NAME
Parrot - Running
VERSION
$Revision$
OVERVIEW
This document describes Parrot's command line options.
SYNOPSIS
parrot [-options] <file> [arguments ...]
ENVIRONMENT
- PARROT_RUNTIME If this environment variable is set, parrot will use this path as its runtime prefix instead of the compiled in path.
- PARROT_GC_DEBUG Turn on the --gc-debug flag.
OPTIONS
Assembler options
- -a, --pasm Assume PASM input on stdin.
- -c, --pbc Assume PBC file on stdin, run it.
- -d, --imcc-debug [hexbits] The -d switch takes an optional argument which is considered to hold a hex value of debug bits. Without a value, debug is set to 1.The individual bits can be listed on the command line by use of the --help-debug switch.To produce really huge output on stderr run
- -h, --help Print command line option summary.
- --help-debug Print debugging and tracing flag bits summary.
- -o outputfile, --output=outputfile Act like an assembler. Don't run code, unless -r is given too. If the outputfile ends with .pbc, a PBC file is written. If it ends with .pasm, a PASM output is generated, even from PASM input. This can be handy to check various optimizations, including
- --output-pbc Act like an assembler, but always output bytecode, even if the output file does not end in .pbc
- -r, --run-pbc Only useful after
- -v, --verbose One
- -y, --yydebug Turn on yydebug in yacc/bison.
- -V, --version Print version information and exit.
- -Ox Optimize
- -E, --pre-process-only Preprocess source file (expand macros) and print result to stdout:
"parrot -d 0ffff ..."
. Note: If the argument is separated by whitespace from the -d switch, it has to start with a number.
-Op
.
-o
or --output-pbc
. Run the program from the compiled in-memory image. If two -r
options are given, the .pbc file is read from disc and run. This is mainly needed for tests.
-v
shows which files are worked on and prints a summary over register usage and optimization stats per subroutine. With two -v
switches, parrot
prints a line per individual processing step too.
-O0 no optimization (default) -O1 optimizations without life info (e.g. branches) -O same -O2 optimizations with life info -Op rewrite I and N PASM registers most used first -Ot select fastest runcore -Oc turns on the optional/experimental tail call optimizationsSee docs/dev/optimizer.pod for more information on the optimizer. Note that optimization is currently experimental and these options are likely to change.
$ parrot -E t/op/macro_10.pasm $ parrot -E t/op/macro_10.pasm | parrot -- -
Runcore Options
These options select the runcore, which is useful for performance tuning and debugging. See "About runcores" for details.
- -R, --runcore CORE Select the runcore. The following cores are available in Parrot, but not all may be available on your system:
- -p, --profile Run with the slow core and print an execution profile.
- -t, --trace Run with the slow core and print trace information to stderr. See
slow, bounds bounds checking core (default) cgoto computed goto core cgp computed goto-predereferenced core fast fast core (no bounds checking, profiling, or tracing) gcdebug performs a full GC run before every op dispatch (good for debugging GC problems) switch switch core trace bounds checking core w/ trace info (see 'parrot --help-debug')The
jit
, switch-jit
, and cgp-jit
options are currently aliases for the fast
, switch
, and cgp
options, respectively. We do not recommend their use in new code; they will continue working for existing code per our deprecation policy.
parrot --help-debug
for available flag bits.VM Options
- -w, --warnings Turn on warnings. See
- -D, --parrot-debug Turn on interpreter debug flag. See
- --gc-debug Turn on GC (Garbage Collection) debugging. This imposes some stress on the GC subsystem and can slow down execution considerably.
- -G, --no-gc This turns off GC. This may be useful to find GC related bugs. Don't use this option for longer running programs: as memory is no longer recycled, it may quickly become exhausted.
- --leak-test, --destroy-at-end Free all memory of the last interpreter. This is useful when running leak checkers.
- -., --wait Read a keystroke before starting. This is useful when you want to attach a debugger on platforms such as Windows.
- --runtime-prefix Print the runtime prefix path and exit.
parrot --help-debug
for available flag bits.
parrot --help-debug
for available flag bits.
<file>
If the file ends in .pbc it will be interpreted immediately.
If the file ends in .pasm, then it is parsed as PASM code. Otherwise, it is parsed as PIR code. In both cases, it will then be run, unless the -o
flag was given.
If the file
is a single dash, input from stdin
is read.
[arguments ...]
Optional arguments passed to the running program as ARGV. The program is assumed to know what to do with these.
Generated files
About runcores
The runcore (or runloop) tells Parrot how to find the C code that implements each instruction. Parrot provides more than one way to do this, partly because no single runcore will perform optimally on all architectures (or even for all problems on a given architecture), and partly because some of the runcores have specific debugging and tracing capabilities.
In the default "slow" runcore, each opcode is a separate C function. That's pretty easy in pseudocode:
slow_runcore( op ): while ( op ): op = op_function( op ) check_for_events()
The GC debugging runcore is similar:
gcdebug_runcore( op ): while ( op ): perform_full_gc_run() op = op_function( op ) check_for_events()
Of course, this is much slower, but is extremely helpful for pinning memory corruption problems that affect GC down to single-instruction resolution. See http://www.oreillynet.com/onlamp/blog/2007/10/debugging_gc_problems_in_parro.html for more information.
The trace and profile cores are also based on the "slow" core, doing full bounds checking, and also printing runtime information to stderr.
The switched core eschews these tiny op functions in favor of cases in a large switch statement:
switch_runcore( op ): while ( op ): switch *op: case NOP: ... case STORE: ... ...
Depending on the C compiler implementation, this may be faster than function calling. On older systems, it may fail to compile altogether.
The computed-goto ("cgoto") runcore avoids the overhead of function calls by jumping directly to the address where each opcode's function starts. The computed-goto-prederef ("CGP") core takes this one step further by replacing opcode numbers in the bytecode with those opfunc addresses. See "Predereferencing" in docs/glossary.pod for a fuller explanation.
Operation table
Command Line Action Output --------------------------------------------- parrot x.pir run parrot x.pasm run parrot x.pbc run -o x.pasm x.pir ass x.pasm -o x.pasm y.pasm ass x.pasm -o x.pbc x.pir ass x.pbc -o x.pbc x.pasm ass x.pbc -o x.pbc -r x.pasm ass/run pasm x.pbc -o x.pbc -r -r x.pasm ass/run pbc x.pbc -o x.o x.pbc obj
... where the possible actions are:
run ... yes, run the program ass ... assemble sourcefile obj .. produce native (ELF) object file for the EXEC subsystem
FILES
main.c