Copyright © 2006, 2007. QLogic Corporation. All rights reserved.
-L
MPI wrapper script for a C compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile programs for MPI.
-L
MPI wrapper script for a C compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
-L
MPI wrapper script for a C compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile programs for MPI.
-L
MPI wrapper script for a FORTRAN 90/95 compiler.
The wrapper script provides all the needed include directories and
libraries needed to compile FORTRAN programs for MPI.
This option is used to indicate that the host system's integers are 32-bits wide, and longs and pointers are 64-bits wide. Not all benchmarks use this macro.
SPEC_MPI_DOUBLE_UNDERSCORE may be used in SPEC MPI2007.
This option is used to indicate that the host system's integers are 32-bits wide, and longs and pointers are 64-bits wide. Not all benchmarks use this macro.
This option is used to indicate that the host system's integers are 32-bits wide, and longs and pointers are 64-bits wide. Not all benchmarks use this macro.
This flag should be used if C function names need to have two underscores appended in order for them to be callable by Fortran functions.
SPEC_MPI_DOUBLE_UNDERSCORE may be used in SPEC MPI2007.
This macro indicates that the benchmark is being compiled on a Linux system.
This option is used to indicate that the host system's integers are 32-bits wide, and longs and pointers are 64-bits wide. Not all benchmarks use this macro.
This option is used to indicate that the host system's integers are 32-bits wide, and longs and pointers are 64-bits wide. Not all benchmarks use this macro.
CFP2006:
If -funderscoring is in effect, and the original Fortran external identifier contained an underscore, -fsecond-underscore appends a second underscore to the one added by -funderscoring. -fno-second-underscore does not append a second underscore. The default is both -funderscoring and -fsecond-underscore, the same defaults as g77 uses. -fno-second-underscore corresponds to the default policies of PGI Fortran and Intel Fortran.
This option is used to indicate that the host system's integers are 32-bits wide, and longs and pointers are 64-bits wide. Not all benchmarks use this macro.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Equivalent to -O3 -ipa -OPT:Ofast -fno-math-errno -ffast-math.
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
NOTE: -Ofast enables -ipa (inter-procedural analysis), which places limitations on how libraries and .o files are built.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-CG:local_fwd_sched : Change the instruction scheduling algorithm to work forward instead of backward for the instructions in each basic block. The default is OFF for 64-bit ABI, and ON for 32-bit ABI.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
Compiler will optimize code for selected platform. The default value, auto, means to optimize for the platform on which the compiler is running, as determined by reading /proc/cpuinfo. anyx86 means a generic 32-bit x86 processor without SSE2 support.
Equivalent to -O3 -ipa -OPT:Ofast -fno-math-errno -ffast-math.
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
NOTE: -Ofast enables -ipa (inter-procedural analysis), which places limitations on how libraries and .o files are built.
-OPT:malloc_alg=(0|1)
Select an alternate malloc algorithm which may improve speed.
The compiler adds setup code in the
C/C++/Fortran "main" function to enable the chosen algorithm.
The default is 0.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-LANG:copyinout : When an array section is passed as the actual argument in a call, the compiler sometimes copies the array section to a temporary array and passes the temporary array, thus promoting locality in the accesses to the array argu- ment. This optimization is relevant only to Fortran, and this flag controls the aggressiveness of this optimization. The default is ON for -O2 or higher and OFF otherwise.
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
-IPA:max_jobs=N : This option limits the maximum parallelism when invoking the compiler after IPA to (at most) N compilations running at once. The option can take the following values:
0 = The parallelism chosen is equal to either the number of CPUs, the number of cores, or the number of hyperthreading units in the compiling system, whichever is greatest.
1 = Disable parallelization during compilation (default)
>1 = Specifically set the degree of parallelism
This section contains descriptions of flags that were included implicitly by other flags, but which do not have a permanent home at SPEC.
Specify the basic level of optimization desired.
The options can be one of the following:
0 Turn off all optimizations.
1 Turn on local optimizations that can be done quickly. Do peephole optimizations and instruction scheduling.
2 Turn on extensive optimization.
This is the default.
The optimizations at this level are generally conservative,
in the sense that they are virtually always beneficial and
avoid changes which affect
such things as floating point accuracy. In addition to the level
1 optimizations, do inner loop
unrolling, if-conversion, two passes of instruction scheduling,
global register allocation, dead store elimination,
instruction scheduling across basic blocks,
and partial redundancy elimination.
3 Turn on aggressive optimization.
The optimizations at this level are distinguished from -O2
by their aggressiveness, generally seeking highest-quality
generated code even if it requires extensive compile time.
They may include optimizations that are generally beneficial
but may hurt performance.
This includes but is not limited to turning on the
Loop Nest Optimizer, -LNO:opt=1, and setting
-OPT:roundoff=1:IEEE_arithmetic=2:Olimit=9000:reorg_common=ON.
s Specify that code size is to be given priority in tradeoffs with execution time.
If no value is specified, 2 is assumed.Invoke inter-procedural analysis (IPA). Specifying this option is identical to specifying -IPA or -IPA:. Default settings for the individual IPA suboptions are used.
-OPT:Ofast
Use optimizations selected to maximize performance.
Although the optimizations are generally safe, they may affect
floating point accuracy due to rearrangement of computations.
This effectively turns on the following optimizations:
-OPT:ro=2:Olimit=0:div_split=ON:alias=typed.
-OPT:roundoff,ro=(0|1|2|3)
Specify the level of acceptable departure from source language
floating-point, round-off, and overflow semantics.
The options can be one of the following:
0 = Inhibit optimizations that might affect the floating-point behavior. This is the default when optimization levels -O0, -O1, and -O2 are in effect.
1 = Allow simple transformations that might cause limited round-off or overflow differences. Compounding such transformations could have more extensive effects. This is the default when -O3 is in effect.
2 = Allow more extensive transformations, such as the reordering of reduction loops. This is the default level when -OPT:Ofast is specified.
3 = Enable any mathematically valid transformation.
-OPT:Olimit=N
Disable optimization when size of program unit is > N. When N is 0,
program unit size is ignored and optimization process will not be
disabled due to compile time limit.
The default is 0 when -OPT:Ofast is specified,
9000 when -O3 is specified; otherwise the default is 6000.
-OPT:div_split=(ON|OFF)
Enable or disable changing x/y into x*(recip(y)). This is OFF by
default, but enabled by -OPT:Ofast or -OPT:IEEE_arithmetic=3.
This transformation generates fairly accurate code.
The -OPT: option group controls miscellaneous optimizations. These options override defaults based on the main optimization level.
-OPT:alias=<name>
Specify the pointer aliasing model
to be used. By specifying one or more of the following for <name>,
the compiler is able to make assumptions throughout the compilation:
typed
Assume that the code adheres to the ANSI/ISO C standard
which states that two pointers of different types cannot point
to the same location in memory.
This is ON by default when -OPT:Ofast is specified.
restrict
Specify that distinct pointers are assumed to point to distinct,
non-overlapping objects. This is OFF by default.
disjoint
Specify that any two pointer expressions are assumed to point
to distinct, non-overlapping objects. This is OFF by default.
Do not set ERRNO after calling math functions that are executed with a single instruction, e.g. sqrt. A program that relies on IEEE exceptions for math error handling may want to use this flag for speed while maintaining IEEE arithmetic compatibility. This is implied by -Ofast. The default is -fmath-errno.
-ffast-math improves FP speed by relaxing ANSI & IEEE rules. -fno-fast-math tells the compiler to conform to ANSI and IEEE math rules at the expense of speed. -ffast- math implies -OPT:IEEE_arithmetic=2 -fno-math-errno. -fno-fast-math implies -OPT:IEEE_arithmetic=1 -fmath-errno.
Flag description origin markings:
For questions about the meanings of these flags, please contact the tester.
For other inquiries, please contact webmaster@spec.org
Copyright 2006-2010 Standard Performance Evaluation Corporation
Tested with SPEC MPI2007 v58.
Report generated on Tue Apr 13 15:44:09 2010 by SPEC MPI2007 flags formatter v1412.