CPU2017 Flag Description
ASRock Rack Inc. 1U4LW-B650/2L2T RPSU AMD Ryzen 9 7950X

Base Optimization Flags

C benchmarks

• • -m64
  • 
  • CC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-ldist-scalar-expand
  • 
  • LDCFLAGS

  • Enables loop distribution with scalar expansion for better vectorization.

• • -fenable-aggressive-gather
  • 
  • LDCFLAGS

  • This option enables generation of gather instructions for cases where it is profitable.

• • -O3
  • 
  • COPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • COPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

C++ benchmarks

• • -m64
  • 
  • CXX, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • CXXOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -O3
  • 
  • CXXOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • CXXOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • CXXOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • CXXOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -loop-unswitch-threshold=200000
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unswitched. For example, if unswitch threshold is set to 100 then only loops with 100 or fewer instructions will be unswtched.

• • -mllvm -reduce-array-computations=3
  • 
  • CXXOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • CXXOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

Fortran benchmarks

• • -m64
  • 
  • FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-enable-X86-prefetching
  • 
  • LDFFLAGS

  • This optimization enables generation of prefetch instructions for tightly coupled loops

• • -O3
  • 
  • FOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -Kieee
  • 
  • FOPTIMIZE

  • Instructs the compiler to conform to the IEEE-754 specifications. The compiler will perform floating-point operations in strict conformance with the IEEE 754 standard. Some optimizations are disabled when this option is specified

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -funroll-loops
  • 
  • FOPTIMIZE

  • This option instructs the compiler to unroll loops wherever possible.

• • -mllvm -lsr-in-nested-loop
  • 
  • FOPTIMIZE

  • Enables loop strength reduction for nested loop structures. By default, the compiler performs loop strength reduction only for the innermost loop.

• • -mllvm -reduce-array-computations=3
  • 
  • FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -zopt
  • 
  • FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

Benchmarks using both Fortran and C

• • -m64
  • 
  • CC, FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-enable-X86-prefetching
  • 
  • LDFFLAGS

  • This optimization enables generation of prefetch instructions for tightly coupled loops

• • -O3
  • 
  • COPTIMIZE, FOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • COPTIMIZE, FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -Kieee
  • 
  • FOPTIMIZE

  • Instructs the compiler to conform to the IEEE-754 specifications. The compiler will perform floating-point operations in strict conformance with the IEEE 754 standard. Some optimizations are disabled when this option is specified

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -funroll-loops
  • 
  • FOPTIMIZE

  • This option instructs the compiler to unroll loops wherever possible.

• • -mllvm -lsr-in-nested-loop
  • 
  • FOPTIMIZE

  • Enables loop strength reduction for nested loop structures. By default, the compiler performs loop strength reduction only for the innermost loop.

• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

Benchmarks using both C and C++

• • -m64
  • 
  • CC, CXX, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, CXXOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -O3
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -loop-unswitch-threshold=200000
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unswitched. For example, if unswitch threshold is set to 100 then only loops with 100 or fewer instructions will be unswtched.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

Benchmarks using Fortran, C, and C++

• • -m64
  • 
  • CC, CXX, FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -O3
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -loop-unswitch-threshold=200000
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unswitched. For example, if unswitch threshold is set to 100 then only loops with 100 or fewer instructions will be unswtched.

• • -Kieee
  • 
  • FOPTIMIZE

  • Instructs the compiler to conform to the IEEE-754 specifications. The compiler will perform floating-point operations in strict conformance with the IEEE 754 standard. Some optimizations are disabled when this option is specified

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -funroll-loops
  • 
  • FOPTIMIZE

  • This option instructs the compiler to unroll loops wherever possible.

• • -mllvm -lsr-in-nested-loop
  • 
  • FOPTIMIZE

  • Enables loop strength reduction for nested loop structures. By default, the compiler performs loop strength reduction only for the innermost loop.

• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

Peak Optimization Flags

C benchmarks

519.lbm_r

• • -m64
  • 
  • CC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Ofast
  • 
  • COPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • COPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

538.imagick_r

• • Same as 519.lbm_r

544.nab_r

• • -m64
  • 
  • CC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-ldist-scalar-expand
  • 
  • LDFLAGS

  • Enables loop distribution with scalar expansion for better vectorization.

• • -fenable-aggressive-gather
  • 
  • LDFLAGS

  • This option enables generation of gather instructions for cases where it is profitable.

• • -Ofast
  • 
  • COPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • COPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

C++ benchmarks

508.namd_r

• • -m64
  • 
  • CXX, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • CXXOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -Ofast
  • 
  • CXXOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • CXXOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • CXXOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • CXXOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -reduce-array-computations=3
  • 
  • CXXOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • CXXOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

510.parest_r

• • -m64
  • 
  • CXX, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • CXXOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-suppress-fmas
  • 
  • LDFLAGS

  • Disables generation of fma instructions when there is a chain of fma instructions and output of one fma instruction is used as input to other fma instruction.

• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -Ofast
  • 
  • CXXOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • CXXOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • CXXOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • CXXOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -reduce-array-computations=3
  • 
  • CXXOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • CXXOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

Fortran benchmarks

503.bwaves_r

• • -m64
  • 
  • FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-enable-X86-prefetching
  • 
  • LDFFLAGS

  • This optimization enables generation of prefetch instructions for tightly coupled loops

• • -Ofast
  • 
  • FOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -mllvm -reduce-array-computations=3
  • 
  • FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -zopt
  • 
  • FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_FLIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

549.fotonik3d_r

• • -m64
  • 
  • FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-enable-X86-prefetching
  • 
  • LDFFLAGS

  • This optimization enables generation of prefetch instructions for tightly coupled loops

• • -Ofast
  • 
  • FOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -Kieee
  • 
  • FOPTIMIZE

  • Instructs the compiler to conform to the IEEE-754 specifications. The compiler will perform floating-point operations in strict conformance with the IEEE 754 standard. Some optimizations are disabled when this option is specified

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -mllvm -reduce-array-computations=3
  • 
  • FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -fvector-transform
  • 
  • FOPTIMIZE

  • This option enables a subset of vector transformations including improved variants of SLP and loop vectorization.

• • -fscalar-transform
  • 
  • FOPTIMIZE

  • This option enables a subset of scalar transformations including improved variants of various code movement optimizations like hosting and invariant code movement.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_FLIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

554.roms_r

• • Same as 503.bwaves_r

Benchmarks using both Fortran and C

521.wrf_r

• • -m64
  • 
  • CC, FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-enable-X86-prefetching
  • 
  • LDFFLAGS

  • This optimization enables generation of prefetch instructions for tightly coupled loops

• • -Ofast
  • 
  • COPTIMIZE, FOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • COPTIMIZE, FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_FLIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

527.cam4_r

• • -m64
  • 
  • CC, FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-enable-X86-prefetching
  • 
  • LDFFLAGS

  • This optimization enables generation of prefetch instructions for tightly coupled loops

• • -O3
  • 
  • COPTIMIZE, FOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • COPTIMIZE, FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -Kieee
  • 
  • FOPTIMIZE

  • Instructs the compiler to conform to the IEEE-754 specifications. The compiler will perform floating-point operations in strict conformance with the IEEE 754 standard. Some optimizations are disabled when this option is specified

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -funroll-loops
  • 
  • FOPTIMIZE

  • This option instructs the compiler to unroll loops wherever possible.

• • -mllvm -lsr-in-nested-loop
  • 
  • FOPTIMIZE

  • Enables loop strength reduction for nested loop structures. By default, the compiler performs loop strength reduction only for the innermost loop.

• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_FLIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.

Benchmarks using both C and C++

511.povray_r

• • -m64
  • 
  • CC, CXX, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, CXXOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -O3
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Like -O2, except that it enables optimizations that take longer to perform or that may generate larger code (in an attempt to make the program run faster).

    If multiple "O" options are used, with or without level numbers, the last such option is the one that is effective.

  • Includes:
    • -O2
      • -O1
• • -march=znver4
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -loop-unswitch-threshold=200000
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unswitched. For example, if unswitch threshold is set to 100 then only loops with 100 or fewer instructions will be unswtched.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

526.blender_r

• • -m64
  • 
  • CC, CXX, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, CXXOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -Ofast
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, CXXOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

Benchmarks using Fortran, C, and C++

• • -m64
  • 
  • CC, CXX, FC, LD

  • Generates code for a 64-bit environment. The 64-bit environment sets int to 32 bits and long and pointer to 64 bits and generates code for AMD's x86-64 architecture. The compiler generates AMD64, INTEL64, x86-64 64-bit ABI. The default on a 32-bit host is 32-bit ABI. The default on a 64-bit host is 64-bit ABI if the target platform specified is 64-bit, otherwise the default is 32-bit.

• • -flto
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE, LDFLAGS

  • Generate output files in LLVM formats suitable for link time optimization. When used with -S this generates LLVM intermediate language assembly files, otherwise this generates LLVM bitcode format object files (which may be passed to the linker depending on the stage selection options).

• • -Wl,-mllvm -Wl,-align-all-nofallthru-blocks=6
  • 
  • LDFLAGS

  • Forces the alignment of all blocks that have no fall-through predecessors (i.e. don't add nops that are executed). In log2 format (e.g 4 means align on 16B boundaries).

• • -Wl,-mllvm -Wl,-reduce-array-computations=3
  • 
  • LDFLAGS

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -Wl,-mllvm -Wl,-x86-use-vzeroupper=false
  • 
  • LDCXXFLAGS

  • This option controls the vzeroupper instruction generation before a transfer of control flow. Not emitting the vzeroupper instruction can help minimize the AVX to SSE transition penalty.

• • -Ofast
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Enables all the optimizations from -O3 along with other aggressive optimizations that may violate strict compliance with language standards. Refer to the AOCC options document for the language you're using for more detailed documentation of optimizations enabled under -Ofast.

  • Includes:
    • -O3
      • -O2
        • -O1
• • -march=znver4
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Specify that Clang should generate code for a specific processor family member and later. For example, if you specify -march=znver1, the compiler is allowed to generate instructions that are valid on AMD Zen processors, but which may not exist on earlier products. -march=znver4 enables AVX 512 ISA for Genoa (znver4) processors.

• • -fveclib=AMDLIBM
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Use the given vector functions library.

• • -ffast-math
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • Enables a range of optimizations that provide faster, though sometimes less precise, mathematical operations that may not conform to the IEEE-754 specifications. When this option is specified, the __STDC_IEC_559__ macro is ignored even if set by the system headers.

• • -fstruct-layout=7
  • 
  • COPTIMIZE

  • Analyzes the whole program to determine if the structures in the code can be peeled, if dead or redundant fields can be deleted, and if the pointer or integer fields in the structure can be compressed. If feasible, this optimization transforms the code to enable these improvements. This transformation is likely to improve cache utilization and memory bandwidth. It is expected to improve the scalability of programs executed on multiple cores. This is effective only under flto as the whole program analysis is required to perform this optimization. You can choose different levels of aggressiveness with which this optimization can be applied to your application; with 1 being the least aggressive and 7 being the most aggressive level.

    Possible values:

    • fstruct-layout=0: disables structure peeling (default).
    • fstruct-layout=1: enables structure peeling.
    • fstruct-layout=2: enables structure peeling and selectively compresses self-referential pointers in these structures to 32-bit pointers wherever safe.
    • fstruct-layout=3: enables structure peeling and selectively compresses self-referential pointers in these structures to 16-bit pointers wherever safe.
    • fstruct-layout=4: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=5: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of 64-bit integer type to 32-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=6: enables structure peeling, pointer compression as in level 2 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=7: enables structure peeling, pointer compression as in level 3 and further enables compression of structure fields which are of type 64-bit integer type to 16-bit integer type. This is performed under a strict safety check.
    • fstruct-layout=8: enables structure peeling, pointer compression, 64 bit integer type compression as in level 6 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    • fstruct-layout=9: enables structure peeling, pointer compression, 64 bit integer type compression as in level 7 and creates optimal ordering of peeled structure fields which could improve runtime performance.
    Note:

    fstruct-layout=4 and fstruct-layout=5 are derived from fstruct-layout=2 and fstruct-layout=3 respectively with the added feature of safe compression of 64-bit integer fields to 32-bit integer fields in structures. Going from fstruct-layout=4 to fstruct-layout=5 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

    fstruct-layout=6 and fstruct-layout=7 are derived from fstruct-layout=2 and fstructlayout=3 respectively, with the added feature of safe compression of 64 bit integer fields to 16 bit integer in structures. Going from fstruct-layout=6 to fstruct-layout=7 may result in higher performance if the pointer values are such that the pointers can be compressed to 16-bits.

• • -mllvm -unroll-threshold=50
  • 
  • COPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -fremap-arrays
  • 
  • COPTIMIZE

  • This option enables an optimization that transforms the data layout of a single dimensional array to provide better cache locality by analysing the access patterns.

• • -fstrip-mining
  • 
  • COPTIMIZE

  • Enables loop strip mining optimization. This optimization breaks a large loop into smaller segments or strips to improve temporal and spatial locality.

• • -mllvm -inline-threshold=1000
  • 
  • COPTIMIZE

  • Sets the compiler's inlining threshold level to the value passed as the argument. The inline threshold is used in the inliner heuristics to decide which functions should be inlined.

• • -mllvm -reduce-array-computations=3
  • 
  • COPTIMIZE, CXXOPTIMIZE, FOPTIMIZE

  • This option eliminates the array computations based on their usage. The computations on unused array elements and computations on zero valued array elements are eliminated with this optimization. -flto as whole program analysis is required to perform this optimization.

    Possible values:

    • 1: Eliminates the computations on unused array elements
    • 2: Eliminates the computations on zero valued array elements
    • 3: Eliminates the computations on unused and zero valued array elements
• • -zopt
  • 
  • COPTIMIZE, FOPTIMIZE

  • This option enables a subset of scalar, vector and loop transformations including improved variants of loop invariant code motion, SLP and loop vectorizations, loop-fusion, loop-interchange, loop-unswitch, loop tiling and loop distribution.

• • -mllvm -unroll-threshold=100
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unrolled. For example, if unroll threshold is set to 100 then only loops with 100 or fewer instructions will be unrolled.

• • -mllvm -loop-unswitch-threshold=200000
  • 
  • CXXOPTIMIZE

  • Sets the limit at which loops will be unswitched. For example, if unswitch threshold is set to 100 then only loops with 100 or fewer instructions will be unswtched.

• • -finline-aggressive
  • 
  • CXXOPTIMIZE

  • Sets the compiler's inlining heuristics to an aggressive level by increasing the inline thresholds.

• • -faggressive-loop-transform
  • 
  • CXXOPTIMIZE

  • This option enables a subset of loop transformations including improved variants of loop unswitching, loop-tiling and versioning of loop invariant code motion.

• • -fvector-transform
  • 
  • CXXOPTIMIZE

  • This option enables a subset of vector transformations including improved variants of SLP and loop vectorization.

• • -fscalar-transform
  • 
  • CXXOPTIMIZE

  • This option enables a subset of scalar transformations including improved variants of various code movement optimizations like hosting and invariant code movement.

• • -Mrecursive
  • 
  • FOPTIMIZE

  • Allocate local variables on the stack, thus allowing recursion. SAVEd, data-initialized, or namelist members are always allocated statically, regardless of the setting of this switch.

• • -fepilog-vectorization-of-inductions
  • 
  • FOPTIMIZE

  • Enables epilog vectorization of loops that require loop induction variables also to be vectorized.

• • -lamdlibm
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with AMD-supported optimized math library.

• • -lamdalloc
  • 
  • EXTRA_LIBS

  • amdalloc is a AMD's memory allocator based on jemalloc library and is available as a part of AOCC binary package.

• • -lflang
  • 
  • EXTRA_LIBS

  • Instructs the compiler to link with flang Fortran runtime libraries.