mirror of
https://github.com/netwide-assembler/nasm.git
synced 2024-11-27 08:10:07 +08:00
177a05d0ce
Clean up some perl warnings, some of which were legitimate (apparently undef doesn't actually take a list of arguments, a common enough mistake that it is mentioned in the man page!, and a list of variables after "my" can be cantankerous), and some of which were nuisance but were easy enough to clean up. Maybe this can resolve the problems with very old version of Perl? Signed-off-by: H. Peter Anvin (Intel) <hpa@zytor.com>
201 lines
4.2 KiB
Perl
201 lines
4.2 KiB
Perl
# -*- perl -*-
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#
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# Perfect Minimal Hash Generator written in Perl, which produces
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# C output.
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#
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require 'random_sv_vectors.ph';
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require 'crc64.ph';
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#
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# Compute the prehash for a key
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#
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# prehash(key, sv, N)
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#
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sub prehash($$$) {
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my($key, $n, $sv) = @_;
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my @c = crc64($sv, $key);
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# Create a bipartite graph...
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$k1 = (($c[1] & ($n-1)) << 1) + 0; # low word
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$k2 = (($c[0] & ($n-1)) << 1) + 1; # high word
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return ($k1, $k2);
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}
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#
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# Walk the assignment graph, return true on success
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#
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sub walk_graph($$$$) {
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my($nodeval,$nodeneigh,$n,$v) = @_;
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my $nx;
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# print STDERR "Vertex $n value $v\n";
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$$nodeval[$n] = $v;
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foreach $nx (@{$$nodeneigh[$n]}) {
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# $nx -> [neigh, hash]
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my ($o, $e) = @$nx;
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# print STDERR "Edge $n,$o value $e: ";
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my $ov;
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if (defined($ov = $$nodeval[$o])) {
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if ($v+$ov != $e) {
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# Cyclic graph with collision
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# print STDERR "error, should be ", $v+$ov, "\n";
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return 0;
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} else {
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# print STDERR "ok\n";
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}
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} else {
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return 0 unless (walk_graph($nodeval, $nodeneigh, $o, $e-$v));
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}
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}
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return 1;
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}
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#
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# Generate the function assuming a given N.
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#
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# gen_hash_n(N, sv, \%data, run)
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#
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sub gen_hash_n($$$$) {
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my($n, $sv, $href, $run) = @_;
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my @keys = keys(%{$href});
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my $i;
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my $gr;
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my ($k, $v);
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my $gsize = 2*$n;
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my @nodeval;
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my @nodeneigh;
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my %edges;
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for ($i = 0; $i < $gsize; $i++) {
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$nodeneigh[$i] = [];
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}
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%edges = ();
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foreach $k (@keys) {
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my ($pf1, $pf2) = prehash($k, $n, $sv);
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($pf1,$pf2) = ($pf2,$pf1) if ($pf1 > $pf2); # Canonicalize order
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my $pf = "$pf1,$pf2";
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my $e = ${$href}{$k};
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my $xkey;
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if (defined($xkey = $edges{$pf})) {
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next if ($e == ${$href}{$xkey}); # Duplicate hash, safe to ignore
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if (defined($run)) {
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print STDERR "$run: Collision: $pf: $k with $xkey\n";
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}
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return;
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}
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# print STDERR "Edge $pf value $e from $k\n";
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$edges{$pf} = $k;
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push(@{$nodeneigh[$pf1]}, [$pf2, $e]);
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push(@{$nodeneigh[$pf2]}, [$pf1, $e]);
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}
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# Now we need to assign values to each vertex, so that for each
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# edge, the sum of the values for the two vertices give the value
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# for the edge (which is our hash index.) If we find an impossible
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# sitation, the graph was cyclic.
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@nodeval = (undef) x $gsize;
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for ($i = 0; $i < $gsize; $i++) {
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if (scalar(@{$nodeneigh[$i]})) {
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# This vertex has neighbors (is used)
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if (!defined($nodeval[$i])) {
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# First vertex in a cluster
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unless (walk_graph(\@nodeval, \@nodeneigh, $i, 0)) {
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if (defined($run)) {
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print STDERR "$run: Graph is cyclic\n";
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}
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return;
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}
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}
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}
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}
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# for ($i = 0; $i < $n; $i++) {
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# print STDERR "Vertex ", $i, ": ", $g[$i], "\n";
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# }
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if (defined($run)) {
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printf STDERR "$run: Done: n = $n, sv = [0x%08x, 0x%08x]\n",
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$$sv[0], $$sv[1];
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}
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return ($n, $sv, \@nodeval);
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}
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#
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# Driver for generating the function
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#
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# gen_perfect_hash(\%data)
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#
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sub gen_perfect_hash($) {
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my($href) = @_;
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my @keys = keys(%{$href});
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my @hashinfo;
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my ($n, $i, $j, $sv, $maxj);
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my $run = 1;
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# Minimal power of 2 value for N with enough wiggle room.
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# The scaling constant must be larger than 0.5 in order for the
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# algorithm to ever terminate.
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my $room = int(scalar(@keys)*0.8);
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$n = 1;
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while ($n < $room) {
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$n <<= 1;
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}
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# Number of times to try...
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$maxj = scalar @random_sv_vectors;
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for ($i = 0; $i < 4; $i++) {
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printf STDERR "%d vectors, trying n = %d...\n",
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scalar @keys, $n;
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for ($j = 0; $j < $maxj; $j++) {
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$sv = $random_sv_vectors[$j];
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@hashinfo = gen_hash_n($n, $sv, $href, $run++);
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return @hashinfo if (@hashinfo);
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}
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$n <<= 1;
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}
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return;
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}
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#
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# Verify that the hash table is actually correct...
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#
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sub verify_hash_table($$)
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{
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my ($href, $hashinfo) = @_;
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my ($n, $sv, $g) = @{$hashinfo};
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my $k;
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my $err = 0;
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foreach $k (keys(%$href)) {
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my ($pf1, $pf2) = prehash($k, $n, $sv);
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my $g1 = ${$g}[$pf1];
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my $g2 = ${$g}[$pf2];
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if ($g1+$g2 != ${$href}{$k}) {
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printf STDERR "%s(%d,%d): %d+%d = %d != %d\n",
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$k, $pf1, $pf2, $g1, $g2, $g1+$g2, ${$href}{$k};
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$err = 1;
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} else {
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# printf STDERR "%s: %d+%d = %d ok\n",
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# $k, $g1, $g2, $g1+$g2;
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}
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}
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die "$0: hash validation error\n" if ($err);
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}
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1;
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