#! @perl@ -w -I@libexecdir@/nix
use strict;
use File::Temp qw(tempdir);
use readmanifest;
# Some hard-coded options.
my $maxNarSize = 100 * 1024 * 1024; # max size of NAR archives to generate patches for
my $maxPatchFraction = 0.60; # if patch is bigger than this fraction of full archive, reject
die unless scalar @ARGV == 5;
my $hashAlgo = "sha256";
my $cacheDir = $ARGV[0];
my $patchesDir = $ARGV[1];
my $patchesURL = $ARGV[2];
my $srcDir = $ARGV[3];
my $dstDir = $ARGV[4];
my $tmpDir = tempdir("nix-generate-patches.XXXXXX", CLEANUP => 1, TMPDIR => 1)
or die "cannot create a temporary directory";
print "TEMP = $tmpDir\n";
#END { rmdir $tmpDir; }
my %srcNarFiles;
my %srcPatches;
my %srcSuccessors;
my %dstNarFiles;
my %dstPatches;
my %dstSuccessors;
readManifest "$srcDir/MANIFEST",
\%srcNarFiles, \%srcPatches, \%srcSuccessors;
readManifest "$dstDir/MANIFEST",
\%dstNarFiles, \%dstPatches, \%dstSuccessors;
sub findOutputPaths {
my $narFiles = shift;
my $successors = shift;
my %outPaths;
foreach my $p (keys %{$narFiles}) {
# Ignore store expressions.
next if ($p =~ /\.store$/);
next if ($p =~ /\.drv$/);
# Ignore builders (too much ambiguity -- they're all called
# `builder.sh').
next if ($p =~ /\.sh$/);
next if ($p =~ /\.patch$/);
# Don't bother including tar files etc.
next if ($p =~ /\.tar\.(gz|bz2)$/ || $p =~ /\.zip$/ || $p =~ /\.bin$/);
$outPaths{$p} = 1;
}
return %outPaths;
}
print "finding src output paths...\n";
my %srcOutPaths = findOutputPaths \%srcNarFiles, \%srcSuccessors;
print "finding dst output paths...\n";
my %dstOutPaths = findOutputPaths \%dstNarFiles, \%dstSuccessors;
sub getNameVersion {
my $p = shift;
$p =~ /\/[0-9a-z]+((?:-[a-zA-Z][^\/-]*)+)([^\/]*)$/;
my $name = $1;
my $version = $2;
$name =~ s/^-//;
$version =~ s/^-//;
return ($name, $version);
}
# A quick hack to get a measure of the `distance' between two
# versions: it's just the position of the first character that differs
# (or 999 if they are the same).
sub versionDiff {
my $s = shift;
my $t = shift;
my $i;
return 999 if $s eq $t;
for ($i = 0; $i < length $s; $i++) {
return $i if $i >= length $t or
substr($s, $i, 1) ne substr($t, $i, 1);
}
return $i;
}
sub getNarBz2 {
my $narFiles = shift;
my $storePath = shift;
my $narFileList = $$narFiles{$storePath};
die "missing store expression $storePath" unless defined $narFileList;
my $narFile = @{$narFileList}[0];
die unless defined $narFile;
$narFile->{url} =~ /\/([^\/]+)$/;
die unless defined $1;
return "$cacheDir/$1";
}
sub containsPatch {
my $patches = shift;
my $storePath = shift;
my $basePath = shift;
my $patchList = $$patches{$storePath};
return 0 if !defined $patchList;
my $found = 0;
foreach my $patch (@{$patchList}) {
# !!! baseHash might differ
return 1 if $patch->{basePath} eq $basePath;
}
return 0;
}
# Compute the "weighted" number of uses of a path in the build graph.
sub computeUses {
my $narFiles = shift;
my $path = shift;
# Find the deriver of $path.
return 1 unless defined $$narFiles{$path};
my $deriver = @{$$narFiles{$path}}[0]->{deriver};
return 1 unless defined $deriver && $deriver ne "";
# print " DERIVER $deriver\n";
# Optimisation: build the referrers graph from the references
# graph.
my %referrers;
foreach my $q (keys %{$narFiles}) {
my @refs = split " ", @{$$narFiles{$q}}[0]->{references};
foreach my $r (@refs) {
$referrers{$r} = [] unless defined $referrers{$r};
push @{$referrers{$r}}, $q;
}
}
# Determine the shortest path from $deriver to all other reachable
# paths in the `referrers' graph.
my %dist;
$dist{$deriver} = 0;
my @queue = ($deriver);
my $pos = 0;
while ($pos < scalar @queue) {
my $p = $queue[$pos];
$pos++;
foreach my $q (@{$referrers{$p}}) {
if (!defined $dist{$q}) {
$dist{$q} = $dist{$p} + 1;
# print " $q $dist{$q}\n";
push @queue, $q;
}
}
}
my $wuse = 1.0;
foreach my $user (keys %dist) {
next if $user eq $deriver;
# print " $user $dist{$user}\n";
$wuse += 1.0 / 2.0**$dist{$user};
}
# print " XXX $path $wuse\n";
return $wuse;
}
# For each output path in the destination, see if we need to / can
# create a patch.
print "creating patches...\n";
foreach my $p (keys %dstOutPaths) {
# If exactly the same path already exists in the source, skip it.
next if defined $srcOutPaths{$p};
print " $p\n";
# If not, then we should find the paths in the source that are
# `most' likely to be present on a system that wants to install
# this path.
(my $name, my $version) = getNameVersion $p;
my @closest = ();
my $closestVersion;
my $minDist = -1; # actually, larger means closer
# Find all source paths with the same name.
foreach my $q (keys %srcOutPaths) {
(my $name2, my $version2) = getNameVersion $q;
if ($name eq $name2) {
# If the sizes differ too much, then skip. This
# disambiguates between, e.g., a real component and a
# wrapper component (cf. Firefox in Nixpkgs).
my $srcSize = @{$srcNarFiles{$q}}[0]->{size};
my $dstSize = @{$dstNarFiles{$p}}[0]->{size};
my $ratio = $srcSize / $dstSize;
$ratio = 1 / $ratio if $ratio < 1;
# print " SIZE $srcSize $dstSize $ratio $q\n";
if ($ratio >= 3) {
print " SKIPPING $q due to size ratio $ratio ($srcSize $dstSize)\n";
next;
}
# If the numbers of weighted uses differ too much, then
# skip. This disambiguates between, e.g., the bootstrap
# GCC and the final GCC in Nixpkgs.
my $srcUses = computeUses \%srcNarFiles, $q;
my $dstUses = computeUses \%dstNarFiles, $p;
$ratio = $srcUses / $dstUses;
$ratio = 1 / $ratio if $ratio < 1;
print " USE $srcUses $dstUses $ratio $q\n";
# if ($ratio >= 2) {
# print " SKIPPING $q due to use ratio $ratio ($srcUses $dstUses)\n";
# next;
# }
# If there are multiple matching names, include the ones
# with the closest version numbers.
my $dist = versionDiff $version, $version2;
if ($dist > $minDist) {
$minDist = $dist;
@closest = ($q);
$closestVersion = $version2;
} elsif ($dist == $minDist) {
push @closest, $q;
}
}
}
if (scalar(@closest) == 0) {
print " NO BASE: $p\n";
next;
}
foreach my $closest (@closest) {
# Generate a patch between $closest and $p.
print " $p <- $closest\n";
# If the patch already exists, skip it.
if (containsPatch(\%srcPatches, $p, $closest) ||
containsPatch(\%dstPatches, $p, $closest))
{
print " skipping, already exists\n";
next;
}
# next;
my $srcNarBz2 = getNarBz2 \%srcNarFiles, $closest;
my $dstNarBz2 = getNarBz2 \%dstNarFiles, $p;
system("@bunzip2@ < $srcNarBz2 > $tmpDir/A") == 0
or die "cannot unpack $srcNarBz2";
if ((stat "$tmpDir/A")[7] >= $maxNarSize) {
print " skipping, source is too large\n";
next;
}
system("@bunzip2@ < $dstNarBz2 > $tmpDir/B") == 0
or die "cannot unpack $dstNarBz2";
if ((stat "$tmpDir/B")[7] >= $maxNarSize) {
print " skipping, destination is too large\n";
next;
}
system("@libexecdir@/bsdiff $tmpDir/A $tmpDir/B $tmpDir/DIFF") == 0
or die "cannot compute binary diff";
my $baseHash = `@bindir@/nix-hash --flat --type $hashAlgo --base32 $tmpDir/A` or die;
chomp $baseHash;
my $narHash = `@bindir@/nix-hash --flat --type $hashAlgo --base32 $tmpDir/B` or die;
chomp $narHash;
my $narDiffHash = `@bindir@/nix-hash --flat --type $hashAlgo --base32 $tmpDir/DIFF` or die;
chomp $narDiffHash;
my $narDiffSize = (stat "$tmpDir/DIFF")[7];
my $dstNarBz2Size = (stat $dstNarBz2)[7];
print " size $narDiffSize; full size $dstNarBz2Size\n";
if ($narDiffSize >= $dstNarBz2Size) {
print " rejecting; patch bigger than full archive\n";
next;
}
if ($narDiffSize / $dstNarBz2Size >= $maxPatchFraction) {
print " rejecting; patch too large relative to full archive\n";
next;
}
my $finalName =
"$narDiffHash.nar-bsdiff";
if (-e "$patchesDir/$finalName") {
print " not copying, already exists\n";
}
else {
system("cp '$tmpDir/DIFF' '$patchesDir/$finalName.tmp'") == 0
or die "cannot copy diff";
rename("$patchesDir/$finalName.tmp", "$patchesDir/$finalName")
or die "cannot rename $patchesDir/$finalName.tmp";
}
# Add the patch to the manifest.
addPatch \%dstPatches, $p,
{ url => "$patchesURL/$finalName", hash => "$hashAlgo:$narDiffHash"
, size => $narDiffSize, basePath => $closest, baseHash => "$hashAlgo:$baseHash"
, narHash => "$hashAlgo:$narHash", patchType => "nar-bsdiff"
}, 0;
}
}
# Add in any potentially useful patches in the source (namely, those
# patches that produce either paths in the destination or paths that
# can be used as the base for other useful patches).
print "propagating patches...\n";
my $changed;
do {
# !!! we repeat this to reach the transitive closure; inefficient
$changed = 0;
print "loop\n";
my %dstBasePaths;
foreach my $q (keys %dstPatches) {
foreach my $patch (@{$dstPatches{$q}}) {
$dstBasePaths{$patch->{basePath}} = 1;
}
}
foreach my $p (keys %srcPatches) {
my $patchList = $srcPatches{$p};
my $include = 0;
# Is path $p included in the destination? If so, include
# patches that produce it.
$include = 1 if defined $dstNarFiles{$p};
# Is path $p a path that serves as a base for paths in the
# destination? If so, include patches that produce it.
# !!! check baseHash
$include = 1 if defined $dstBasePaths{$p};
if ($include) {
foreach my $patch (@{$patchList}) {
$changed = 1 if addPatch \%dstPatches, $p, $patch;
}
}
}
} while $changed;
# Rewrite the manifest of the destination (with the new patches).
writeManifest "$dstDir/MANIFEST",
\%dstNarFiles, \%dstPatches, \%dstSuccessors;