path: root/lib/B/Bytecode.pm

#      Bytecode.pm
#
#      Copyright (c) 1996-1998 Malcolm Beattie
#
#      You may distribute under the terms of either the GNU General Public
#      License or the Artistic License, as specified in the README file.
#
package B::Bytecode;
use strict;
use Carp;
use IO::File;

use B qw(minus_c main_cv main_root main_start comppadlist
	 class peekop walkoptree svref_2object cstring walksymtable);
use B::Asmdata qw(@optype @specialsv_name);
use B::Assembler qw(assemble_fh);

my %optype_enum;
my $i;
for ($i = 0; $i < @optype; $i++) {
    $optype_enum{$optype[$i]} = $i;
}

# Following is SVf_POK|SVp_POK
# XXX Shouldn't be hardwired
sub POK () { 0x04040000 }

# Following is SVf_IOK|SVp_OK
# XXX Shouldn't be hardwired
sub IOK () { 0x01010000 }

my ($verbose, $module_only, $no_assemble, $debug_bc, $debug_cv);
my $assembler_pid;

# Optimisation options. On the command line, use hyphens instead of
# underscores for compatibility with gcc-style options. We use
# underscores here because they are OK in (strict) barewords.
my ($strip_syntree, $compress_nullops, $omit_seq, $bypass_nullops);
my %optimise = (strip_syntax_tree	=> \$strip_syntree,
		compress_nullops	=> \$compress_nullops,
		omit_sequence_numbers	=> \$omit_seq,
		bypass_nullops		=> \$bypass_nullops);

my $nextix = 0;
my %symtable;	# maps object addresses to object indices.
		# Filled in at allocation (newsv/newop) time.
my %saved;	# maps object addresses (for SVish classes) to "saved yet?"
		# flag. Set at FOO::bytecode time usually by SV::bytecode.
		# Manipulated via saved(), mark_saved(), unmark_saved().

my $svix = -1;	# we keep track of when the sv register contains an element
		# of the object table to avoid unnecessary repeated
		# consecutive ldsv instructions.
my $opix = -1;	# Ditto for the op register.

sub ldsv {
    my $ix = shift;
    if ($ix != $svix) {
	print "ldsv $ix\n";
	$svix = $ix;
    }
}

sub stsv {
    my $ix = shift;
    print "stsv $ix\n";
    $svix = $ix;
}

sub set_svix {
    $svix = shift;
}

sub ldop {
    my $ix = shift;
    if ($ix != $opix) {
	print "ldop $ix\n";
	$opix = $ix;
    }
}

sub stop {
    my $ix = shift;
    print "stop $ix\n";
    $opix = $ix;
}

sub set_opix {
    $opix = shift;
}

sub pvstring {
    my $str = shift;
    if (defined($str)) {
	return cstring($str . "\0");
    } else {
	return '""';
    }
}

sub saved { $saved{${$_[0]}} }
sub mark_saved { $saved{${$_[0]}} = 1 }
sub unmark_saved { $saved{${$_[0]}} = 0 }

sub debug { $debug_bc = shift }

sub B::OBJECT::nyi {
    my $obj = shift;
    warn sprintf("bytecode save method for %s (0x%x) not yet implemented\n",
		 class($obj), $$obj);
}

#
# objix may stomp on the op register (for op objects)
# or the sv register (for SV objects)
#
sub B::OBJECT::objix {
    my $obj = shift;
    my $ix = $symtable{$$obj};
    if (defined($ix)) {
	return $ix;
    } else {
	$obj->newix($nextix);
	return $symtable{$$obj} = $nextix++;
    }
}

sub B::SV::newix {
    my ($sv, $ix) = @_;
    printf "newsv %d\t# %s\n", $sv->FLAGS & 0xf, class($sv);
    stsv($ix);    
}

sub B::GV::newix {
    my ($gv, $ix) = @_;
    my $gvname = $gv->NAME;
    my $name = cstring($gv->STASH->NAME . "::" . $gvname);
    print "gv_fetchpv $name\n";
    stsv($ix);
}

sub B::HV::newix {
    my ($hv, $ix) = @_;
    my $name = $hv->NAME;
    if ($name) {
	# It's a stash
	printf "gv_stashpv %s\n", cstring($name);
	stsv($ix);
    } else {
	# It's an ordinary HV. Fall back to ordinary newix method
	$hv->B::SV::newix($ix);
    }
}

sub B::SPECIAL::newix {
    my ($sv, $ix) = @_;
    # Special case. $$sv is not the address of the SV but an
    # index into svspecialsv_list.
    printf "ldspecsv $$sv\t# %s\n", $specialsv_name[$$sv];
    stsv($ix);
}

sub B::OP::newix {
    my ($op, $ix) = @_;
    my $class = class($op);
    my $typenum = $optype_enum{$class};
    croak "OP::newix: can't understand class $class" unless defined($typenum);
    print "newop $typenum\t# $class\n";
    stop($ix);
}

sub B::OP::walkoptree_debug {
    my $op = shift;
    warn(sprintf("walkoptree: %s\n", peekop($op)));
}

sub B::OP::bytecode {
    my $op = shift;
    my $next = $op->next;
    my $nextix;
    my $sibix = $op->sibling->objix;
    my $ix = $op->objix;
    my $type = $op->type;

    if ($bypass_nullops) {
	$next = $next->next while $$next && $next->type == 0;
    }
    $nextix = $next->objix;

    printf "# %s\n", peekop($op) if $debug_bc;
    ldop($ix);
    print "op_next $nextix\n";
    print "op_sibling $sibix\n" unless $strip_syntree;
    printf "op_type %s\t# %d\n", $op->ppaddr, $type;
    printf("op_seq %d\n", $op->seq) unless $omit_seq;
    if ($type || !$compress_nullops) {
	printf "op_targ %d\nop_flags 0x%x\nop_private 0x%x\n",
	    $op->targ, $op->flags, $op->private;
    }
}

sub B::UNOP::bytecode {
    my $op = shift;
    my $firstix = $op->first->objix;
    $op->B::OP::bytecode;
    if (($op->type || !$compress_nullops) && !$strip_syntree) {
	print "op_first $firstix\n";
    }
}

sub B::LOGOP::bytecode {
    my $op = shift;
    my $otherix = $op->other->objix;
    $op->B::UNOP::bytecode;
    print "op_other $otherix\n";
}

sub B::SVOP::bytecode {
    my $op = shift;
    my $sv = $op->sv;
    my $svix = $sv->objix;
    $op->B::OP::bytecode;
    print "op_sv $svix\n";
    $sv->bytecode;
}

sub B::GVOP::bytecode {
    my $op = shift;
    my $gv = $op->gv;
    my $gvix = $gv->objix;
    $op->B::OP::bytecode;
    print "op_gv $gvix\n";
    $gv->bytecode;
}

sub B::PVOP::bytecode {
    my $op = shift;
    my $pv = $op->pv;
    $op->B::OP::bytecode;
    #
    # This would be easy except that OP_TRANS uses a PVOP to store an
    # endian-dependent array of 256 shorts instead of a plain string.
    #
    if ($op->ppaddr eq "pp_trans") {
	my @shorts = unpack("s256", $pv); # assembler handles endianness
	print "op_pv_tr ", join(",", @shorts), "\n";
    } else {
	printf "newpv %s\nop_pv\n", pvstring($pv);
    }
}

sub B::BINOP::bytecode {
    my $op = shift;
    my $lastix = $op->last->objix;
    $op->B::UNOP::bytecode;
    if (($op->type || !$compress_nullops) && !$strip_syntree) {
	print "op_last $lastix\n";
    }
}

sub B::CONDOP::bytecode {
    my $op = shift;
    my $trueix = $op->true->objix;
    my $falseix = $op->false->objix;
    $op->B::UNOP::bytecode;
    print "op_true $trueix\nop_false $falseix\n";
}

sub B::LISTOP::bytecode {
    my $op = shift;
    my $children = $op->children;
    $op->B::BINOP::bytecode;
    if (($op->type || !$compress_nullops) && !$strip_syntree) {
	print "op_children $children\n";
    }
}

sub B::LOOP::bytecode {
    my $op = shift;
    my $redoopix = $op->redoop->objix;
    my $nextopix = $op->nextop->objix;
    my $lastopix = $op->lastop->objix;
    $op->B::LISTOP::bytecode;
    print "op_redoop $redoopix\nop_nextop $nextopix\nop_lastop $lastopix\n";
}

sub B::COP::bytecode {
    my $op = shift;
    my $stash = $op->stash;
    my $stashix = $stash->objix;
    my $filegv = $op->filegv;
    my $filegvix = $filegv->objix;
    my $line = $op->line;
    if ($debug_bc) {
	printf "# line %s:%d\n", $filegv->SV->PV, $line;
    }
    $op->B::OP::bytecode;
    printf <<"EOT", pvstring($op->label), $op->cop_seq, $op->arybase;
newpv %s
cop_label
cop_stash $stashix
cop_seq %d
cop_filegv $filegvix
cop_arybase %d
cop_line $line
EOT
    $filegv->bytecode;
    $stash->bytecode;
}

sub B::PMOP::bytecode {
    my $op = shift;
    my $replroot = $op->pmreplroot;
    my $replrootix = $replroot->objix;
    my $replstartix = $op->pmreplstart->objix;
    my $ppaddr = $op->ppaddr;
    # pmnext is corrupt in some PMOPs (see misc.t for example)
    #my $pmnextix = $op->pmnext->objix;

    if ($$replroot) {
	# OP_PUSHRE (a mutated version of OP_MATCH for the regexp
	# argument to a split) stores a GV in op_pmreplroot instead
	# of a substitution syntax tree. We don't want to walk that...
	if ($ppaddr eq "pp_pushre") {
	    $replroot->bytecode;
	} else {
	    walkoptree($replroot, "bytecode");
	}
    }
    $op->B::LISTOP::bytecode;
    if ($ppaddr eq "pp_pushre") {
	printf "op_pmreplrootgv $replrootix\n";
    } else {
	print "op_pmreplroot $replrootix\nop_pmreplstart $replstartix\n";
    }
    my $re = pvstring($op->precomp);
    # op_pmnext omitted since a perl bug means it's sometime corrupt
    printf <<"EOT", $op->pmflags, $op->pmpermflags;
op_pmflags 0x%x
op_pmpermflags 0x%x
newpv $re
pregcomp
EOT
}

sub B::SV::bytecode {
    my $sv = shift;
    return if saved($sv);
    my $ix = $sv->objix;
    my $refcnt = $sv->REFCNT;
    my $flags = sprintf("0x%x", $sv->FLAGS);
    ldsv($ix);
    print "sv_refcnt $refcnt\nsv_flags $flags\n";
    mark_saved($sv);
}

sub B::PV::bytecode {
    my $sv = shift;
    return if saved($sv);
    $sv->B::SV::bytecode;
    printf("newpv %s\nxpv\n", pvstring($sv->PV)) if $sv->FLAGS & POK;
}

sub B::IV::bytecode {
    my $sv = shift;
    return if saved($sv);
    my $iv = $sv->IVX;
    $sv->B::SV::bytecode;
    printf "%s $iv\n", $sv->needs64bits ? "xiv64" : "xiv32";
}

sub B::NV::bytecode {
    my $sv = shift;
    return if saved($sv);
    $sv->B::SV::bytecode;
    printf "xnv %s\n", $sv->NVX;
}

sub B::RV::bytecode {
    my $sv = shift;
    return if saved($sv);
    my $rv = $sv->RV;
    my $rvix = $rv->objix;
    $rv->bytecode;
    $sv->B::SV::bytecode;
    print "xrv $rvix\n";
}

sub B::PVIV::bytecode {
    my $sv = shift;
    return if saved($sv);
    my $iv = $sv->IVX;
    $sv->B::PV::bytecode;
    printf "%s $iv\n", $sv->needs64bits ? "xiv64" : "xiv32";
}

sub B::PVNV::bytecode {
    my ($sv, $flag) = @_;
    # The $flag argument is passed through PVMG::bytecode by BM::bytecode
    # and AV::bytecode and indicates special handling. $flag = 1 is used by
    # BM::bytecode and means that we should ensure we save the whole B-M
    # table. It consists of 257 bytes (256 char array plus a final \0)
    # which follow the ordinary PV+\0 and the 257 bytes are *not* reflected
    # in SvCUR. $flag = 2 is used by AV::bytecode and means that we only
    # call SV::bytecode instead of saving PV and calling NV::bytecode since
    # PV/NV/IV stuff is different for AVs.
    return if saved($sv);
    if ($flag == 2) {
	$sv->B::SV::bytecode;
    } else {
	my $pv = $sv->PV;
	$sv->B::IV::bytecode;
	printf "xnv %s\n", $sv->NVX;
	if ($flag == 1) {
	    $pv .= "\0" . $sv->TABLE;
	    printf "newpv %s\npv_cur %d\nxpv\n", pvstring($pv),length($pv)-257;
	} else {
	    printf("newpv %s\nxpv\n", pvstring($pv)) if $sv->FLAGS & POK;
	}
    }
}

sub B::PVMG::bytecode {
    my ($sv, $flag) = @_;
    # See B::PVNV::bytecode for an explanation of $flag.
    return if saved($sv);
    # XXX We assume SvSTASH is already saved and don't save it later ourselves
    my $stashix = $sv->SvSTASH->objix;
    my @mgchain = $sv->MAGIC;
    my (@mgobjix, $mg);
    #
    # We need to traverse the magic chain and get objix for each OBJ
    # field *before* we do B::PVNV::bytecode since objix overwrites
    # the sv register. However, we need to write the magic-saving
    # bytecode *after* B::PVNV::bytecode since sv isn't initialised
    # to refer to $sv until then.
    #
    @mgobjix = map($_->OBJ->objix, @mgchain);
    $sv->B::PVNV::bytecode($flag);
    print "xmg_stash $stashix\n";
    foreach $mg (@mgchain) {
	printf "sv_magic %s\nmg_obj %d\nnewpv %s\nmg_pv\n",
	    cstring($mg->TYPE), shift(@mgobjix), pvstring($mg->PTR);
    }
}

sub B::PVLV::bytecode {
    my $sv = shift;
    return if saved($sv);
    $sv->B::PVMG::bytecode;
    printf <<'EOT', $sv->TARGOFF, $sv->TARGLEN, cstring($sv->TYPE);
xlv_targoff %d
xlv_targlen %d
xlv_type %s
EOT
}

sub B::BM::bytecode {
    my $sv = shift;
    return if saved($sv);
    # See PVNV::bytecode for an explanation of what the argument does
    $sv->B::PVMG::bytecode(1);
    printf "xbm_useful %d\nxbm_previous %d\nxbm_rare %d\n",
	$sv->USEFUL, $sv->PREVIOUS, $sv->RARE;
}

sub B::GV::bytecode {
    my $gv = shift;
    return if saved($gv);
    my $ix = $gv->objix;
    mark_saved($gv);
    my $gvname = $gv->NAME;
    my $name = cstring($gv->STASH->NAME . "::" . $gvname);
    my $egv = $gv->EGV;
    my $egvix = $egv->objix;
    ldsv($ix);
    printf <<"EOT", $gv->FLAGS, $gv->GvFLAGS, $gv->LINE;
sv_flags 0x%x
xgv_flags 0x%x
gp_line %d
EOT
    my $refcnt = $gv->REFCNT;
    printf("sv_refcnt_add %d\n", $refcnt - 1) if $refcnt > 1;
    my $gvrefcnt = $gv->GvREFCNT;
    printf("gp_refcnt_add %d\n", $gvrefcnt - 1) if $gvrefcnt > 1;
    if ($gvrefcnt > 1 &&  $ix != $egvix) {
	print "gp_share $egvix\n";
    } else {
	if ($gvname !~ /^([^A-Za-z]|STDIN|STDOUT|STDERR|ARGV|SIG|ENV)$/) {
	    my $i;
	    my @subfield_names = qw(SV AV HV CV FILEGV FORM IO);
	    my @subfields = map($gv->$_(), @subfield_names);
	    my @ixes = map($_->objix, @subfields);
	    # Reset sv register for $gv
	    ldsv($ix);
	    for ($i = 0; $i < @ixes; $i++) {
		printf "gp_%s %d\n", lc($subfield_names[$i]), $ixes[$i];
	    }
	    # Now save all the subfields
	    my $sv;
	    foreach $sv (@subfields) {
		$sv->bytecode;
	    }
	}
    }
}

sub B::HV::bytecode {
    my $hv = shift;
    return if saved($hv);
    mark_saved($hv);
    my $name = $hv->NAME;
    my $ix = $hv->objix;
    if (!$name) {
	# It's an ordinary HV. Stashes have NAME set and need no further
	# saving beyond the gv_stashpv that $hv->objix already ensures.
	my @contents = $hv->ARRAY;
	my ($i, @ixes);
	for ($i = 1; $i < @contents; $i += 2) {
	    push(@ixes, $contents[$i]->objix);
	}
	for ($i = 1; $i < @contents; $i += 2) {
	    $contents[$i]->bytecode;
	}
	ldsv($ix);
	for ($i = 0; $i < @contents; $i += 2) {
	    printf("newpv %s\nhv_store %d\n",
		   pvstring($contents[$i]), $ixes[$i / 2]);
	}
	printf "sv_refcnt %d\nsv_flags 0x%x\n", $hv->REFCNT, $hv->FLAGS;
    }
}

sub B::AV::bytecode {
    my $av = shift;
    return if saved($av);
    my $ix = $av->objix;
    my $fill = $av->FILL;
    my $max = $av->MAX;
    my (@array, @ixes);
    if ($fill > -1) {
	@array = $av->ARRAY;
	@ixes = map($_->objix, @array);
	my $sv;
	foreach $sv (@array) {
	    $sv->bytecode;
	}
    }
    # See PVNV::bytecode for the meaning of the flag argument of 2.
    $av->B::PVMG::bytecode(2);
    # Recover sv register and set AvMAX and AvFILL to -1 (since we
    # create an AV with NEWSV and SvUPGRADE rather than doing newAV
    # which is what sets AvMAX and AvFILL.
    ldsv($ix);
    printf "xav_flags 0x%x\nxav_max -1\nxav_fill -1\n", $av->AvFLAGS;
    if ($fill > -1) {
	my $elix;
	foreach $elix (@ixes) {
	    print "av_push $elix\n";
	}
    } else {
	if ($max > -1) {
	    print "av_extend $max\n";
	}
    }
}

sub B::CV::bytecode {
    my $cv = shift;
    return if saved($cv);
    my $ix = $cv->objix;
    $cv->B::PVMG::bytecode;
    my $i;
    my @subfield_names = qw(ROOT START STASH GV FILEGV PADLIST OUTSIDE);
    my @subfields = map($cv->$_(), @subfield_names);
    my @ixes = map($_->objix, @subfields);
    # Save OP tree from CvROOT (first element of @subfields)
    my $root = shift @subfields;
    if ($$root) {
	walkoptree($root, "bytecode");
    }
    # Reset sv register for $cv (since above ->objix calls stomped on it)
    ldsv($ix);
    for ($i = 0; $i < @ixes; $i++) {
	printf "xcv_%s %d\n", lc($subfield_names[$i]), $ixes[$i];
    }
    printf "xcv_depth %d\nxcv_flags 0x%x\n", $cv->DEPTH, $cv->FLAGS;
    # Now save all the subfields (except for CvROOT which was handled
    # above) and CvSTART (now the initial element of @subfields).
    shift @subfields; # bye-bye CvSTART
    my $sv;
    foreach $sv (@subfields) {
	$sv->bytecode;
    }
}

sub B::IO::bytecode {
    my $io = shift;
    return if saved($io);
    my $ix = $io->objix;
    my $top_gv = $io->TOP_GV;
    my $top_gvix = $top_gv->objix;
    my $fmt_gv = $io->FMT_GV;
    my $fmt_gvix = $fmt_gv->objix;
    my $bottom_gv = $io->BOTTOM_GV;
    my $bottom_gvix = $bottom_gv->objix;

    $io->B::PVMG::bytecode;
    ldsv($ix);
    print "xio_top_gv $top_gvix\n";
    print "xio_fmt_gv $fmt_gvix\n";
    print "xio_bottom_gv $bottom_gvix\n";
    my $field;
    foreach $field (qw(TOP_NAME FMT_NAME BOTTOM_NAME)) {
	printf "newpv %s\nxio_%s\n", pvstring($io->$field()), lc($field);
    }
    foreach $field (qw(LINES PAGE PAGE_LEN LINES_LEFT SUBPROCESS)) {
	printf "xio_%s %d\n", lc($field), $io->$field();
    }
    printf "xio_type %s\nxio_flags 0x%x\n", cstring($io->IoTYPE), $io->IoFLAGS;
    $top_gv->bytecode;
    $fmt_gv->bytecode;
    $bottom_gv->bytecode;
}

sub B::SPECIAL::bytecode {
    # nothing extra needs doing
}

sub bytecompile_object {
    my $sv;
    foreach $sv (@_) {
	svref_2object($sv)->bytecode;
    }
}

sub B::GV::bytecodecv {
    my $gv = shift;
    my $cv = $gv->CV;
    if ($$cv && !saved($cv)) {
	if ($debug_cv) {
	    warn sprintf("saving extra CV &%s::%s (0x%x) from GV 0x%x\n",
			 $gv->STASH->NAME, $gv->NAME, $$cv, $$gv);
	}
	$gv->bytecode;
    }
}

sub bytecompile_main {
    my $curpad = (comppadlist->ARRAY)[1];
    my $curpadix = $curpad->objix;
    $curpad->bytecode;
    walkoptree(main_root, "bytecode");
    warn "done main program, now walking symbol table\n" if $debug_bc;
    my ($pack, %exclude);
    foreach $pack (qw(B O AutoLoader DynaLoader Config DB VMS strict vars
		      FileHandle Exporter Carp UNIVERSAL IO Fcntl Symbol
		      SelectSaver blib Cwd))
    {
	$exclude{$pack."::"} = 1;
    }
    no strict qw(vars refs);
    walksymtable(\%{"main::"}, "bytecodecv", sub {
	warn "considering $_[0]\n" if $debug_bc;
	return !defined($exclude{$_[0]});
    });
    if (!$module_only) {
	printf "main_root %d\n", main_root->objix;
	printf "main_start %d\n", main_start->objix;
	printf "curpad $curpadix\n";
	# XXX Do min_intro_pending and max_intro_pending matter?
    }
}

sub prepare_assemble {
    my $newfh = IO::File->new_tmpfile;
    select($newfh);
    binmode $newfh;
    return $newfh;
}

sub do_assemble {
    my $fh = shift;
    seek($fh, 0, 0); # rewind the temporary file
    assemble_fh($fh, sub { print OUT @_ });
}

sub compile {
    my @options = @_;
    my ($option, $opt, $arg);
    open(OUT, ">&STDOUT");
    binmode OUT;
    select(OUT);
  OPTION:
    while ($option = shift @options) {
	if ($option =~ /^-(.)(.*)/) {
	    $opt = $1;
	    $arg = $2;
	} else {
	    unshift @options, $option;
	    last OPTION;
	}
	if ($opt eq "-" && $arg eq "-") {
	    shift @options;
	    last OPTION;
	} elsif ($opt eq "o") {
	    $arg ||= shift @options;
	    open(OUT, ">$arg") or return "$arg: $!\n";
	    binmode OUT;
	} elsif ($opt eq "D") {
	    $arg ||= shift @options;
	    foreach $arg (split(//, $arg)) {
		if ($arg eq "b") {
		    $| = 1;
		    debug(1);
		} elsif ($arg eq "o") {
		    B->debug(1);
		} elsif ($arg eq "a") {
		    B::Assembler::debug(1);
		} elsif ($arg eq "C") {
		    $debug_cv = 1;
		}
	    }
	} elsif ($opt eq "v") {
	    $verbose = 1;
	} elsif ($opt eq "m") {
	    $module_only = 1;
	} elsif ($opt eq "S") {
	    $no_assemble = 1;
	} elsif ($opt eq "f") {
	    $arg ||= shift @options;
	    my $value = $arg !~ s/^no-//;
	    $arg =~ s/-/_/g;
	    my $ref = $optimise{$arg};
	    if (defined($ref)) {
		$$ref = $value;
	    } else {
		warn qq(ignoring unknown optimisation option "$arg"\n);
	    }
	} elsif ($opt eq "O") {
	    $arg = 1 if $arg eq "";
	    my $ref;
	    foreach $ref (values %optimise) {
		$$ref = 0;
	    }
	    if ($arg >= 6) {
		$strip_syntree = 1;
	    }
	    if ($arg >= 2) {
		$bypass_nullops = 1;
	    }
	    if ($arg >= 1) {
		$compress_nullops = 1;
		$omit_seq = 1;
	    }
	}
    }
    if (@options) {
	return sub {
	    my $objname;
	    my $newfh; 
	    $newfh = prepare_assemble() unless $no_assemble;
	    foreach $objname (@options) {
		eval "bytecompile_object(\\$objname)";
	    }
	    do_assemble($newfh) unless $no_assemble;
	}
    } else {
	return sub {
	    my $newfh; 
	    $newfh = prepare_assemble() unless $no_assemble;
	    bytecompile_main();
	    do_assemble($newfh) unless $no_assemble;
	}
    }
}

1;