nvcc --version (return code: 0)
nvcc: NVIDIA (R) Cuda compiler driver
Copyright (c) 2005-2016 NVIDIA Corporation
Built on Sun_Sep__4_22:14:01_CDT_2016
Cuda compilation tools, release 8.0, V8.0.44
nvcc --help (return code: 0)
Usage : nvcc [options] <inputfile>
Options for specifying the compilation phase
============================================
More exactly, this option specifies up to which stage the input files must be compiled,
according to the following compilation trajectories for different input file types:
.c/.cc/.cpp/.cxx : preprocess, compile, link
.o : link
.i/.ii : compile, link
.cu : preprocess, cuda frontend, PTX assemble,
merge with host C code, compile, link
.gpu : cicc compile into cubin
.ptx : PTX assemble into cubin.
--cuda (-cuda)
Compile all .cu input files to .cu.cpp.ii output.
--cubin (-cubin)
Compile all .cu/.gpu/.ptx input files to device-only .cubin files. This
step discards the host code for each .cu input file.
--fatbin(-fatbin)
Compile all .cu/.gpu/.ptx/.cubin input files to device-only .fatbin files.
This step discards the host code for each .cu input file.
--ptx (-ptx)
Compile all .cu/.gpu input files to device-only .ptx files. This step discards
the host code for each of these input file.
--gpu (-gpu)
Compile all .cu input files to device-only .gpu files. This step discards
the host code for each .cu input file.
--preprocess (-E)
Preprocess all .c/.cc/.cpp/.cxx/.cu input files.
--generate-dependencies (-M)
Generate a dependency file that can be included in a make file for the .c/.cc/.cpp/.cxx/.cu
input file (more than one are not allowed in this mode).
--compile (-c)
Compile each .c/.cc/.cpp/.cxx/.cu input file into an object file.
--device-c (-dc)
Compile each .c/.cc/.cpp/.cxx/.cu input file into an object file that contains
relocatable device code. It is equivalent to '--relocatable-device-code=true
--compile'.
--device-w (-dw)
Compile each .c/.cc/.cpp/.cxx/.cu input file into an object file that contains
executable device code. It is equivalent to '--relocatable-device-code=false
--compile'.
--device-link (-dlink)
Link object files with relocatable device code and .ptx/.cubin/.fatbin files
into an object file with executable device code, which can be passed to the
host linker.
--link (-link)
This option specifies the default behavior: compile and link all inputs.
--lib (-lib)
Compile all inputs into object files (if necessary) and add the results to
the specified output library file.
--run (-run)
This option compiles and links all inputs into an executable, and executes
it. Or, when the input is a single executable, it is executed without any
compilation or linking. This step is intended for developers who do not want
to be bothered with setting the necessary environment variables; these are
set temporarily by nvcc).
File and path specifications.
=============================
--output-file <file> (-o)
Specify name and location of the output file. Only a single input file is
allowed when this option is present in nvcc non-linking/archiving mode.
--pre-include <file>,... (-include)
Specify header files that must be preincluded during preprocessing.
--library <library>,... (-l)
Specify libraries to be used in the linking stage without the library file
extension. The libraries are searched for on the library search paths that
have been specified using option '--library-path'.
--define-macro <def>,... (-D)
Specify macro definitions to define for use during preprocessing or compilation.
--undefine-macro <def>,... (-U)
Undefine macro definitions during preprocessing or compilation.
--include-path <path>,... (-I)
Specify include search paths.
--system-include <path>,... (-isystem)
Specify system include search paths.
--library-path <path>,... (-L)
Specify library search paths.
--output-directory <directory> (-odir)
Specify the directory of the output file. This option is intended for letting
the dependency generation step (see '--generate-dependencies') generate a
rule that defines the target object file in the proper directory.
--compiler-bindir <path> (-ccbin)
Specify the directory in which the host compiler executable resides. The
host compiler executable name can be also specified to ensure that the correct
host compiler is selected. In addition, driver prefix options ('--input-drive-prefix',
'--dependency-drive-prefix', or '--drive-prefix') may need to be specified,
if nvcc is executed in a Cygwin shell or a MinGW shell on Windows.
--cudart{none|shared|static} (-cudart)
Specify the type of CUDA runtime library to be used: no CUDA runtime library,
shared/dynamic CUDA runtime library, or static CUDA runtime library.
Allowed values for this option: 'none','shared','static'.
Default value: 'static'.
--libdevice-directory <directory> (-ldir)
Specify the directory that contains the libdevice library files when option
'--dont-use-profile' is used. Libdevice library files are located in the
'nvvm/libdevice' directory in the CUDA toolkit.
--cl-version <cl-version-number> --cl-version <cl-version-number>
Specify the version of Microsoft Visual Studio installation. Note: this
option is to be used in conjunction with '--use-local-env', and is ignored
when '--use-local-env' is not specified. Support for VS2010 and earlier has
been deprecated.
Allowed values for this option: 2010,2012,2013,2015.
--use-local-env --use-local-env
Specify whether the environment is already set up for the host compiler.
Options for specifying behavior of compiler/linker.
===================================================
--profile (-pg)
Instrument generated code/executable for use by gprof (Linux only).
--debug (-g)
Generate debug information for host code.
--device-debug (-G)
Generate debug information for device code. Turns off all optimizations.
Don't use for profiling; use -lineinfo instead.
--generate-line-info (-lineinfo)
Generate line-number information for device code.
--optimize <level> (-O)
Specify optimization level for host code.
--ftemplate-backtrace-limit <limit> (-ftemplate-backtrace-limit)
When compiling CUDA source code, set the maximum number of template instantiation
notes for a single warning or error to <limit>. A value of 0 is allowed,
and indicates that no limit should be enforced. Note: This flag does not
affect the host compiler used for compiling host part of the CUDA source
code.
--ftemplate-depth <limit> (-ftemplate-depth)
Set the maximum instantiation depth for template classes to <limit>. This
value is also passed to the host compiler if it provides an equivalent flag.
--shared(-shared)
Generate a shared library during linking. Use option '--linker-options'
when other linker options are required for more control.
--x {c|c++|cu} (-x)
Explicitly specify the language for the input files, rather than letting
the compiler choose a default based on the file name suffix.
Allowed values for this option: 'c','c++','cu'.
--std {c++11} (-std)
Select a particular C++ dialect. Note that this flag also turns on the corresponding
dialect flag for the host compiler.
Allowed values for this option: 'c++11'.
--no-host-device-initializer-list (-nohdinitlist)
Do not implicitly consider member functions of std::initializer_list as __host__
__device__ functions.
--no-host-device-move-forward (-nohdmoveforward)
Do not implicitly consider std::move and std::forward as __host__ __device__
function templates.
--expt-relaxed-constexpr (-expt-relaxed-constexpr)
Experimental flag: Allow host code to invoke __device__ constexpr functions,
and device code to invoke __host__ constexpr functions.
--expt-extended-lambda (-expt-extended-lambda)
Experimental flag: Allow __host__, __device__ annotations in lambda declaration.
--machine {32|64} (-m)
Specify 32 vs 64 bit architecture.
Allowed values for this option: 32,64.
Default value: 64.
Options for passing specific phase options
==========================================
These allow for passing options directly to the intended compilation phase. Using
these, users have the ability to pass options to the lower level compilation tools,
without the need for nvcc to know about each and every such option.
--compiler-options <options>,... (-Xcompiler)
Specify options directly to the compiler/preprocessor.
--linker-options <options>,... (-Xlinker)
Specify options directly to the host linker.
--archive-options <options>,... (-Xarchive)
Specify options directly to library manager.
--ptxas-options <options>,... (-Xptxas)
Specify options directly to ptxas, the PTX optimizing assembler.
--nvlink-options <options>,... (-Xnvlink)
Specify options directly to nvlink.
Miscellaneous options for guiding the compiler driver.
======================================================
--dont-use-profile (-noprof)
Nvcc uses the nvcc.profiles file for compilation. When specifying this option,
the profile file is not used.
--dryrun(-dryrun)
Do not execute the compilation commands generated by nvcc. Instead, list
them.
--verbose (-v)
List the compilation commands generated by this compiler driver, but do not
suppress their execution.
--keep (-keep)
Keep all intermediate files that are generated during internal compilation
steps.
--keep-dir <directory> (-keep-dir)
Keep all intermediate files that are generated during internal compilation
steps in this directory.
--save-temps (-save-temps)
This option is an alias of '--keep'.
--clean-targets (-clean)
This option reverses the behavior of nvcc. When specified, none of the compilation
phases will be executed. Instead, all of the non-temporary files that nvcc
would otherwise create will be deleted.
--run-args <arguments>,... (-run-args)
Used in combination with option --run to specify command line arguments for
the executable.
--input-drive-prefix <prefix> (-idp)
On Windows, all command line arguments that refer to file names must be converted
to the Windows native format before they are passed to pure Windows executables.
This option specifies how the current development environment represents
absolute paths. Use '/cygwin/' as <prefix> for Cygwin build environments,
and '/' as <prefix> for MinGW.
--dependency-drive-prefix <prefix> (-ddp)
On Windows, when generating dependency files (see --generate-dependencies),
all file names must be converted appropriately for the instance of 'make'
that is used. Some instances of 'make' have trouble with the colon in absolute
paths in the native Windows format, which depends on the environment in which
the 'make' instance has been compiled. Use '/cygwin/' as <prefix> for a
Cygwin make, and '/' as <prefix> for MinGW. Or leave these file names in
the native Windows format by specifying nothing.
--drive-prefix <prefix> (-dp)
Specifies <prefix> as both --input-drive-prefix and --dependency-drive-prefix.
--dependency-target-name <target> (-MT)
Specify the target name of the generated rule when generating a dependency
file (see '--generate-dependencies').
--no-align-double --no-align-double
Specifies that '-malign-double' should not be passed as a compiler argument
on 32-bit platforms. WARNING: this makes the ABI incompatible with the cuda's
kernel ABI for certain 64-bit types.
--no-device-link (-nodlink)
Skip the device link step when linking object files.
Options for steering GPU code generation.
=========================================
--gpu-architecture <arch> (-arch)
Specify the name of the class of NVIDIA 'virtual' GPU architecture for which
the CUDA input files must be compiled.
With the exception as described for the shorthand below, the architecture
specified with this option must be a 'virtual' architecture (such as compute_50).
Normally, this option alone does not trigger assembly of the generated PTX
for a 'real' architecture (that is the role of nvcc option '--gpu-code',
see below); rather, its purpose is to control preprocessing and compilation
of the input to PTX.
For convenience, in case of simple nvcc compilations, the following shorthand
is supported. If no value for option '--gpu-code' is specified, then the
value of this option defaults to the value of '--gpu-architecture'. In this
situation, as only exception to the description above, the value specified
for '--gpu-architecture' may be a 'real' architecture (such as a sm_50),
in which case nvcc uses the specified 'real' architecture and its closest
'virtual' architecture as effective architecture values. For example, 'nvcc
--gpu-architecture=sm_50' is equivalent to 'nvcc --gpu-architecture=compute_50
--gpu-code=sm_50,compute_50'.
Allowed values for this option: 'compute_20','compute_30','compute_32',
'compute_35','compute_37','compute_50','compute_52','compute_53','compute_60',
'compute_61','compute_62','sm_20','sm_21','sm_30','sm_32','sm_35','sm_37',
'sm_50','sm_52','sm_53','sm_60','sm_61','sm_62'.
--gpu-code <code>,... (-code)
Specify the name of the NVIDIA GPU to assemble and optimize PTX for.
nvcc embeds a compiled code image in the resulting executable for each specified
<code> architecture, which is a true binary load image for each 'real' architecture
(such as sm_50), and PTX code for the 'virtual' architecture (such as compute_50).
During runtime, such embedded PTX code is dynamically compiled by the CUDA
runtime system if no binary load image is found for the 'current' GPU.
Architectures specified for options '--gpu-architecture' and '--gpu-code'
may be 'virtual' as well as 'real', but the <code> architectures must be
compatible with the <arch> architecture. When the '--gpu-code' option is
used, the value for the '--gpu-architecture' option must be a 'virtual' PTX
architecture.
For instance, '--gpu-architecture=compute_35' is not compatible with '--gpu-code=sm_30',
because the earlier compilation stages will assume the availability of 'compute_35'
features that are not present on 'sm_30'.
Allowed values for this option: 'compute_20','compute_30','compute_32',
'compute_35','compute_37','compute_50','compute_52','compute_53','compute_60',
'compute_61','compute_62','sm_20','sm_21','sm_30','sm_32','sm_35','sm_37',
'sm_50','sm_52','sm_53','sm_60','sm_61','sm_62'.
--generate-code <specification>,... (-gencode)
This option provides a generalization of the '--gpu-architecture=<arch> --gpu-code=<code>,
...' option combination for specifying nvcc behavior with respect to code
generation. Where use of the previous options generates code for different
'real' architectures with the PTX for the same 'virtual' architecture, option
'--generate-code' allows multiple PTX generations for different 'virtual'
architectures. In fact, '--gpu-architecture=<arch> --gpu-code=<code>,
...' is equivalent to '--generate-code arch=<arch>,code=<code>,...'.
'--generate-code' options may be repeated for different virtual architectures.
Allowed keywords for this option: 'arch','code'.
--relocatable-device-code {true|false} (-rdc)
Enable (disable) the generation of relocatable device code. If disabled,
executable device code is generated. Relocatable device code must be linked
before it can be executed.
Default value: 0.
--entries entry,... (-e)
Specify the global entry functions for which code must be generated. By
default, code will be generated for all entry functions.
--maxrregcount <amount> (-maxrregcount)
Specify the maximum amount of registers that GPU functions can use.
Until a function-specific limit, a higher value will generally increase the
performance of individual GPU threads that execute this function. However,
because thread registers are allocated from a global register pool on each
GPU, a higher value of this option will also reduce the maximum thread block
size, thereby reducing the amount of thread parallelism. Hence, a good maxrregcount
value is the result of a trade-off.
If this option is not specified, then no maximum is assumed.
Value less than the minimum registers required by ABI will be bumped up by
the compiler to ABI minimum limit.
--use_fast_math (-use_fast_math)
Make use of fast math library. '--use_fast_math' implies '--ftz=true --prec-div=false
--prec-sqrt=false --fmad=true'.
--ftz {true|false} (-ftz)
This option controls single-precision denormals support. '--ftz=true' flushes
denormal values to zero and '--ftz=false' preserves denormal values. '--use_fast_math'
implies '--ftz=true'.
Default value: 0.
--prec-div {true|false} (-prec-div)
This option controls single-precision floating-point division and reciprocals.
'--prec-div=true' enables the IEEE round-to-nearest mode and '--prec-div=false'
enables the fast approximation mode. '--use_fast_math' implies '--prec-div=false'.
Default value: 1.
--prec-sqrt {true|false} (-prec-sqrt)
This option controls single-precision floating-point squre root. '--prec-sqrt=true'
enables the IEEE round-to-nearest mode and '--prec-sqrt=false' enables the
fast approximation mode. '--use_fast_math' implies '--prec-sqrt=false'.
Default value: 1.
--fmad {true|false} (-fmad)
This option enables (disables) the contraction of floating-point multiplies
and adds/subtracts into floating-point multiply-add operations (FMAD, FFMA,
or DFMA). '--use_fast_math' implies '--fmad=true'.
Default value: 1.
Options for steering cuda compilation.
======================================
--default-stream {legacy|null|per-thread} (-default-stream)
Specify the stream that CUDA commands from the compiled program will be sent
to by default.
legacy
The CUDA legacy stream (per context, implicitly synchronizes with
other streams).
per-thread
A normal CUDA stream (per thread, does not implicitly
synchronize with other streams).
'null' is a deprecated alias for 'legacy'.
Allowed values for this option: 'legacy','null','per-thread'.
Default value: 'legacy'.
Generic tool options.
=====================
--disable-warnings (-w)
Inhibit all warning messages.
--keep-device-functions (-keep-device-functions)
In whole program compilation mode, preserve user defined external linkage
__device__ function definitions up to PTX.
--source-in-ptx (-src-in-ptx)
Interleave source in PTX. May only be used in conjunction with --device-debug
or --generate-line-info.
--restrict (-restrict)
Programmer assertion that all kernel pointer parameters are restrict pointers.
--Wno-deprecated-gpu-targets (-Wno-deprecated-gpu-targets)
Suppress warnings about deprecated GPU target architectures.
--Werror<kind>,... (-Werror)
Make warnings of the specified kinds into errors. The following is the list
of warning kinds accepted by this option:
cross-execution-space-call
Be more strict about unsupported cross execution space calls.
The compiler will generate an error instead of a warning for a
call from a __host__ __device__ to a __host__ function.
Allowed values for this option: 'cross-execution-space-call'.
--resource-usage (-res-usage)
Show resource usage such as registers and memory of the GPU code.
This option implies '--nvlink-options --verbose' when '--relocatable-device-code=true'
is set. Otherwise, it implies '--ptxas-options --verbose'.
--help (-h)
Print this help information on this tool.
--version (-V)
Print version information on this tool.
--options-file <file>,... (-optf)
Include command line options from specified file.