docs/CommandGuide/lli.pod - llvm - Git at Google

 =pod

 =head1 NAME

 lli - directly execute programs from LLVM bitcode

 =head1 SYNOPSIS

 B<lli> [I<options>] [I<filename>] [I<program args>]

 =head1 DESCRIPTION

 B<lli> directly executes programs in LLVM bitcode format.  It takes a program
 in LLVM bitcode format and executes it using a just-in-time compiler, if one is
 available for the current architecture, or an interpreter.  B<lli> takes all of
 the same code generator options as L<llc|llc>, but they are only effective when
 B<lli> is using the just-in-time compiler.

 If I<filename> is not specified, then B<lli> reads the LLVM bitcode for the
 program from standard input.

 The optional I<args> specified on the command line are passed to the program as
 arguments.

 =head1 GENERAL OPTIONS

 =over

 =item B<-fake-argv0>=I<executable>

 Override the C<argv[0]> value passed into the executing program.

 =item B<-force-interpreter>=I<{false,true}>

 If set to true, use the interpreter even if a just-in-time compiler is available
 for this architecture. Defaults to false.

 =item B<-help>

 Print a summary of command line options.

 =item B<-load>=I<puginfilename>

 Causes B<lli> to load the plugin (shared object) named I<pluginfilename> and use
 it for optimization.

 =item B<-stats>

 Print statistics from the code-generation passes. This is only meaningful for
 the just-in-time compiler, at present.

 =item B<-time-passes>

 Record the amount of time needed for each code-generation pass and print it to
 standard error.

 =item B<-version>

 Print out the version of B<lli> and exit without doing anything else.

 =back

 =head1 TARGET OPTIONS

 =over

 =item B<-mtriple>=I<target triple>

 Override the target triple specified in the input bitcode file with the
 specified string.  This may result in a crash if you pick an
 architecture which is not compatible with the current system.

 =item B<-march>=I<arch>

 Specify the architecture for which to generate assembly, overriding the target
 encoded in the bitcode file.  See the output of B<llc --help> for a list of
 valid architectures.  By default this is inferred from the target triple or
 autodetected to the current architecture.

 =item B<-mcpu>=I<cpuname>

 Specify a specific chip in the current architecture to generate code for.
 By default this is inferred from the target triple and autodetected to
 the current architecture.  For a list of available CPUs, use:
 B<llvm-as E<lt> /dev/null | llc -march=xyz -mcpu=help>

 =item B<-mattr>=I<a1,+a2,-a3,...>

 Override or control specific attributes of the target, such as whether SIMD
 operations are enabled or not.  The default set of attributes is set by the
 current CPU.  For a list of available attributes, use:
 B<llvm-as E<lt> /dev/null | llc -march=xyz -mattr=help>

 =back


 =head1 FLOATING POINT OPTIONS

 =over

 =item B<-disable-excess-fp-precision>

 Disable optimizations that may increase floating point precision.

 =item B<-enable-finite-only-fp-math>

 Enable optimizations that assumes only finite floating point math. That is,
 there is no NAN or Inf values.

 =item B<-enable-unsafe-fp-math>

 Causes B<lli> to enable optimizations that may decrease floating point
 precision.

 =item B<-soft-float>

 Causes B<lli> to generate software floating point library calls instead of
 equivalent hardware instructions.

 =back

 =head1 CODE GENERATION OPTIONS

 =over

 =item B<-code-model>=I<model>

 Choose the code model from:

     default: Target default code model
     small: Small code model
     kernel: Kernel code model
     medium: Medium code model
     large: Large code model

 =item B<-disable-post-RA-scheduler>

 Disable scheduling after register allocation.

 =item B<-disable-spill-fusing>

 Disable fusing of spill code into instructions.

 =item B<-enable-correct-eh-support>

 Make the -lowerinvoke pass insert expensive, but correct, EH code.

 =item B<-enable-eh>

 Exception handling should be emitted.

 =item B<-join-liveintervals>

 Coalesce copies (default=true).

 =item B<-nozero-initialized-in-bss>
 Don't place zero-initialized symbols into the BSS section.

 =item B<-pre-RA-sched>=I<scheduler>

 Instruction schedulers available (before register allocation):

     =default: Best scheduler for the target
     =none: No scheduling: breadth first sequencing
     =simple: Simple two pass scheduling: minimize critical path and maximize processor utilization
     =simple-noitin: Simple two pass scheduling: Same as simple except using generic latency
     =list-burr: Bottom-up register reduction list scheduling
     =list-tdrr: Top-down register reduction list scheduling
     =list-td: Top-down list scheduler -print-machineinstrs - Print generated machine code

 =item B<-regalloc>=I<allocator>

 Register allocator to use: (default = linearscan)

     =bigblock: Big-block register allocator
     =linearscan: linear scan register allocator =local -   local register allocator
     =simple: simple register allocator

 =item B<-relocation-model>=I<model>

 Choose relocation model from:

     =default: Target default relocation model
     =static: Non-relocatable code =pic -   Fully relocatable, position independent code
     =dynamic-no-pic: Relocatable external references, non-relocatable code

 =item B<-spiller>

 Spiller to use: (default: local)

     =simple: simple spiller
     =local: local spiller

 =item B<-x86-asm-syntax>=I<syntax>

 Choose style of code to emit from X86 backend:

     =att: Emit AT&T-style assembly
     =intel: Emit Intel-style assembly

 =back

 =head1 EXIT STATUS

 If B<lli> fails to load the program, it will exit with an exit code of 1.
 Otherwise, it will return the exit code of the program it executes.

 =head1 SEE ALSO

 L<llc|llc>

 =head1 AUTHOR

 Maintained by the LLVM Team (L<http://llvm.org>).

 =cut
	=pod

	=head1 NAME

	lli - directly execute programs from LLVM bitcode

	=head1 SYNOPSIS

	B<lli> [I<options>] [I<filename>] [I<program args>]

	=head1 DESCRIPTION

	B<lli> directly executes programs in LLVM bitcode format. It takes a program
	in LLVM bitcode format and executes it using a just-in-time compiler, if one is
	available for the current architecture, or an interpreter. B<lli> takes all of
	the same code generator options as L<llc\|llc>, but they are only effective when
	B<lli> is using the just-in-time compiler.

	If I<filename> is not specified, then B<lli> reads the LLVM bitcode for the
	program from standard input.

	The optional I<args> specified on the command line are passed to the program as
	arguments.

	=head1 GENERAL OPTIONS

	=over

	=item B<-fake-argv0>=I<executable>

	Override the C<argv[0]> value passed into the executing program.

	=item B<-force-interpreter>=I<{false,true}>

	If set to true, use the interpreter even if a just-in-time compiler is available
	for this architecture. Defaults to false.

	=item B<-help>

	Print a summary of command line options.

	=item B<-load>=I<puginfilename>

	Causes B<lli> to load the plugin (shared object) named I<pluginfilename> and use
	it for optimization.

	=item B<-stats>

	Print statistics from the code-generation passes. This is only meaningful for
	the just-in-time compiler, at present.

	=item B<-time-passes>

	Record the amount of time needed for each code-generation pass and print it to
	standard error.

	=item B<-version>

	Print out the version of B<lli> and exit without doing anything else.

	=back

	=head1 TARGET OPTIONS

	=over

	=item B<-mtriple>=I<target triple>

	Override the target triple specified in the input bitcode file with the
	specified string. This may result in a crash if you pick an
	architecture which is not compatible with the current system.

	=item B<-march>=I<arch>

	Specify the architecture for which to generate assembly, overriding the target
	encoded in the bitcode file. See the output of B<llc --help> for a list of
	valid architectures. By default this is inferred from the target triple or
	autodetected to the current architecture.

	=item B<-mcpu>=I<cpuname>

	Specify a specific chip in the current architecture to generate code for.
	By default this is inferred from the target triple and autodetected to
	the current architecture. For a list of available CPUs, use:
	B<llvm-as E<lt> /dev/null \| llc -march=xyz -mcpu=help>

	=item B<-mattr>=I<a1,+a2,-a3,...>

	Override or control specific attributes of the target, such as whether SIMD
	operations are enabled or not. The default set of attributes is set by the
	current CPU. For a list of available attributes, use:
	B<llvm-as E<lt> /dev/null \| llc -march=xyz -mattr=help>

	=back


	=head1 FLOATING POINT OPTIONS

	=over

	=item B<-disable-excess-fp-precision>

	Disable optimizations that may increase floating point precision.

	=item B<-enable-finite-only-fp-math>

	Enable optimizations that assumes only finite floating point math. That is,
	there is no NAN or Inf values.

	=item B<-enable-unsafe-fp-math>

	Causes B<lli> to enable optimizations that may decrease floating point
	precision.

	=item B<-soft-float>

	Causes B<lli> to generate software floating point library calls instead of
	equivalent hardware instructions.

	=back

	=head1 CODE GENERATION OPTIONS

	=over

	=item B<-code-model>=I<model>

	Choose the code model from:

	default: Target default code model
	small: Small code model
	kernel: Kernel code model
	medium: Medium code model
	large: Large code model

	=item B<-disable-post-RA-scheduler>

	Disable scheduling after register allocation.

	=item B<-disable-spill-fusing>

	Disable fusing of spill code into instructions.

	=item B<-enable-correct-eh-support>

	Make the -lowerinvoke pass insert expensive, but correct, EH code.

	=item B<-enable-eh>

	Exception handling should be emitted.

	=item B<-join-liveintervals>

	Coalesce copies (default=true).

	=item B<-nozero-initialized-in-bss>
	Don't place zero-initialized symbols into the BSS section.

	=item B<-pre-RA-sched>=I<scheduler>

	Instruction schedulers available (before register allocation):

	=default: Best scheduler for the target
	=none: No scheduling: breadth first sequencing
	=simple: Simple two pass scheduling: minimize critical path and maximize processor utilization
	=simple-noitin: Simple two pass scheduling: Same as simple except using generic latency
	=list-burr: Bottom-up register reduction list scheduling
	=list-tdrr: Top-down register reduction list scheduling
	=list-td: Top-down list scheduler -print-machineinstrs - Print generated machine code

	=item B<-regalloc>=I<allocator>

	Register allocator to use: (default = linearscan)

	=bigblock: Big-block register allocator
	=linearscan: linear scan register allocator =local - local register allocator
	=simple: simple register allocator

	=item B<-relocation-model>=I<model>

	Choose relocation model from:

	=default: Target default relocation model
	=static: Non-relocatable code =pic - Fully relocatable, position independent code
	=dynamic-no-pic: Relocatable external references, non-relocatable code

	=item B<-spiller>

	Spiller to use: (default: local)

	=simple: simple spiller
	=local: local spiller

	=item B<-x86-asm-syntax>=I<syntax>

	Choose style of code to emit from X86 backend:

	=att: Emit AT&T-style assembly
	=intel: Emit Intel-style assembly

	=back

	=head1 EXIT STATUS

	If B<lli> fails to load the program, it will exit with an exit code of 1.
	Otherwise, it will return the exit code of the program it executes.

	=head1 SEE ALSO

	L<llc\|llc>

	=head1 AUTHOR

	Maintained by the LLVM Team (L<http://llvm.org>).

	=cut