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2002 lines
57 KiB
2002 lines
57 KiB
# CC.pm
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#
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# Copyright (c) 1996, 1997, 1998 Malcolm Beattie
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#
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# You may distribute under the terms of either the GNU General Public
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# License or the Artistic License, as specified in the README file.
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#
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package B::CC;
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use Config;
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use strict;
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use B qw(main_start main_root class comppadlist peekop svref_2object
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timing_info init_av sv_undef amagic_generation
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OPf_WANT_LIST OPf_WANT OPf_MOD OPf_STACKED OPf_SPECIAL
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OPpASSIGN_BACKWARDS OPpLVAL_INTRO OPpDEREF_AV OPpDEREF_HV
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OPpDEREF OPpFLIP_LINENUM G_ARRAY G_SCALAR
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CXt_NULL CXt_SUB CXt_EVAL CXt_LOOP CXt_SUBST CXt_BLOCK
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);
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use B::C qw(save_unused_subs objsym init_sections mark_unused
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output_all output_boilerplate output_main);
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use B::Bblock qw(find_leaders);
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use B::Stackobj qw(:types :flags);
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# These should probably be elsewhere
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# Flags for $op->flags
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my $module; # module name (when compiled with -m)
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my %done; # hash keyed by $$op of leaders of basic blocks
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# which have already been done.
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my $leaders; # ref to hash of basic block leaders. Keys are $$op
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# addresses, values are the $op objects themselves.
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my @bblock_todo; # list of leaders of basic blocks that need visiting
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# sometime.
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my @cc_todo; # list of tuples defining what PP code needs to be
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# saved (e.g. CV, main or PMOP repl code). Each tuple
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# is [$name, $root, $start, @padlist]. PMOP repl code
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# tuples inherit padlist.
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my @stack; # shadows perl's stack when contents are known.
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# Values are objects derived from class B::Stackobj
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my @pad; # Lexicals in current pad as Stackobj-derived objects
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my @padlist; # Copy of current padlist so PMOP repl code can find it
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my @cxstack; # Shadows the (compile-time) cxstack for next,last,redo
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my $jmpbuf_ix = 0; # Next free index for dynamically allocated jmpbufs
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my %constobj; # OP_CONST constants as Stackobj-derived objects
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# keyed by $$sv.
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my $need_freetmps = 0; # We may postpone FREETMPS to the end of each basic
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# block or even to the end of each loop of blocks,
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# depending on optimisation options.
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my $know_op = 0; # Set when C variable op already holds the right op
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# (from an immediately preceding DOOP(ppname)).
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my $errors = 0; # Number of errors encountered
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my %skip_stack; # Hash of PP names which don't need write_back_stack
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my %skip_lexicals; # Hash of PP names which don't need write_back_lexicals
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my %skip_invalidate; # Hash of PP names which don't need invalidate_lexicals
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my %ignore_op; # Hash of ops which do nothing except returning op_next
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my %need_curcop; # Hash of ops which need PL_curcop
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my %lexstate; #state of padsvs at the start of a bblock
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BEGIN {
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foreach (qw(pp_scalar pp_regcmaybe pp_lineseq pp_scope pp_null)) {
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$ignore_op{$_} = 1;
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}
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}
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my ($module_name);
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my ($debug_op, $debug_stack, $debug_cxstack, $debug_pad, $debug_runtime,
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$debug_shadow, $debug_queue, $debug_lineno, $debug_timings);
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# Optimisation options. On the command line, use hyphens instead of
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# underscores for compatibility with gcc-style options. We use
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# underscores here because they are OK in (strict) barewords.
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my ($freetmps_each_bblock, $freetmps_each_loop, $omit_taint);
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my %optimise = (freetmps_each_bblock => \$freetmps_each_bblock,
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freetmps_each_loop => \$freetmps_each_loop,
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omit_taint => \$omit_taint);
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# perl patchlevel to generate code for (defaults to current patchlevel)
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my $patchlevel = int(0.5 + 1000 * ($] - 5));
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# Could rewrite push_runtime() and output_runtime() to use a
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# temporary file if memory is at a premium.
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my $ppname; # name of current fake PP function
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my $runtime_list_ref;
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my $declare_ref; # Hash ref keyed by C variable type of declarations.
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my @pp_list; # list of [$ppname, $runtime_list_ref, $declare_ref]
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# tuples to be written out.
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my ($init, $decl);
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sub init_hash { map { $_ => 1 } @_ }
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#
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# Initialise the hashes for the default PP functions where we can avoid
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# either write_back_stack, write_back_lexicals or invalidate_lexicals.
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#
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%skip_lexicals = init_hash qw(pp_enter pp_enterloop);
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%skip_invalidate = init_hash qw(pp_enter pp_enterloop);
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%need_curcop = init_hash qw(pp_rv2gv pp_bless pp_repeat pp_sort pp_caller
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pp_reset pp_rv2cv pp_entereval pp_require pp_dofile
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pp_entertry pp_enterloop pp_enteriter pp_entersub
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pp_enter pp_method);
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sub debug {
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if ($debug_runtime) {
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warn(@_);
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} else {
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my @tmp=@_;
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runtime(map { chomp; "/* $_ */"} @tmp);
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}
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}
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sub declare {
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my ($type, $var) = @_;
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push(@{$declare_ref->{$type}}, $var);
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}
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sub push_runtime {
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push(@$runtime_list_ref, @_);
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warn join("\n", @_) . "\n" if $debug_runtime;
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}
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sub save_runtime {
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push(@pp_list, [$ppname, $runtime_list_ref, $declare_ref]);
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}
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sub output_runtime {
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my $ppdata;
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print qq(#include "cc_runtime.h"\n);
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foreach $ppdata (@pp_list) {
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my ($name, $runtime, $declare) = @$ppdata;
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print "\nstatic\nCCPP($name)\n{\n";
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my ($type, $varlist, $line);
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while (($type, $varlist) = each %$declare) {
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print "\t$type ", join(", ", @$varlist), ";\n";
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}
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foreach $line (@$runtime) {
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print $line, "\n";
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}
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print "}\n";
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}
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}
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sub runtime {
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my $line;
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foreach $line (@_) {
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push_runtime("\t$line");
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}
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}
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sub init_pp {
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$ppname = shift;
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$runtime_list_ref = [];
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$declare_ref = {};
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runtime("dSP;");
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declare("I32", "oldsave");
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declare("SV", "**svp");
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map { declare("SV", "*$_") } qw(sv src dst left right);
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declare("MAGIC", "*mg");
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$decl->add("static OP * $ppname (pTHX);");
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debug "init_pp: $ppname\n" if $debug_queue;
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}
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# Initialise runtime_callback function for Stackobj class
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BEGIN { B::Stackobj::set_callback(\&runtime) }
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# Initialise saveoptree_callback for B::C class
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sub cc_queue {
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my ($name, $root, $start, @pl) = @_;
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debug "cc_queue: name $name, root $root, start $start, padlist (@pl)\n"
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if $debug_queue;
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if ($name eq "*ignore*") {
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$name = 0;
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} else {
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push(@cc_todo, [$name, $root, $start, (@pl ? @pl : @padlist)]);
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}
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my $fakeop = new B::FAKEOP ("next" => 0, sibling => 0, ppaddr => $name);
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$start = $fakeop->save;
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debug "cc_queue: name $name returns $start\n" if $debug_queue;
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return $start;
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}
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BEGIN { B::C::set_callback(\&cc_queue) }
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sub valid_int { $_[0]->{flags} & VALID_INT }
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sub valid_double { $_[0]->{flags} & VALID_DOUBLE }
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sub valid_numeric { $_[0]->{flags} & (VALID_INT | VALID_DOUBLE) }
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sub valid_sv { $_[0]->{flags} & VALID_SV }
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sub top_int { @stack ? $stack[-1]->as_int : "TOPi" }
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sub top_double { @stack ? $stack[-1]->as_double : "TOPn" }
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sub top_numeric { @stack ? $stack[-1]->as_numeric : "TOPn" }
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sub top_sv { @stack ? $stack[-1]->as_sv : "TOPs" }
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sub top_bool { @stack ? $stack[-1]->as_bool : "SvTRUE(TOPs)" }
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sub pop_int { @stack ? (pop @stack)->as_int : "POPi" }
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sub pop_double { @stack ? (pop @stack)->as_double : "POPn" }
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sub pop_numeric { @stack ? (pop @stack)->as_numeric : "POPn" }
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sub pop_sv { @stack ? (pop @stack)->as_sv : "POPs" }
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sub pop_bool {
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if (@stack) {
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return ((pop @stack)->as_bool);
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} else {
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# Careful: POPs has an auto-decrement and SvTRUE evaluates
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# its argument more than once.
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runtime("sv = POPs;");
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return "SvTRUE(sv)";
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}
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}
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sub write_back_lexicals {
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my $avoid = shift || 0;
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debug "write_back_lexicals($avoid) called from @{[(caller(1))[3]]}\n"
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if $debug_shadow;
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my $lex;
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foreach $lex (@pad) {
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next unless ref($lex);
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$lex->write_back unless $lex->{flags} & $avoid;
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}
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}
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sub save_or_restore_lexical_state {
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my $bblock=shift;
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unless( exists $lexstate{$bblock}){
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foreach my $lex (@pad) {
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next unless ref($lex);
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${$lexstate{$bblock}}{$lex->{iv}} = $lex->{flags} ;
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}
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}
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else {
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foreach my $lex (@pad) {
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next unless ref($lex);
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my $old_flags=${$lexstate{$bblock}}{$lex->{iv}} ;
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next if ( $old_flags eq $lex->{flags});
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if (($old_flags & VALID_SV) && !($lex->{flags} & VALID_SV)){
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$lex->write_back;
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}
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if (($old_flags & VALID_DOUBLE) && !($lex->{flags} & VALID_DOUBLE)){
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$lex->load_double;
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}
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if (($old_flags & VALID_INT) && !($lex->{flags} & VALID_INT)){
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$lex->load_int;
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}
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}
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}
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}
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sub write_back_stack {
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my $obj;
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return unless @stack;
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runtime(sprintf("EXTEND(sp, %d);", scalar(@stack)));
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foreach $obj (@stack) {
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runtime(sprintf("PUSHs((SV*)%s);", $obj->as_sv));
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}
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@stack = ();
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}
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sub invalidate_lexicals {
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my $avoid = shift || 0;
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debug "invalidate_lexicals($avoid) called from @{[(caller(1))[3]]}\n"
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if $debug_shadow;
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my $lex;
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foreach $lex (@pad) {
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next unless ref($lex);
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$lex->invalidate unless $lex->{flags} & $avoid;
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}
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}
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sub reload_lexicals {
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my $lex;
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foreach $lex (@pad) {
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next unless ref($lex);
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my $type = $lex->{type};
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if ($type == T_INT) {
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$lex->as_int;
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} elsif ($type == T_DOUBLE) {
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$lex->as_double;
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} else {
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$lex->as_sv;
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}
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}
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}
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{
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package B::Pseudoreg;
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#
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# This class allocates pseudo-registers (OK, so they're C variables).
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#
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my %alloc; # Keyed by variable name. A value of 1 means the
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# variable has been declared. A value of 2 means
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# it's in use.
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sub new_scope { %alloc = () }
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sub new ($$$) {
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my ($class, $type, $prefix) = @_;
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my ($ptr, $i, $varname, $status, $obj);
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$prefix =~ s/^(\**)//;
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$ptr = $1;
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$i = 0;
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do {
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$varname = "$prefix$i";
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$status = $alloc{$varname};
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} while $status == 2;
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if ($status != 1) {
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# Not declared yet
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B::CC::declare($type, "$ptr$varname");
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$alloc{$varname} = 2; # declared and in use
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}
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$obj = bless \$varname, $class;
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return $obj;
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}
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sub DESTROY {
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my $obj = shift;
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$alloc{$$obj} = 1; # no longer in use but still declared
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}
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}
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{
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package B::Shadow;
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#
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# This class gives a standard API for a perl object to shadow a
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# C variable and only generate reloads/write-backs when necessary.
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#
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# Use $obj->load($foo) instead of runtime("shadowed_c_var = foo").
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# Use $obj->write_back whenever shadowed_c_var needs to be up to date.
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# Use $obj->invalidate whenever an unknown function may have
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# set shadow itself.
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sub new {
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my ($class, $write_back) = @_;
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# Object fields are perl shadow variable, validity flag
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# (for *C* variable) and callback sub for write_back
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# (passed perl shadow variable as argument).
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bless [undef, 1, $write_back], $class;
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}
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sub load {
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my ($obj, $newval) = @_;
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$obj->[1] = 0; # C variable no longer valid
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$obj->[0] = $newval;
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}
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sub write_back {
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my $obj = shift;
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if (!($obj->[1])) {
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$obj->[1] = 1; # C variable will now be valid
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&{$obj->[2]}($obj->[0]);
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}
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}
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sub invalidate { $_[0]->[1] = 0 } # force C variable to be invalid
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}
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my $curcop = new B::Shadow (sub {
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my $opsym = shift->save;
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runtime("PL_curcop = (COP*)$opsym;");
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});
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#
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# Context stack shadowing. Mimics stuff in pp_ctl.c, cop.h and so on.
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#
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sub dopoptoloop {
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my $cxix = $#cxstack;
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while ($cxix >= 0 && $cxstack[$cxix]->{type} != CXt_LOOP) {
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$cxix--;
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}
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debug "dopoptoloop: returning $cxix" if $debug_cxstack;
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return $cxix;
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}
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sub dopoptolabel {
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my $label = shift;
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my $cxix = $#cxstack;
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while ($cxix >= 0 &&
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($cxstack[$cxix]->{type} != CXt_LOOP ||
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$cxstack[$cxix]->{label} ne $label)) {
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$cxix--;
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}
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debug "dopoptolabel: returning $cxix" if $debug_cxstack;
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return $cxix;
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}
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sub error {
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my $format = shift;
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my $file = $curcop->[0]->file;
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my $line = $curcop->[0]->line;
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$errors++;
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if (@_) {
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warn sprintf("%s:%d: $format\n", $file, $line, @_);
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} else {
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warn sprintf("%s:%d: %s\n", $file, $line, $format);
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}
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}
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#
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# Load pad takes (the elements of) a PADLIST as arguments and loads
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# up @pad with Stackobj-derived objects which represent those lexicals.
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# If/when perl itself can generate type information (my int $foo) then
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# we'll take advantage of that here. Until then, we'll use various hacks
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# to tell the compiler when we want a lexical to be a particular type
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# or to be a register.
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#
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sub load_pad {
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my ($namelistav, $valuelistav) = @_;
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@padlist = @_;
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my @namelist = $namelistav->ARRAY;
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my @valuelist = $valuelistav->ARRAY;
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my $ix;
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@pad = ();
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debug "load_pad: $#namelist names, $#valuelist values\n" if $debug_pad;
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# Temporary lexicals don't get named so it's possible for @valuelist
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# to be strictly longer than @namelist. We count $ix up to the end of
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# @valuelist but index into @namelist for the name. Any temporaries which
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# run off the end of @namelist will make $namesv undefined and we treat
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# that the same as having an explicit SPECIAL sv_undef object in @namelist.
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# [XXX If/when @_ becomes a lexical, we must start at 0 here.]
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for ($ix = 1; $ix < @valuelist; $ix++) {
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my $namesv = $namelist[$ix];
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my $type = T_UNKNOWN;
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my $flags = 0;
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my $name = "tmp$ix";
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my $class = class($namesv);
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if (!defined($namesv) || $class eq "SPECIAL") {
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# temporaries have &PL_sv_undef instead of a PVNV for a name
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$flags = VALID_SV|TEMPORARY|REGISTER;
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} else {
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if ($namesv->PV =~ /^\$(.*)_([di])(r?)$/) {
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$name = $1;
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if ($2 eq "i") {
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$type = T_INT;
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$flags = VALID_SV|VALID_INT;
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} elsif ($2 eq "d") {
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$type = T_DOUBLE;
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$flags = VALID_SV|VALID_DOUBLE;
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}
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$flags |= REGISTER if $3;
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}
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}
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$pad[$ix] = new B::Stackobj::Padsv ($type, $flags, $ix,
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"i_$name", "d_$name");
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debug sprintf("PL_curpad[$ix] = %s\n", $pad[$ix]->peek) if $debug_pad;
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}
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}
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sub declare_pad {
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my $ix;
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for ($ix = 1; $ix <= $#pad; $ix++) {
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my $type = $pad[$ix]->{type};
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declare("IV", $type == T_INT ?
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sprintf("%s=0",$pad[$ix]->{iv}):$pad[$ix]->{iv}) if $pad[$ix]->save_int;
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declare("double", $type == T_DOUBLE ?
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sprintf("%s = 0",$pad[$ix]->{nv}):$pad[$ix]->{nv} )if $pad[$ix]->save_double;
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}
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}
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#
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# Debugging stuff
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#
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sub peek_stack { sprintf "stack = %s\n", join(" ", map($_->minipeek, @stack)) }
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#
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# OP stuff
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#
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sub label {
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my $op = shift;
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# XXX Preserve original label name for "real" labels?
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return sprintf("lab_%x", $$op);
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}
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sub write_label {
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my $op = shift;
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push_runtime(sprintf(" %s:", label($op)));
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}
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sub loadop {
|
|
my $op = shift;
|
|
my $opsym = $op->save;
|
|
runtime("PL_op = $opsym;") unless $know_op;
|
|
return $opsym;
|
|
}
|
|
|
|
sub doop {
|
|
my $op = shift;
|
|
my $ppname = $op->ppaddr;
|
|
my $sym = loadop($op);
|
|
runtime("DOOP($ppname);");
|
|
$know_op = 1;
|
|
return $sym;
|
|
}
|
|
|
|
sub gimme {
|
|
my $op = shift;
|
|
my $flags = $op->flags;
|
|
return (($flags & OPf_WANT) ? (($flags & OPf_WANT)== OPf_WANT_LIST? G_ARRAY:G_SCALAR) : "dowantarray()");
|
|
}
|
|
|
|
#
|
|
# Code generation for PP code
|
|
#
|
|
|
|
sub pp_null {
|
|
my $op = shift;
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_stub {
|
|
my $op = shift;
|
|
my $gimme = gimme($op);
|
|
if ($gimme != G_ARRAY) {
|
|
my $obj= new B::Stackobj::Const(sv_undef);
|
|
push(@stack, $obj);
|
|
# XXX Change to push a constant sv_undef Stackobj onto @stack
|
|
#write_back_stack();
|
|
#runtime("if ($gimme != G_ARRAY) XPUSHs(&PL_sv_undef);");
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_unstack {
|
|
my $op = shift;
|
|
@stack = ();
|
|
runtime("PP_UNSTACK;");
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_and {
|
|
my $op = shift;
|
|
my $next = $op->next;
|
|
reload_lexicals();
|
|
unshift(@bblock_todo, $next);
|
|
if (@stack >= 1) {
|
|
my $bool = pop_bool();
|
|
write_back_stack();
|
|
save_or_restore_lexical_state($$next);
|
|
runtime(sprintf("if (!$bool) {XPUSHs(&PL_sv_no); goto %s;}", label($next)));
|
|
} else {
|
|
save_or_restore_lexical_state($$next);
|
|
runtime(sprintf("if (!%s) goto %s;", top_bool(), label($next)),
|
|
"*sp--;");
|
|
}
|
|
return $op->other;
|
|
}
|
|
|
|
sub pp_or {
|
|
my $op = shift;
|
|
my $next = $op->next;
|
|
reload_lexicals();
|
|
unshift(@bblock_todo, $next);
|
|
if (@stack >= 1) {
|
|
my $bool = pop_bool @stack;
|
|
write_back_stack();
|
|
save_or_restore_lexical_state($$next);
|
|
runtime(sprintf("if (%s) { XPUSHs(&PL_sv_yes); goto %s; }",
|
|
$bool, label($next)));
|
|
} else {
|
|
save_or_restore_lexical_state($$next);
|
|
runtime(sprintf("if (%s) goto %s;", top_bool(), label($next)),
|
|
"*sp--;");
|
|
}
|
|
return $op->other;
|
|
}
|
|
|
|
sub pp_cond_expr {
|
|
my $op = shift;
|
|
my $false = $op->next;
|
|
unshift(@bblock_todo, $false);
|
|
reload_lexicals();
|
|
my $bool = pop_bool();
|
|
write_back_stack();
|
|
save_or_restore_lexical_state($$false);
|
|
runtime(sprintf("if (!$bool) goto %s;", label($false)));
|
|
return $op->other;
|
|
}
|
|
|
|
sub pp_padsv {
|
|
my $op = shift;
|
|
my $ix = $op->targ;
|
|
push(@stack, $pad[$ix]);
|
|
if ($op->flags & OPf_MOD) {
|
|
my $private = $op->private;
|
|
if ($private & OPpLVAL_INTRO) {
|
|
runtime("SAVECLEARSV(PL_curpad[$ix]);");
|
|
} elsif ($private & OPpDEREF) {
|
|
runtime(sprintf("vivify_ref(PL_curpad[%d], %d);",
|
|
$ix, $private & OPpDEREF));
|
|
$pad[$ix]->invalidate;
|
|
}
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_const {
|
|
my $op = shift;
|
|
my $sv = $op->sv;
|
|
my $obj;
|
|
# constant could be in the pad (under useithreads)
|
|
if ($$sv) {
|
|
$obj = $constobj{$$sv};
|
|
if (!defined($obj)) {
|
|
$obj = $constobj{$$sv} = new B::Stackobj::Const ($sv);
|
|
}
|
|
}
|
|
else {
|
|
$obj = $pad[$op->targ];
|
|
}
|
|
push(@stack, $obj);
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_nextstate {
|
|
my $op = shift;
|
|
$curcop->load($op);
|
|
@stack = ();
|
|
debug(sprintf("%s:%d\n", $op->file, $op->line)) if $debug_lineno;
|
|
runtime("TAINT_NOT;") unless $omit_taint;
|
|
runtime("sp = PL_stack_base + cxstack[cxstack_ix].blk_oldsp;");
|
|
if ($freetmps_each_bblock || $freetmps_each_loop) {
|
|
$need_freetmps = 1;
|
|
} else {
|
|
runtime("FREETMPS;");
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_dbstate {
|
|
my $op = shift;
|
|
$curcop->invalidate; # XXX?
|
|
return default_pp($op);
|
|
}
|
|
|
|
#default_pp will handle this:
|
|
#sub pp_bless { $curcop->write_back; default_pp(@_) }
|
|
#sub pp_repeat { $curcop->write_back; default_pp(@_) }
|
|
# The following subs need $curcop->write_back if we decide to support arybase:
|
|
# pp_pos, pp_substr, pp_index, pp_rindex, pp_aslice, pp_lslice, pp_splice
|
|
#sub pp_caller { $curcop->write_back; default_pp(@_) }
|
|
#sub pp_reset { $curcop->write_back; default_pp(@_) }
|
|
|
|
sub pp_rv2gv{
|
|
my $op =shift;
|
|
$curcop->write_back;
|
|
write_back_lexicals() unless $skip_lexicals{$ppname};
|
|
write_back_stack() unless $skip_stack{$ppname};
|
|
my $sym=doop($op);
|
|
if ($op->private & OPpDEREF) {
|
|
$init->add(sprintf("((UNOP *)$sym)->op_first = $sym;"));
|
|
$init->add(sprintf("((UNOP *)$sym)->op_type = %d;",
|
|
$op->first->type));
|
|
}
|
|
return $op->next;
|
|
}
|
|
sub pp_sort {
|
|
my $op = shift;
|
|
my $ppname = $op->ppaddr;
|
|
if ( $op->flags & OPf_SPECIAL && $op->flags & OPf_STACKED){
|
|
#this indicates the sort BLOCK Array case
|
|
#ugly surgery required.
|
|
my $root=$op->first->sibling->first;
|
|
my $start=$root->first;
|
|
$op->first->save;
|
|
$op->first->sibling->save;
|
|
$root->save;
|
|
my $sym=$start->save;
|
|
my $fakeop=cc_queue("pp_sort".$$op,$root,$start);
|
|
$init->add(sprintf("(%s)->op_next=%s;",$sym,$fakeop));
|
|
}
|
|
$curcop->write_back;
|
|
write_back_lexicals();
|
|
write_back_stack();
|
|
doop($op);
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_gv {
|
|
my $op = shift;
|
|
my $gvsym;
|
|
if ($Config{useithreads}) {
|
|
$gvsym = $pad[$op->padix]->as_sv;
|
|
}
|
|
else {
|
|
$gvsym = $op->gv->save;
|
|
}
|
|
write_back_stack();
|
|
runtime("XPUSHs((SV*)$gvsym);");
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_gvsv {
|
|
my $op = shift;
|
|
my $gvsym;
|
|
if ($Config{useithreads}) {
|
|
$gvsym = $pad[$op->padix]->as_sv;
|
|
}
|
|
else {
|
|
$gvsym = $op->gv->save;
|
|
}
|
|
write_back_stack();
|
|
if ($op->private & OPpLVAL_INTRO) {
|
|
runtime("XPUSHs(save_scalar($gvsym));");
|
|
} else {
|
|
runtime("XPUSHs(GvSV($gvsym));");
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_aelemfast {
|
|
my $op = shift;
|
|
my $gvsym;
|
|
if ($Config{useithreads}) {
|
|
$gvsym = $pad[$op->padix]->as_sv;
|
|
}
|
|
else {
|
|
$gvsym = $op->gv->save;
|
|
}
|
|
my $ix = $op->private;
|
|
my $flag = $op->flags & OPf_MOD;
|
|
write_back_stack();
|
|
runtime("svp = av_fetch(GvAV($gvsym), $ix, $flag);",
|
|
"PUSHs(svp ? *svp : &PL_sv_undef);");
|
|
return $op->next;
|
|
}
|
|
|
|
sub int_binop {
|
|
my ($op, $operator) = @_;
|
|
if ($op->flags & OPf_STACKED) {
|
|
my $right = pop_int();
|
|
if (@stack >= 1) {
|
|
my $left = top_int();
|
|
$stack[-1]->set_int(&$operator($left, $right));
|
|
} else {
|
|
runtime(sprintf("sv_setiv(TOPs, %s);",&$operator("TOPi", $right)));
|
|
}
|
|
} else {
|
|
my $targ = $pad[$op->targ];
|
|
my $right = new B::Pseudoreg ("IV", "riv");
|
|
my $left = new B::Pseudoreg ("IV", "liv");
|
|
runtime(sprintf("$$right = %s; $$left = %s;", pop_int(), pop_int));
|
|
$targ->set_int(&$operator($$left, $$right));
|
|
push(@stack, $targ);
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub INTS_CLOSED () { 0x1 }
|
|
sub INT_RESULT () { 0x2 }
|
|
sub NUMERIC_RESULT () { 0x4 }
|
|
|
|
sub numeric_binop {
|
|
my ($op, $operator, $flags) = @_;
|
|
my $force_int = 0;
|
|
$force_int ||= ($flags & INT_RESULT);
|
|
$force_int ||= ($flags & INTS_CLOSED && @stack >= 2
|
|
&& valid_int($stack[-2]) && valid_int($stack[-1]));
|
|
if ($op->flags & OPf_STACKED) {
|
|
my $right = pop_numeric();
|
|
if (@stack >= 1) {
|
|
my $left = top_numeric();
|
|
if ($force_int) {
|
|
$stack[-1]->set_int(&$operator($left, $right));
|
|
} else {
|
|
$stack[-1]->set_numeric(&$operator($left, $right));
|
|
}
|
|
} else {
|
|
if ($force_int) {
|
|
my $rightruntime = new B::Pseudoreg ("IV", "riv");
|
|
runtime(sprintf("$$rightruntime = %s;",$right));
|
|
runtime(sprintf("sv_setiv(TOPs, %s);",
|
|
&$operator("TOPi", $$rightruntime)));
|
|
} else {
|
|
my $rightruntime = new B::Pseudoreg ("double", "rnv");
|
|
runtime(sprintf("$$rightruntime = %s;",$right));
|
|
runtime(sprintf("sv_setnv(TOPs, %s);",
|
|
&$operator("TOPn",$$rightruntime)));
|
|
}
|
|
}
|
|
} else {
|
|
my $targ = $pad[$op->targ];
|
|
$force_int ||= ($targ->{type} == T_INT);
|
|
if ($force_int) {
|
|
my $right = new B::Pseudoreg ("IV", "riv");
|
|
my $left = new B::Pseudoreg ("IV", "liv");
|
|
runtime(sprintf("$$right = %s; $$left = %s;",
|
|
pop_numeric(), pop_numeric));
|
|
$targ->set_int(&$operator($$left, $$right));
|
|
} else {
|
|
my $right = new B::Pseudoreg ("double", "rnv");
|
|
my $left = new B::Pseudoreg ("double", "lnv");
|
|
runtime(sprintf("$$right = %s; $$left = %s;",
|
|
pop_numeric(), pop_numeric));
|
|
$targ->set_numeric(&$operator($$left, $$right));
|
|
}
|
|
push(@stack, $targ);
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_ncmp {
|
|
my ($op) = @_;
|
|
if ($op->flags & OPf_STACKED) {
|
|
my $right = pop_numeric();
|
|
if (@stack >= 1) {
|
|
my $left = top_numeric();
|
|
runtime sprintf("if (%s > %s){",$left,$right);
|
|
$stack[-1]->set_int(1);
|
|
$stack[-1]->write_back();
|
|
runtime sprintf("}else if (%s < %s ) {",$left,$right);
|
|
$stack[-1]->set_int(-1);
|
|
$stack[-1]->write_back();
|
|
runtime sprintf("}else if (%s == %s) {",$left,$right);
|
|
$stack[-1]->set_int(0);
|
|
$stack[-1]->write_back();
|
|
runtime sprintf("}else {");
|
|
$stack[-1]->set_sv("&PL_sv_undef");
|
|
runtime "}";
|
|
} else {
|
|
my $rightruntime = new B::Pseudoreg ("double", "rnv");
|
|
runtime(sprintf("$$rightruntime = %s;",$right));
|
|
runtime sprintf(qq/if ("TOPn" > %s){/,$rightruntime);
|
|
runtime sprintf("sv_setiv(TOPs,1);");
|
|
runtime sprintf(qq/}else if ( "TOPn" < %s ) {/,$$rightruntime);
|
|
runtime sprintf("sv_setiv(TOPs,-1);");
|
|
runtime sprintf(qq/} else if ("TOPn" == %s) {/,$$rightruntime);
|
|
runtime sprintf("sv_setiv(TOPs,0);");
|
|
runtime sprintf(qq/}else {/);
|
|
runtime sprintf("sv_setiv(TOPs,&PL_sv_undef;");
|
|
runtime "}";
|
|
}
|
|
} else {
|
|
my $targ = $pad[$op->targ];
|
|
my $right = new B::Pseudoreg ("double", "rnv");
|
|
my $left = new B::Pseudoreg ("double", "lnv");
|
|
runtime(sprintf("$$right = %s; $$left = %s;",
|
|
pop_numeric(), pop_numeric));
|
|
runtime sprintf("if (%s > %s){",$$left,$$right);
|
|
$targ->set_int(1);
|
|
$targ->write_back();
|
|
runtime sprintf("}else if (%s < %s ) {",$$left,$$right);
|
|
$targ->set_int(-1);
|
|
$targ->write_back();
|
|
runtime sprintf("}else if (%s == %s) {",$$left,$$right);
|
|
$targ->set_int(0);
|
|
$targ->write_back();
|
|
runtime sprintf("}else {");
|
|
$targ->set_sv("&PL_sv_undef");
|
|
runtime "}";
|
|
push(@stack, $targ);
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub sv_binop {
|
|
my ($op, $operator, $flags) = @_;
|
|
if ($op->flags & OPf_STACKED) {
|
|
my $right = pop_sv();
|
|
if (@stack >= 1) {
|
|
my $left = top_sv();
|
|
if ($flags & INT_RESULT) {
|
|
$stack[-1]->set_int(&$operator($left, $right));
|
|
} elsif ($flags & NUMERIC_RESULT) {
|
|
$stack[-1]->set_numeric(&$operator($left, $right));
|
|
} else {
|
|
# XXX Does this work?
|
|
runtime(sprintf("sv_setsv($left, %s);",
|
|
&$operator($left, $right)));
|
|
$stack[-1]->invalidate;
|
|
}
|
|
} else {
|
|
my $f;
|
|
if ($flags & INT_RESULT) {
|
|
$f = "sv_setiv";
|
|
} elsif ($flags & NUMERIC_RESULT) {
|
|
$f = "sv_setnv";
|
|
} else {
|
|
$f = "sv_setsv";
|
|
}
|
|
runtime(sprintf("%s(TOPs, %s);", $f, &$operator("TOPs", $right)));
|
|
}
|
|
} else {
|
|
my $targ = $pad[$op->targ];
|
|
runtime(sprintf("right = %s; left = %s;", pop_sv(), pop_sv));
|
|
if ($flags & INT_RESULT) {
|
|
$targ->set_int(&$operator("left", "right"));
|
|
} elsif ($flags & NUMERIC_RESULT) {
|
|
$targ->set_numeric(&$operator("left", "right"));
|
|
} else {
|
|
# XXX Does this work?
|
|
runtime(sprintf("sv_setsv(%s, %s);",
|
|
$targ->as_sv, &$operator("left", "right")));
|
|
$targ->invalidate;
|
|
}
|
|
push(@stack, $targ);
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub bool_int_binop {
|
|
my ($op, $operator) = @_;
|
|
my $right = new B::Pseudoreg ("IV", "riv");
|
|
my $left = new B::Pseudoreg ("IV", "liv");
|
|
runtime(sprintf("$$right = %s; $$left = %s;", pop_int(), pop_int()));
|
|
my $bool = new B::Stackobj::Bool (new B::Pseudoreg ("int", "b"));
|
|
$bool->set_int(&$operator($$left, $$right));
|
|
push(@stack, $bool);
|
|
return $op->next;
|
|
}
|
|
|
|
sub bool_numeric_binop {
|
|
my ($op, $operator) = @_;
|
|
my $right = new B::Pseudoreg ("double", "rnv");
|
|
my $left = new B::Pseudoreg ("double", "lnv");
|
|
runtime(sprintf("$$right = %s; $$left = %s;",
|
|
pop_numeric(), pop_numeric()));
|
|
my $bool = new B::Stackobj::Bool (new B::Pseudoreg ("int", "b"));
|
|
$bool->set_numeric(&$operator($$left, $$right));
|
|
push(@stack, $bool);
|
|
return $op->next;
|
|
}
|
|
|
|
sub bool_sv_binop {
|
|
my ($op, $operator) = @_;
|
|
runtime(sprintf("right = %s; left = %s;", pop_sv(), pop_sv()));
|
|
my $bool = new B::Stackobj::Bool (new B::Pseudoreg ("int", "b"));
|
|
$bool->set_numeric(&$operator("left", "right"));
|
|
push(@stack, $bool);
|
|
return $op->next;
|
|
}
|
|
|
|
sub infix_op {
|
|
my $opname = shift;
|
|
return sub { "$_[0] $opname $_[1]" }
|
|
}
|
|
|
|
sub prefix_op {
|
|
my $opname = shift;
|
|
return sub { sprintf("%s(%s)", $opname, join(", ", @_)) }
|
|
}
|
|
|
|
BEGIN {
|
|
my $plus_op = infix_op("+");
|
|
my $minus_op = infix_op("-");
|
|
my $multiply_op = infix_op("*");
|
|
my $divide_op = infix_op("/");
|
|
my $modulo_op = infix_op("%");
|
|
my $lshift_op = infix_op("<<");
|
|
my $rshift_op = infix_op(">>");
|
|
my $scmp_op = prefix_op("sv_cmp");
|
|
my $seq_op = prefix_op("sv_eq");
|
|
my $sne_op = prefix_op("!sv_eq");
|
|
my $slt_op = sub { "sv_cmp($_[0], $_[1]) < 0" };
|
|
my $sgt_op = sub { "sv_cmp($_[0], $_[1]) > 0" };
|
|
my $sle_op = sub { "sv_cmp($_[0], $_[1]) <= 0" };
|
|
my $sge_op = sub { "sv_cmp($_[0], $_[1]) >= 0" };
|
|
my $eq_op = infix_op("==");
|
|
my $ne_op = infix_op("!=");
|
|
my $lt_op = infix_op("<");
|
|
my $gt_op = infix_op(">");
|
|
my $le_op = infix_op("<=");
|
|
my $ge_op = infix_op(">=");
|
|
|
|
#
|
|
# XXX The standard perl PP code has extra handling for
|
|
# some special case arguments of these operators.
|
|
#
|
|
sub pp_add { numeric_binop($_[0], $plus_op) }
|
|
sub pp_subtract { numeric_binop($_[0], $minus_op) }
|
|
sub pp_multiply { numeric_binop($_[0], $multiply_op) }
|
|
sub pp_divide { numeric_binop($_[0], $divide_op) }
|
|
sub pp_modulo { int_binop($_[0], $modulo_op) } # differs from perl's
|
|
|
|
sub pp_left_shift { int_binop($_[0], $lshift_op) }
|
|
sub pp_right_shift { int_binop($_[0], $rshift_op) }
|
|
sub pp_i_add { int_binop($_[0], $plus_op) }
|
|
sub pp_i_subtract { int_binop($_[0], $minus_op) }
|
|
sub pp_i_multiply { int_binop($_[0], $multiply_op) }
|
|
sub pp_i_divide { int_binop($_[0], $divide_op) }
|
|
sub pp_i_modulo { int_binop($_[0], $modulo_op) }
|
|
|
|
sub pp_eq { bool_numeric_binop($_[0], $eq_op) }
|
|
sub pp_ne { bool_numeric_binop($_[0], $ne_op) }
|
|
sub pp_lt { bool_numeric_binop($_[0], $lt_op) }
|
|
sub pp_gt { bool_numeric_binop($_[0], $gt_op) }
|
|
sub pp_le { bool_numeric_binop($_[0], $le_op) }
|
|
sub pp_ge { bool_numeric_binop($_[0], $ge_op) }
|
|
|
|
sub pp_i_eq { bool_int_binop($_[0], $eq_op) }
|
|
sub pp_i_ne { bool_int_binop($_[0], $ne_op) }
|
|
sub pp_i_lt { bool_int_binop($_[0], $lt_op) }
|
|
sub pp_i_gt { bool_int_binop($_[0], $gt_op) }
|
|
sub pp_i_le { bool_int_binop($_[0], $le_op) }
|
|
sub pp_i_ge { bool_int_binop($_[0], $ge_op) }
|
|
|
|
sub pp_scmp { sv_binop($_[0], $scmp_op, INT_RESULT) }
|
|
sub pp_slt { bool_sv_binop($_[0], $slt_op) }
|
|
sub pp_sgt { bool_sv_binop($_[0], $sgt_op) }
|
|
sub pp_sle { bool_sv_binop($_[0], $sle_op) }
|
|
sub pp_sge { bool_sv_binop($_[0], $sge_op) }
|
|
sub pp_seq { bool_sv_binop($_[0], $seq_op) }
|
|
sub pp_sne { bool_sv_binop($_[0], $sne_op) }
|
|
}
|
|
|
|
|
|
sub pp_sassign {
|
|
my $op = shift;
|
|
my $backwards = $op->private & OPpASSIGN_BACKWARDS;
|
|
my ($dst, $src);
|
|
if (@stack >= 2) {
|
|
$dst = pop @stack;
|
|
$src = pop @stack;
|
|
($src, $dst) = ($dst, $src) if $backwards;
|
|
my $type = $src->{type};
|
|
if ($type == T_INT) {
|
|
$dst->set_int($src->as_int,$src->{flags} & VALID_UNSIGNED);
|
|
} elsif ($type == T_DOUBLE) {
|
|
$dst->set_numeric($src->as_numeric);
|
|
} else {
|
|
$dst->set_sv($src->as_sv);
|
|
}
|
|
push(@stack, $dst);
|
|
} elsif (@stack == 1) {
|
|
if ($backwards) {
|
|
my $src = pop @stack;
|
|
my $type = $src->{type};
|
|
runtime("if (PL_tainting && PL_tainted) TAINT_NOT;");
|
|
if ($type == T_INT) {
|
|
if ($src->{flags} & VALID_UNSIGNED){
|
|
runtime sprintf("sv_setuv(TOPs, %s);", $src->as_int);
|
|
}else{
|
|
runtime sprintf("sv_setiv(TOPs, %s);", $src->as_int);
|
|
}
|
|
} elsif ($type == T_DOUBLE) {
|
|
runtime sprintf("sv_setnv(TOPs, %s);", $src->as_double);
|
|
} else {
|
|
runtime sprintf("sv_setsv(TOPs, %s);", $src->as_sv);
|
|
}
|
|
runtime("SvSETMAGIC(TOPs);");
|
|
} else {
|
|
my $dst = $stack[-1];
|
|
my $type = $dst->{type};
|
|
runtime("sv = POPs;");
|
|
runtime("MAYBE_TAINT_SASSIGN_SRC(sv);");
|
|
if ($type == T_INT) {
|
|
$dst->set_int("SvIV(sv)");
|
|
} elsif ($type == T_DOUBLE) {
|
|
$dst->set_double("SvNV(sv)");
|
|
} else {
|
|
runtime("SvSetMagicSV($dst->{sv}, sv);");
|
|
$dst->invalidate;
|
|
}
|
|
}
|
|
} else {
|
|
if ($backwards) {
|
|
runtime("src = POPs; dst = TOPs;");
|
|
} else {
|
|
runtime("dst = POPs; src = TOPs;");
|
|
}
|
|
runtime("MAYBE_TAINT_SASSIGN_SRC(src);",
|
|
"SvSetSV(dst, src);",
|
|
"SvSETMAGIC(dst);",
|
|
"SETs(dst);");
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_preinc {
|
|
my $op = shift;
|
|
if (@stack >= 1) {
|
|
my $obj = $stack[-1];
|
|
my $type = $obj->{type};
|
|
if ($type == T_INT || $type == T_DOUBLE) {
|
|
$obj->set_int($obj->as_int . " + 1");
|
|
} else {
|
|
runtime sprintf("PP_PREINC(%s);", $obj->as_sv);
|
|
$obj->invalidate();
|
|
}
|
|
} else {
|
|
runtime sprintf("PP_PREINC(TOPs);");
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
|
|
sub pp_pushmark {
|
|
my $op = shift;
|
|
write_back_stack();
|
|
runtime("PUSHMARK(sp);");
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_list {
|
|
my $op = shift;
|
|
write_back_stack();
|
|
my $gimme = gimme($op);
|
|
if ($gimme == G_ARRAY) { # sic
|
|
runtime("POPMARK;"); # need this even though not a "full" pp_list
|
|
} else {
|
|
runtime("PP_LIST($gimme);");
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_entersub {
|
|
my $op = shift;
|
|
$curcop->write_back;
|
|
write_back_lexicals(REGISTER|TEMPORARY);
|
|
write_back_stack();
|
|
my $sym = doop($op);
|
|
runtime("while (PL_op != ($sym)->op_next && PL_op != (OP*)0 ){");
|
|
runtime("PL_op = (*PL_op->op_ppaddr)(aTHX);");
|
|
runtime("SPAGAIN;}");
|
|
$know_op = 0;
|
|
invalidate_lexicals(REGISTER|TEMPORARY);
|
|
return $op->next;
|
|
}
|
|
sub pp_formline {
|
|
my $op = shift;
|
|
my $ppname = $op->ppaddr;
|
|
write_back_lexicals() unless $skip_lexicals{$ppname};
|
|
write_back_stack() unless $skip_stack{$ppname};
|
|
my $sym=doop($op);
|
|
# See comment in pp_grepwhile to see why!
|
|
$init->add("((LISTOP*)$sym)->op_first = $sym;");
|
|
runtime("if (PL_op == ((LISTOP*)($sym))->op_first){");
|
|
save_or_restore_lexical_state(${$op->first});
|
|
runtime( sprintf("goto %s;",label($op->first)));
|
|
runtime("}");
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_goto{
|
|
|
|
my $op = shift;
|
|
my $ppname = $op->ppaddr;
|
|
write_back_lexicals() unless $skip_lexicals{$ppname};
|
|
write_back_stack() unless $skip_stack{$ppname};
|
|
my $sym=doop($op);
|
|
runtime("if (PL_op != ($sym)->op_next && PL_op != (OP*)0){return PL_op;}");
|
|
invalidate_lexicals() unless $skip_invalidate{$ppname};
|
|
return $op->next;
|
|
}
|
|
sub pp_enterwrite {
|
|
my $op = shift;
|
|
pp_entersub($op);
|
|
}
|
|
sub pp_leavesub{
|
|
my $op = shift;
|
|
write_back_lexicals() unless $skip_lexicals{$ppname};
|
|
write_back_stack() unless $skip_stack{$ppname};
|
|
runtime("if (PL_curstackinfo->si_type == PERLSI_SORT){");
|
|
runtime("\tPUTBACK;return 0;");
|
|
runtime("}");
|
|
doop($op);
|
|
return $op->next;
|
|
}
|
|
sub pp_leavewrite {
|
|
my $op = shift;
|
|
write_back_lexicals(REGISTER|TEMPORARY);
|
|
write_back_stack();
|
|
my $sym = doop($op);
|
|
# XXX Is this the right way to distinguish between it returning
|
|
# CvSTART(cv) (via doform) and pop_return()?
|
|
#runtime("if (PL_op) PL_op = (*PL_op->op_ppaddr)(aTHX);");
|
|
runtime("SPAGAIN;");
|
|
$know_op = 0;
|
|
invalidate_lexicals(REGISTER|TEMPORARY);
|
|
return $op->next;
|
|
}
|
|
|
|
sub doeval {
|
|
my $op = shift;
|
|
$curcop->write_back;
|
|
write_back_lexicals(REGISTER|TEMPORARY);
|
|
write_back_stack();
|
|
my $sym = loadop($op);
|
|
my $ppaddr = $op->ppaddr;
|
|
#runtime(qq/printf("$ppaddr type eval\n");/);
|
|
runtime("PP_EVAL($ppaddr, ($sym)->op_next);");
|
|
$know_op = 1;
|
|
invalidate_lexicals(REGISTER|TEMPORARY);
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_entereval { doeval(@_) }
|
|
sub pp_dofile { doeval(@_) }
|
|
|
|
#pp_require is protected by pp_entertry, so no protection for it.
|
|
sub pp_require {
|
|
my $op = shift;
|
|
$curcop->write_back;
|
|
write_back_lexicals(REGISTER|TEMPORARY);
|
|
write_back_stack();
|
|
my $sym = doop($op);
|
|
runtime("while (PL_op != ($sym)->op_next && PL_op != (OP*)0 ){");
|
|
runtime("PL_op = (*PL_op->op_ppaddr)(ARGS);");
|
|
runtime("SPAGAIN;}");
|
|
$know_op = 1;
|
|
invalidate_lexicals(REGISTER|TEMPORARY);
|
|
return $op->next;
|
|
}
|
|
|
|
|
|
sub pp_entertry {
|
|
my $op = shift;
|
|
$curcop->write_back;
|
|
write_back_lexicals(REGISTER|TEMPORARY);
|
|
write_back_stack();
|
|
my $sym = doop($op);
|
|
my $jmpbuf = sprintf("jmpbuf%d", $jmpbuf_ix++);
|
|
declare("JMPENV", $jmpbuf);
|
|
runtime(sprintf("PP_ENTERTRY(%s,%s);", $jmpbuf, label($op->other->next)));
|
|
invalidate_lexicals(REGISTER|TEMPORARY);
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_leavetry{
|
|
my $op=shift;
|
|
default_pp($op);
|
|
runtime("PP_LEAVETRY;");
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_grepstart {
|
|
my $op = shift;
|
|
if ($need_freetmps && $freetmps_each_loop) {
|
|
runtime("FREETMPS;"); # otherwise the grepwhile loop messes things up
|
|
$need_freetmps = 0;
|
|
}
|
|
write_back_stack();
|
|
my $sym= doop($op);
|
|
my $next=$op->next;
|
|
$next->save;
|
|
my $nexttonext=$next->next;
|
|
$nexttonext->save;
|
|
save_or_restore_lexical_state($$nexttonext);
|
|
runtime(sprintf("if (PL_op == (($sym)->op_next)->op_next) goto %s;",
|
|
label($nexttonext)));
|
|
return $op->next->other;
|
|
}
|
|
|
|
sub pp_mapstart {
|
|
my $op = shift;
|
|
if ($need_freetmps && $freetmps_each_loop) {
|
|
runtime("FREETMPS;"); # otherwise the mapwhile loop messes things up
|
|
$need_freetmps = 0;
|
|
}
|
|
write_back_stack();
|
|
# pp_mapstart can return either op_next->op_next or op_next->op_other and
|
|
# we need to be able to distinguish the two at runtime.
|
|
my $sym= doop($op);
|
|
my $next=$op->next;
|
|
$next->save;
|
|
my $nexttonext=$next->next;
|
|
$nexttonext->save;
|
|
save_or_restore_lexical_state($$nexttonext);
|
|
runtime(sprintf("if (PL_op == (($sym)->op_next)->op_next) goto %s;",
|
|
label($nexttonext)));
|
|
return $op->next->other;
|
|
}
|
|
|
|
sub pp_grepwhile {
|
|
my $op = shift;
|
|
my $next = $op->next;
|
|
unshift(@bblock_todo, $next);
|
|
write_back_lexicals();
|
|
write_back_stack();
|
|
my $sym = doop($op);
|
|
# pp_grepwhile can return either op_next or op_other and we need to
|
|
# be able to distinguish the two at runtime. Since it's possible for
|
|
# both ops to be "inlined", the fields could both be zero. To get
|
|
# around that, we hack op_next to be our own op (purely because we
|
|
# know it's a non-NULL pointer and can't be the same as op_other).
|
|
$init->add("((LOGOP*)$sym)->op_next = $sym;");
|
|
save_or_restore_lexical_state($$next);
|
|
runtime(sprintf("if (PL_op == ($sym)->op_next) goto %s;", label($next)));
|
|
$know_op = 0;
|
|
return $op->other;
|
|
}
|
|
|
|
sub pp_mapwhile {
|
|
pp_grepwhile(@_);
|
|
}
|
|
|
|
sub pp_return {
|
|
my $op = shift;
|
|
write_back_lexicals(REGISTER|TEMPORARY);
|
|
write_back_stack();
|
|
doop($op);
|
|
runtime("PUTBACK;", "return PL_op;");
|
|
$know_op = 0;
|
|
return $op->next;
|
|
}
|
|
|
|
sub nyi {
|
|
my $op = shift;
|
|
warn sprintf("%s not yet implemented properly\n", $op->ppaddr);
|
|
return default_pp($op);
|
|
}
|
|
|
|
sub pp_range {
|
|
my $op = shift;
|
|
my $flags = $op->flags;
|
|
if (!($flags & OPf_WANT)) {
|
|
error("context of range unknown at compile-time");
|
|
}
|
|
write_back_lexicals();
|
|
write_back_stack();
|
|
unless (($flags & OPf_WANT)== OPf_WANT_LIST) {
|
|
# We need to save our UNOP structure since pp_flop uses
|
|
# it to find and adjust out targ. We don't need it ourselves.
|
|
$op->save;
|
|
save_or_restore_lexical_state(${$op->other});
|
|
runtime sprintf("if (SvTRUE(PL_curpad[%d])) goto %s;",
|
|
$op->targ, label($op->other));
|
|
unshift(@bblock_todo, $op->other);
|
|
}
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_flip {
|
|
my $op = shift;
|
|
my $flags = $op->flags;
|
|
if (!($flags & OPf_WANT)) {
|
|
error("context of flip unknown at compile-time");
|
|
}
|
|
if (($flags & OPf_WANT)==OPf_WANT_LIST) {
|
|
return $op->first->other;
|
|
}
|
|
write_back_lexicals();
|
|
write_back_stack();
|
|
# We need to save our UNOP structure since pp_flop uses
|
|
# it to find and adjust out targ. We don't need it ourselves.
|
|
$op->save;
|
|
my $ix = $op->targ;
|
|
my $rangeix = $op->first->targ;
|
|
runtime(($op->private & OPpFLIP_LINENUM) ?
|
|
"if (PL_last_in_gv && SvIV(TOPs) == IoLINES(GvIOp(PL_last_in_gv))) {"
|
|
: "if (SvTRUE(TOPs)) {");
|
|
runtime("\tsv_setiv(PL_curpad[$rangeix], 1);");
|
|
if ($op->flags & OPf_SPECIAL) {
|
|
runtime("sv_setiv(PL_curpad[$ix], 1);");
|
|
} else {
|
|
save_or_restore_lexical_state(${$op->first->other});
|
|
runtime("\tsv_setiv(PL_curpad[$ix], 0);",
|
|
"\tsp--;",
|
|
sprintf("\tgoto %s;", label($op->first->other)));
|
|
}
|
|
runtime("}",
|
|
qq{sv_setpv(PL_curpad[$ix], "");},
|
|
"SETs(PL_curpad[$ix]);");
|
|
$know_op = 0;
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_flop {
|
|
my $op = shift;
|
|
default_pp($op);
|
|
$know_op = 0;
|
|
return $op->next;
|
|
}
|
|
|
|
sub enterloop {
|
|
my $op = shift;
|
|
my $nextop = $op->nextop;
|
|
my $lastop = $op->lastop;
|
|
my $redoop = $op->redoop;
|
|
$curcop->write_back;
|
|
debug "enterloop: pushing on cxstack" if $debug_cxstack;
|
|
push(@cxstack, {
|
|
type => CXt_LOOP,
|
|
op => $op,
|
|
"label" => $curcop->[0]->label,
|
|
nextop => $nextop,
|
|
lastop => $lastop,
|
|
redoop => $redoop
|
|
});
|
|
$nextop->save;
|
|
$lastop->save;
|
|
$redoop->save;
|
|
return default_pp($op);
|
|
}
|
|
|
|
sub pp_enterloop { enterloop(@_) }
|
|
sub pp_enteriter { enterloop(@_) }
|
|
|
|
sub pp_leaveloop {
|
|
my $op = shift;
|
|
if (!@cxstack) {
|
|
die "panic: leaveloop";
|
|
}
|
|
debug "leaveloop: popping from cxstack" if $debug_cxstack;
|
|
pop(@cxstack);
|
|
return default_pp($op);
|
|
}
|
|
|
|
sub pp_next {
|
|
my $op = shift;
|
|
my $cxix;
|
|
if ($op->flags & OPf_SPECIAL) {
|
|
$cxix = dopoptoloop();
|
|
if ($cxix < 0) {
|
|
error('"next" used outside loop');
|
|
return $op->next; # ignore the op
|
|
}
|
|
} else {
|
|
$cxix = dopoptolabel($op->pv);
|
|
if ($cxix < 0) {
|
|
error('Label not found at compile time for "next %s"', $op->pv);
|
|
return $op->next; # ignore the op
|
|
}
|
|
}
|
|
default_pp($op);
|
|
my $nextop = $cxstack[$cxix]->{nextop};
|
|
push(@bblock_todo, $nextop);
|
|
save_or_restore_lexical_state($$nextop);
|
|
runtime(sprintf("goto %s;", label($nextop)));
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_redo {
|
|
my $op = shift;
|
|
my $cxix;
|
|
if ($op->flags & OPf_SPECIAL) {
|
|
$cxix = dopoptoloop();
|
|
if ($cxix < 0) {
|
|
error('"redo" used outside loop');
|
|
return $op->next; # ignore the op
|
|
}
|
|
} else {
|
|
$cxix = dopoptolabel($op->pv);
|
|
if ($cxix < 0) {
|
|
error('Label not found at compile time for "redo %s"', $op->pv);
|
|
return $op->next; # ignore the op
|
|
}
|
|
}
|
|
default_pp($op);
|
|
my $redoop = $cxstack[$cxix]->{redoop};
|
|
push(@bblock_todo, $redoop);
|
|
save_or_restore_lexical_state($$redoop);
|
|
runtime(sprintf("goto %s;", label($redoop)));
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_last {
|
|
my $op = shift;
|
|
my $cxix;
|
|
if ($op->flags & OPf_SPECIAL) {
|
|
$cxix = dopoptoloop();
|
|
if ($cxix < 0) {
|
|
error('"last" used outside loop');
|
|
return $op->next; # ignore the op
|
|
}
|
|
} else {
|
|
$cxix = dopoptolabel($op->pv);
|
|
if ($cxix < 0) {
|
|
error('Label not found at compile time for "last %s"', $op->pv);
|
|
return $op->next; # ignore the op
|
|
}
|
|
# XXX Add support for "last" to leave non-loop blocks
|
|
if ($cxstack[$cxix]->{type} != CXt_LOOP) {
|
|
error('Use of "last" for non-loop blocks is not yet implemented');
|
|
return $op->next; # ignore the op
|
|
}
|
|
}
|
|
default_pp($op);
|
|
my $lastop = $cxstack[$cxix]->{lastop}->next;
|
|
push(@bblock_todo, $lastop);
|
|
save_or_restore_lexical_state($$lastop);
|
|
runtime(sprintf("goto %s;", label($lastop)));
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_subst {
|
|
my $op = shift;
|
|
write_back_lexicals();
|
|
write_back_stack();
|
|
my $sym = doop($op);
|
|
my $replroot = $op->pmreplroot;
|
|
if ($$replroot) {
|
|
save_or_restore_lexical_state($$replroot);
|
|
runtime sprintf("if (PL_op == ((PMOP*)(%s))->op_pmreplroot) goto %s;",
|
|
$sym, label($replroot));
|
|
$op->pmreplstart->save;
|
|
push(@bblock_todo, $replroot);
|
|
}
|
|
invalidate_lexicals();
|
|
return $op->next;
|
|
}
|
|
|
|
sub pp_substcont {
|
|
my $op = shift;
|
|
write_back_lexicals();
|
|
write_back_stack();
|
|
doop($op);
|
|
my $pmop = $op->other;
|
|
# warn sprintf("substcont: op = %s, pmop = %s\n",
|
|
# peekop($op), peekop($pmop));#debug
|
|
# my $pmopsym = objsym($pmop);
|
|
my $pmopsym = $pmop->save; # XXX can this recurse?
|
|
# warn "pmopsym = $pmopsym\n";#debug
|
|
save_or_restore_lexical_state(${$pmop->pmreplstart});
|
|
runtime sprintf("if (PL_op == ((PMOP*)(%s))->op_pmreplstart) goto %s;",
|
|
$pmopsym, label($pmop->pmreplstart));
|
|
invalidate_lexicals();
|
|
return $pmop->next;
|
|
}
|
|
|
|
sub default_pp {
|
|
my $op = shift;
|
|
my $ppname = "pp_" . $op->name;
|
|
if ($curcop and $need_curcop{$ppname}){
|
|
$curcop->write_back;
|
|
}
|
|
write_back_lexicals() unless $skip_lexicals{$ppname};
|
|
write_back_stack() unless $skip_stack{$ppname};
|
|
doop($op);
|
|
# XXX If the only way that ops can write to a TEMPORARY lexical is
|
|
# when it's named in $op->targ then we could call
|
|
# invalidate_lexicals(TEMPORARY) and avoid having to write back all
|
|
# the temporaries. For now, we'll play it safe and write back the lot.
|
|
invalidate_lexicals() unless $skip_invalidate{$ppname};
|
|
return $op->next;
|
|
}
|
|
|
|
sub compile_op {
|
|
my $op = shift;
|
|
my $ppname = "pp_" . $op->name;
|
|
if (exists $ignore_op{$ppname}) {
|
|
return $op->next;
|
|
}
|
|
debug peek_stack() if $debug_stack;
|
|
if ($debug_op) {
|
|
debug sprintf("%s [%s]\n",
|
|
peekop($op),
|
|
$op->flags & OPf_STACKED ? "OPf_STACKED" : $op->targ);
|
|
}
|
|
no strict 'refs';
|
|
if (defined(&$ppname)) {
|
|
$know_op = 0;
|
|
return &$ppname($op);
|
|
} else {
|
|
return default_pp($op);
|
|
}
|
|
}
|
|
|
|
sub compile_bblock {
|
|
my $op = shift;
|
|
#warn "compile_bblock: ", peekop($op), "\n"; # debug
|
|
save_or_restore_lexical_state($$op);
|
|
write_label($op);
|
|
$know_op = 0;
|
|
do {
|
|
$op = compile_op($op);
|
|
} while (defined($op) && $$op && !exists($leaders->{$$op}));
|
|
write_back_stack(); # boo hoo: big loss
|
|
reload_lexicals();
|
|
return $op;
|
|
}
|
|
|
|
sub cc {
|
|
my ($name, $root, $start, @padlist) = @_;
|
|
my $op;
|
|
if($done{$$start}){
|
|
#warn "repeat=>".ref($start)."$name,\n";#debug
|
|
$decl->add(sprintf("#define $name %s",$done{$$start}));
|
|
return;
|
|
}
|
|
init_pp($name);
|
|
load_pad(@padlist);
|
|
%lexstate=();
|
|
B::Pseudoreg->new_scope;
|
|
@cxstack = ();
|
|
if ($debug_timings) {
|
|
warn sprintf("Basic block analysis at %s\n", timing_info);
|
|
}
|
|
$leaders = find_leaders($root, $start);
|
|
my @leaders= keys %$leaders;
|
|
if ($#leaders > -1) {
|
|
@bblock_todo = ($start, values %$leaders) ;
|
|
} else{
|
|
runtime("return PL_op?PL_op->op_next:0;");
|
|
}
|
|
if ($debug_timings) {
|
|
warn sprintf("Compilation at %s\n", timing_info);
|
|
}
|
|
while (@bblock_todo) {
|
|
$op = shift @bblock_todo;
|
|
#warn sprintf("Considering basic block %s\n", peekop($op)); # debug
|
|
next if !defined($op) || !$$op || $done{$$op};
|
|
#warn "...compiling it\n"; # debug
|
|
do {
|
|
$done{$$op} = $name;
|
|
$op = compile_bblock($op);
|
|
if ($need_freetmps && $freetmps_each_bblock) {
|
|
runtime("FREETMPS;");
|
|
$need_freetmps = 0;
|
|
}
|
|
} while defined($op) && $$op && !$done{$$op};
|
|
if ($need_freetmps && $freetmps_each_loop) {
|
|
runtime("FREETMPS;");
|
|
$need_freetmps = 0;
|
|
}
|
|
if (!$$op) {
|
|
runtime("PUTBACK;","return PL_op;");
|
|
} elsif ($done{$$op}) {
|
|
save_or_restore_lexical_state($$op);
|
|
runtime(sprintf("goto %s;", label($op)));
|
|
}
|
|
}
|
|
if ($debug_timings) {
|
|
warn sprintf("Saving runtime at %s\n", timing_info);
|
|
}
|
|
declare_pad(@padlist) ;
|
|
save_runtime();
|
|
}
|
|
|
|
sub cc_recurse {
|
|
my $ccinfo;
|
|
my $start;
|
|
$start = cc_queue(@_) if @_;
|
|
while ($ccinfo = shift @cc_todo) {
|
|
cc(@$ccinfo);
|
|
}
|
|
return $start;
|
|
}
|
|
|
|
sub cc_obj {
|
|
my ($name, $cvref) = @_;
|
|
my $cv = svref_2object($cvref);
|
|
my @padlist = $cv->PADLIST->ARRAY;
|
|
my $curpad_sym = $padlist[1]->save;
|
|
cc_recurse($name, $cv->ROOT, $cv->START, @padlist);
|
|
}
|
|
|
|
sub cc_main {
|
|
my @comppadlist = comppadlist->ARRAY;
|
|
my $curpad_nam = $comppadlist[0]->save;
|
|
my $curpad_sym = $comppadlist[1]->save;
|
|
my $init_av = init_av->save;
|
|
my $start = cc_recurse("pp_main", main_root, main_start, @comppadlist);
|
|
# Do save_unused_subs before saving inc_hv
|
|
save_unused_subs();
|
|
cc_recurse();
|
|
|
|
my $inc_hv = svref_2object(\%INC)->save;
|
|
my $inc_av = svref_2object(\@INC)->save;
|
|
my $amagic_generate= amagic_generation;
|
|
return if $errors;
|
|
if (!defined($module)) {
|
|
$init->add(sprintf("PL_main_root = s\\_%x;", ${main_root()}),
|
|
"PL_main_start = $start;",
|
|
"PL_curpad = AvARRAY($curpad_sym);",
|
|
"PL_initav = (AV *) $init_av;",
|
|
"GvHV(PL_incgv) = $inc_hv;",
|
|
"GvAV(PL_incgv) = $inc_av;",
|
|
"av_store(CvPADLIST(PL_main_cv),0,SvREFCNT_inc($curpad_nam));",
|
|
"av_store(CvPADLIST(PL_main_cv),1,SvREFCNT_inc($curpad_sym));",
|
|
"PL_amagic_generation= $amagic_generate;",
|
|
);
|
|
|
|
}
|
|
seek(STDOUT,0,0); #prevent print statements from BEGIN{} into the output
|
|
output_boilerplate();
|
|
print "\n";
|
|
output_all("perl_init");
|
|
output_runtime();
|
|
print "\n";
|
|
output_main();
|
|
if (defined($module)) {
|
|
my $cmodule = $module;
|
|
$cmodule =~ s/::/__/g;
|
|
print <<"EOT";
|
|
|
|
#include "XSUB.h"
|
|
XS(boot_$cmodule)
|
|
{
|
|
dXSARGS;
|
|
perl_init();
|
|
ENTER;
|
|
SAVETMPS;
|
|
SAVEVPTR(PL_curpad);
|
|
SAVEVPTR(PL_op);
|
|
PL_curpad = AvARRAY($curpad_sym);
|
|
PL_op = $start;
|
|
pp_main(aTHX);
|
|
FREETMPS;
|
|
LEAVE;
|
|
ST(0) = &PL_sv_yes;
|
|
XSRETURN(1);
|
|
}
|
|
EOT
|
|
}
|
|
if ($debug_timings) {
|
|
warn sprintf("Done at %s\n", timing_info);
|
|
}
|
|
}
|
|
|
|
sub compile {
|
|
my @options = @_;
|
|
my ($option, $opt, $arg);
|
|
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(STDOUT, ">$arg") or return "open '>$arg': $!\n";
|
|
} elsif ($opt eq "n") {
|
|
$arg ||= shift @options;
|
|
$module_name = $arg;
|
|
} elsif ($opt eq "u") {
|
|
$arg ||= shift @options;
|
|
mark_unused($arg,undef);
|
|
} 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 >= 2) {
|
|
$freetmps_each_loop = 1;
|
|
}
|
|
if ($arg >= 1) {
|
|
$freetmps_each_bblock = 1 unless $freetmps_each_loop;
|
|
}
|
|
} elsif ($opt eq "m") {
|
|
$arg ||= shift @options;
|
|
$module = $arg;
|
|
mark_unused($arg,undef);
|
|
} elsif ($opt eq "p") {
|
|
$arg ||= shift @options;
|
|
$patchlevel = $arg;
|
|
} elsif ($opt eq "D") {
|
|
$arg ||= shift @options;
|
|
foreach $arg (split(//, $arg)) {
|
|
if ($arg eq "o") {
|
|
B->debug(1);
|
|
} elsif ($arg eq "O") {
|
|
$debug_op = 1;
|
|
} elsif ($arg eq "s") {
|
|
$debug_stack = 1;
|
|
} elsif ($arg eq "c") {
|
|
$debug_cxstack = 1;
|
|
} elsif ($arg eq "p") {
|
|
$debug_pad = 1;
|
|
} elsif ($arg eq "r") {
|
|
$debug_runtime = 1;
|
|
} elsif ($arg eq "S") {
|
|
$debug_shadow = 1;
|
|
} elsif ($arg eq "q") {
|
|
$debug_queue = 1;
|
|
} elsif ($arg eq "l") {
|
|
$debug_lineno = 1;
|
|
} elsif ($arg eq "t") {
|
|
$debug_timings = 1;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
init_sections();
|
|
$init = B::Section->get("init");
|
|
$decl = B::Section->get("decl");
|
|
|
|
if (@options) {
|
|
return sub {
|
|
my ($objname, $ppname);
|
|
foreach $objname (@options) {
|
|
$objname = "main::$objname" unless $objname =~ /::/;
|
|
($ppname = $objname) =~ s/^.*?:://;
|
|
eval "cc_obj(qq(pp_sub_$ppname), \\&$objname)";
|
|
die "cc_obj(qq(pp_sub_$ppname, \\&$objname) failed: $@" if $@;
|
|
return if $errors;
|
|
}
|
|
output_boilerplate();
|
|
print "\n";
|
|
output_all($module_name || "init_module");
|
|
output_runtime();
|
|
}
|
|
} else {
|
|
return sub { cc_main() };
|
|
}
|
|
}
|
|
|
|
1;
|
|
|
|
__END__
|
|
|
|
=head1 NAME
|
|
|
|
B::CC - Perl compiler's optimized C translation backend
|
|
|
|
=head1 SYNOPSIS
|
|
|
|
perl -MO=CC[,OPTIONS] foo.pl
|
|
|
|
=head1 DESCRIPTION
|
|
|
|
This compiler backend takes Perl source and generates C source code
|
|
corresponding to the flow of your program. In other words, this
|
|
backend is somewhat a "real" compiler in the sense that many people
|
|
think about compilers. Note however that, currently, it is a very
|
|
poor compiler in that although it generates (mostly, or at least
|
|
sometimes) correct code, it performs relatively few optimisations.
|
|
This will change as the compiler develops. The result is that
|
|
running an executable compiled with this backend may start up more
|
|
quickly than running the original Perl program (a feature shared
|
|
by the B<C> compiler backend--see F<B::C>) and may also execute
|
|
slightly faster. This is by no means a good optimising compiler--yet.
|
|
|
|
=head1 OPTIONS
|
|
|
|
If there are any non-option arguments, they are taken to be
|
|
names of objects to be saved (probably doesn't work properly yet).
|
|
Without extra arguments, it saves the main program.
|
|
|
|
=over 4
|
|
|
|
=item B<-ofilename>
|
|
|
|
Output to filename instead of STDOUT
|
|
|
|
=item B<-v>
|
|
|
|
Verbose compilation (currently gives a few compilation statistics).
|
|
|
|
=item B<-->
|
|
|
|
Force end of options
|
|
|
|
=item B<-uPackname>
|
|
|
|
Force apparently unused subs from package Packname to be compiled.
|
|
This allows programs to use eval "foo()" even when sub foo is never
|
|
seen to be used at compile time. The down side is that any subs which
|
|
really are never used also have code generated. This option is
|
|
necessary, for example, if you have a signal handler foo which you
|
|
initialise with C<$SIG{BAR} = "foo">. A better fix, though, is just
|
|
to change it to C<$SIG{BAR} = \&foo>. You can have multiple B<-u>
|
|
options. The compiler tries to figure out which packages may possibly
|
|
have subs in which need compiling but the current version doesn't do
|
|
it very well. In particular, it is confused by nested packages (i.e.
|
|
of the form C<A::B>) where package C<A> does not contain any subs.
|
|
|
|
=item B<-mModulename>
|
|
|
|
Instead of generating source for a runnable executable, generate
|
|
source for an XSUB module. The boot_Modulename function (which
|
|
DynaLoader can look for) does the appropriate initialisation and runs
|
|
the main part of the Perl source that is being compiled.
|
|
|
|
|
|
=item B<-D>
|
|
|
|
Debug options (concatenated or separate flags like C<perl -D>).
|
|
|
|
=item B<-Dr>
|
|
|
|
Writes debugging output to STDERR just as it's about to write to the
|
|
program's runtime (otherwise writes debugging info as comments in
|
|
its C output).
|
|
|
|
=item B<-DO>
|
|
|
|
Outputs each OP as it's compiled
|
|
|
|
=item B<-Ds>
|
|
|
|
Outputs the contents of the shadow stack at each OP
|
|
|
|
=item B<-Dp>
|
|
|
|
Outputs the contents of the shadow pad of lexicals as it's loaded for
|
|
each sub or the main program.
|
|
|
|
=item B<-Dq>
|
|
|
|
Outputs the name of each fake PP function in the queue as it's about
|
|
to process it.
|
|
|
|
=item B<-Dl>
|
|
|
|
Output the filename and line number of each original line of Perl
|
|
code as it's processed (C<pp_nextstate>).
|
|
|
|
=item B<-Dt>
|
|
|
|
Outputs timing information of compilation stages.
|
|
|
|
=item B<-f>
|
|
|
|
Force optimisations on or off one at a time.
|
|
|
|
=item B<-ffreetmps-each-bblock>
|
|
|
|
Delays FREETMPS from the end of each statement to the end of the each
|
|
basic block.
|
|
|
|
=item B<-ffreetmps-each-loop>
|
|
|
|
Delays FREETMPS from the end of each statement to the end of the group
|
|
of basic blocks forming a loop. At most one of the freetmps-each-*
|
|
options can be used.
|
|
|
|
=item B<-fomit-taint>
|
|
|
|
Omits generating code for handling perl's tainting mechanism.
|
|
|
|
=item B<-On>
|
|
|
|
Optimisation level (n = 0, 1, 2, ...). B<-O> means B<-O1>.
|
|
Currently, B<-O1> sets B<-ffreetmps-each-bblock> and B<-O2>
|
|
sets B<-ffreetmps-each-loop>.
|
|
|
|
=back
|
|
|
|
=head1 EXAMPLES
|
|
|
|
perl -MO=CC,-O2,-ofoo.c foo.pl
|
|
perl cc_harness -o foo foo.c
|
|
|
|
Note that C<cc_harness> lives in the C<B> subdirectory of your perl
|
|
library directory. The utility called C<perlcc> may also be used to
|
|
help make use of this compiler.
|
|
|
|
perl -MO=CC,-mFoo,-oFoo.c Foo.pm
|
|
perl cc_harness -shared -c -o Foo.so Foo.c
|
|
|
|
=head1 BUGS
|
|
|
|
Plenty. Current status: experimental.
|
|
|
|
=head1 DIFFERENCES
|
|
|
|
These aren't really bugs but they are constructs which are heavily
|
|
tied to perl's compile-and-go implementation and with which this
|
|
compiler backend cannot cope.
|
|
|
|
=head2 Loops
|
|
|
|
Standard perl calculates the target of "next", "last", and "redo"
|
|
at run-time. The compiler calculates the targets at compile-time.
|
|
For example, the program
|
|
|
|
sub skip_on_odd { next NUMBER if $_[0] % 2 }
|
|
NUMBER: for ($i = 0; $i < 5; $i++) {
|
|
skip_on_odd($i);
|
|
print $i;
|
|
}
|
|
|
|
produces the output
|
|
|
|
024
|
|
|
|
with standard perl but gives a compile-time error with the compiler.
|
|
|
|
=head2 Context of ".."
|
|
|
|
The context (scalar or array) of the ".." operator determines whether
|
|
it behaves as a range or a flip/flop. Standard perl delays until
|
|
runtime the decision of which context it is in but the compiler needs
|
|
to know the context at compile-time. For example,
|
|
|
|
@a = (4,6,1,0,0,1);
|
|
sub range { (shift @a)..(shift @a) }
|
|
print range();
|
|
while (@a) { print scalar(range()) }
|
|
|
|
generates the output
|
|
|
|
456123E0
|
|
|
|
with standard Perl but gives a compile-time error with compiled Perl.
|
|
|
|
=head2 Arithmetic
|
|
|
|
Compiled Perl programs use native C arithemtic much more frequently
|
|
than standard perl. Operations on large numbers or on boundary
|
|
cases may produce different behaviour.
|
|
|
|
=head2 Deprecated features
|
|
|
|
Features of standard perl such as C<$[> which have been deprecated
|
|
in standard perl since Perl5 was released have not been implemented
|
|
in the compiler.
|
|
|
|
=head1 AUTHOR
|
|
|
|
Malcolm Beattie, C<[email protected]>
|
|
|
|
=cut
|