdrstop
#pragma ident
#pragma init
#pragma [no_]inline
#pragma [no_]warn_missing_parameter
#pragma int_to_unsigned
#pragma opt
#pragma pack
#pragma rarely_called
#pragma redefine_extname
#pragma returns_new_memory
#pragma struct_align
#pragma unknown_control_flow
#pragma weak
#pragma does_not_read_global_data
#pragma does_not_write_global_data
#pragma no_side_effect
See also the Oracle Developer Studio
12.6:
OpenMP API User's Guide for a list of supported OpenMP 2.5
directives.
SPARC Only:
#pragma nomemorydepend
#pragma no_side_effect
#pragma pipeloop
#pragma unroll
Refer to the Oracle Developer Studio
12.6:
C User's Guide for more information on these pragmas.
ENVIRONMENT VARIABLES
The following is a list of environment variables that you can set along
with a brief description of their function.
LINT_OPTIONS
A default set of options to lint. LINT_OPTIONS is interpreted by
lint as though its value had been placed on the command line, imme‐
diately following the name used to invoke lint, as in:
lint $LINT_OPTIONS ... other-arguments ...
TMPDIR
cc normally creates temporary files in the directory tmp. You may
specify another directory by setting the environment variable
TMPDIR to your chosen directory. (If TMPDIR isn't a valid direc‐
tory, then cc will use tmp). The -xtemp option has precedence over
the TMPDIR environment variable.
SUNPRO_SB_INIT_FILE_NAME
(Obsolete) The source browser functionality is no longer supported.
SUN_PROFDATA=profdir
If set, store profile data collected from a program compiled with
-xprofile=collect in a directory named profdir in the current work‐
ing directory at the time that the program is executed. If the
optional argument :profdir was specified in -xprofile=col‐
lect[:profdir] at compilation time, SUN_PROFDATA as no effect.
SUN_PROFDATA_DIR=dirname
If set, store profile data collected from a program compiled with
-xprofile=collect in a directory whose UNIX dirname is dirname. If
dirname is not absolute, it is interpreted relative to the current
working directory at the time that the program is executed. If the
optional argument :profdir was specified in -xprofile=col‐
lect[:profdir] at compilation time, SUN_PROFDATA_DIR has no effect.
SUN_PROFDATA_REPLACE={objfile,program,all}
The value of the environment variable SUN_PROFDATA_REPLACE indi‐
cates the scope of profile data to be reset when a changed version
of an object file is detected at runtime. Use SUN_PROFDATA_REPLACE
to ensure that profile data are consistent with the profiled pro‐
gram within the specified unit of program scope.
The values of SUN_PROFDATA_REPLACE and their meanings are as fol‐
lows:
objfile
Reset profile data of changed object file.
program
Reset profile data of all object files in program containing
changed object file.
all
Reset entire contents of profile directory if any object file
has changed.
The default setting of SUN_PROFDATA_REPLACE is SUN_PROF‐
DATA_REPLACE=objfile .
Example:
% setenv SUN_PROFDATA_REPLACE program (csh)
$ export SUN_PROFDATA_REPLACE=program (ksh)
With this setting, when a program containing a changed object file
is executed, all object files in the program will have their pro‐
file data reset. Relevant options include -xOn and -xipo=n.
SUN_PROFDATA_ASYNC_INTERVAL=async_interval
Set this environment variable to enable asynchronous profile col‐
lection. In asynchronous profile collection, profile data are col‐
lected from a running process at regular intervals whose duration
is specified in units of seconds.
SUN_PROFDATA_ASYNC_INTERVAL has no effect unless one of the envi‐
ronment variables LD_AUDIT, LD_AUDIT_32, or LD_AUDIT_64 is set to
/usr/lib/{,64}/libxprof_audit.so.1.
Asynchronous profile collection requires an MT-safe, mmap based
memory allocator, such as libumem(3LIB) with mmap-based allocation
specified by setting UMEM_OPTIONS to backend=mmap.
Example: To enable asynchronous profile collection from a 64 bit
process at 1 minute intervals,specify the following environment
variables:
$ env LD_AUDIT_64=/usr/lib/64/libxprof_audit.so.1 \
SUN_PROFDATA_ASYNC_INTERVAL=60 UMEM_OPTIONS=backend=mmap \
64-bit-program [program-args]
SUN_PROFDATA_ASYNC_VERBOSE=verbose
If set nonzero, enables verbose messages from asynchronous collec‐
tor to stderr. SUN_PROFDATA_ASYNC_VERBOSE has no effect unless
asynchronous profile collection is enabled.
SUN_PROFDATA_CLEANUP_AFTER_EXIT=[0|1]
If set to 1, enables profiler to clean up its data structures
between the time that the process calls exit() and the time that
process exit is complete. If set to 0, avoids destructive interfer‐
ence with profile collection by application threads that have not
terminated before the application calls exit(). See exit(3C) for
details. The default setting is SUN_PROFDATA_CLEANUP_AFTER_EXIT=0.
Refer to Oracle Developer Studio
12.6:
OpenMP API User's Guide for information about the following
environment variables that can be set for an OpenMP program or a pro‐
gram automatically parallelized by the -xautopar option:
o OMP_SCHEDULE
o OMP_NUM_THREADS
o OMP_DYNAMIC
o OMP_PROC_BIND
o OMP_PLACES
o OMP_NESTED
o OMP_STACKSIZE
o OMP_WAIT_POLICY
o OMP_MAX_ACTIVE_LEVELS
o OMP_THREAD_LIMIT
o OMP_CANCELLATION
o OMP_DISPLAY_ENV
o PARALLEL
o SUNW_MP_WARN
o SUNW_MP_THR_IDLE
o SUNW_MP_PROCBIND
o SUNW_MP_MAX_POOL_THREADS
o SUNW_MP_MAX_NESTED_LEVELS
o STACKSIZE
o SUNW_MP_GUIDED_WEIGHT
o SUNW_MP_WAIT_POLICY
FILES
a.out executable output file
bb_link.o tcov support
file.a library of object files
file.c C source file
file.d tcov(1) test coverage input file
file.i C source file after preprocessing
file.il inline(1) expansion file
file.o object file
file.profile The directory for data used by -xprofile
file.s assembler source file
file.so dynamic library
file.tcov output from tcov(1)
acomp compiler front end
cc compiler command line driver
cg code generator (SPARC)
crt1.o runtime startup code
crti.o runtime startup code
crtn.o runtime startup code
fbe assembler
gcrt1.o startup for profiling with gprof(1)
gmon.out default profile file for -xpg
ipo Interprocedural optimizer (SPARC)
iropt global optimizer
libm.so system math library
libmmheap.so.1 memory allocator for Studio compilers and runtimes
libmtsk_db.so.1 debugging support library for -xautopar and
-xopenmp
libmtsk.so.1 runtime library for -xautopar and -xopenmp
libmvec.so.1 system vector math library
libredblack.so bids support
libstkovf.so.1 runtime library for stack overflow diagnosis
libsunmath.so.1 system math library extensions
libsunperf.so Sun Performance library
libtdf.so.1 file access library for -xprofile
libxprof_audit.so.1 linker audit library for -xprofile
libxprof.so.1 runtime library for -xprofile
llib-lm system math lint library
llib-lm.ln system math lint library
llib-lsunmath System math extensions lint library
llib-lsunmath.ln System math extensions lint library
mcrt1.o start-up for profiling with prof(1) and intro(3)
misalign.o misalign data support (SPARC)
mon.out default profile file for -p
postopt postoptimizer (SPARC)
ssbd Static synchronization bug detection (Oracle
Solaris Operating Environment)
stack_grow.o stack overflow checking (SPARC)
SunWS_cache The directory used to store data when the -xpch
option is used.
ube optimizer, code generator (x86)
ube_ipa Interprocedural analyzer (x86)
values-xa.o -Xa support
values-xc.o -Xc support
values-xpg4.o xpg4 support
values-xpg6.o SUSv3 support
values-xs.o -Xs support
values-xt.o -Xt support
xprof_fini.o Initialization and finalization handlers for pro‐
grams compiled with -xprofile=collect
SEE ALSO
analyzer(1), as(1), c89(1), c99(1), cflow(1), cscope(1), ctags(1),
ctrace(1), dbx(1), er_src(1), indent(1), ld(1), lint(1), prof(1), sun‐
studio(1), version(1), psrinfo(1M), tmpnam(3C), inline(4)
Oracle Developer Studio
12.6:
C User's Guide
Oracle Developer Studio
12.6:
OpenMP API User's Guide
The ISO/IEC 9899-1990 Programming Language - C standard
The ISO/IEC 9899-1999 Programming Language - C standard
Studio 12.6 May 2017 cc(1)