llvm/tools/llvm-config/find-cycles.pl - toolchain/llvm-project - Gitiles

 #!/usr/bin/perl
 #
 # Program:  find-cycles.pl
 #
 # Synopsis: Given a list of possibly cyclic dependencies, merge all the
 #           cycles.  This makes it possible to topologically sort the
 #           dependencies between different parts of LLVM.
 #
 # Syntax:   find-cycles.pl < LibDeps.txt > FinalLibDeps.txt
 #
 # Input:    cycmem1: cycmem2 dep1 dep2
 #           cycmem2: cycmem1 dep3 dep4
 #           boring: dep4
 #
 # Output:   cycmem1 cycmem2: dep1 dep2 dep3 dep4
 #           boring: dep4
 #
 # This file was written by Eric Kidd, and is placed into the public domain.
 #

 use 5.006;
 use strict;
 use warnings;

 my %DEPS;
 my @CYCLES;
 sub find_all_cycles;

 # Read our dependency information.
 while (<>) {
     chomp;
     my ($module, $dependency_str) = /^\s*([^:]+):\s*(.*)\s*$/;
     die "Malformed data: $_" unless defined $dependency_str;
     my @dependencies = split(/ /, $dependency_str);
     $DEPS{$module} = \@dependencies;
 }

 # Partition our raw dependencies into sets of cyclically-connected nodes.
 find_all_cycles();

 # Print out the finished cycles, with their dependencies.
 my @output;
 my $cycles_found = 0;
 foreach my $cycle (@CYCLES) {
     my @modules = sort keys %{$cycle};

     # Merge the dependencies of all modules in this cycle.
     my %dependencies;
     foreach my $module (@modules) {
         @dependencies{@{$DEPS{$module}}} = 1;
     }

     # Prune the known cyclic dependencies.
     foreach my $module (@modules) {
         delete $dependencies{$module};
     }

     # Warn about possible linker problems.
     my @archives = grep(/\.a$/, @modules);
     if (@archives > 1) {
         $cycles_found = $cycles_found + 1;
         print STDERR "find-cycles.pl: Circular dependency between *.a files:\n";
         print STDERR "find-cycles.pl:   ", join(' ', @archives), "\n";
         push @modules, @archives; # WORKAROUND: Duplicate *.a files. Ick.
     }

     # Add to our output.  (@modules is already as sorted as we need it to be.)
     push @output, (join(' ', @modules) . ': ' .
                    join(' ', sort keys %dependencies) . "\n");
 }
 print sort @output;

 exit $cycles_found;

 #==========================================================================
 #  Depedency Cycle Support
 #==========================================================================
 #  For now, we have cycles in our dependency graph.  Ideally, each cycle
 #  would be collapsed down to a single *.a file, saving us all this work.
 #
 #  To understand this code, you'll need a working knowledge of Perl 5,
 #  and possibly some quality time with 'man perlref'.

 my %SEEN;
 my %CYCLES;
 sub find_cycles ($@);
 sub found_cycles ($@);

 sub find_all_cycles {
     # Find all multi-item cycles.
     my @modules = sort keys %DEPS;
     foreach my $module (@modules) { find_cycles($module); }

     # Build fake one-item "cycles" for the remaining modules, so we can
     # treat them uniformly.
     foreach my $module (@modules) {
         unless (defined $CYCLES{$module}) {
             my %cycle = ($module, 1);
             $CYCLES{$module} = \%cycle;
         }
     }

     # Find all our unique cycles.  We have to do this the hard way because
     # we apparently can't store hash references as hash keys without making
     # 'strict refs' sad.
     my %seen;
     foreach my $cycle (values %CYCLES) {
         unless ($seen{$cycle}) {
             $seen{$cycle} = 1;
             push @CYCLES, $cycle;
         }
     }
 }

 # Walk through our graph depth-first (keeping a trail in @path), and report
 # any cycles we find.
 sub find_cycles ($@) {
     my ($module, @path) = @_;
     if (str_in_list($module, @path)) {
         found_cycle($module, @path);
     } else {
         return if defined $SEEN{$module};
         $SEEN{$module} = 1;
         foreach my $dep (@{$DEPS{$module}}) {
             find_cycles($dep, @path, $module);
         }
     }
 }

 # Give a cycle, attempt to merge it with pre-existing cycle data.
 sub found_cycle ($@) {
     my ($module, @path) = @_;

     # Pop any modules which aren't part of our cycle.
     while ($path[0] ne $module) { shift @path; }
     #print join("->", @path, $module) . "\n";

     # Collect the modules in our cycle into a hash.
     my %cycle;
     foreach my $item (@path) {
         $cycle{$item} = 1;
         if (defined $CYCLES{$item}) {
             # Looks like we intersect with an existing cycle, so merge
             # all those in, too.
             foreach my $old_item (keys %{$CYCLES{$item}}) {
                 $cycle{$old_item} = 1;
             }
         }
     }

     # Update our global cycle table.
     my $cycle_ref = \%cycle;
     foreach my $item (keys %cycle) {
         $CYCLES{$item} = $cycle_ref;
     }
     #print join(":", sort keys %cycle) . "\n";
 }

 sub str_in_list ($@) {
     my ($str, @list) = @_;
     foreach my $item (@list) {
         return 1 if ($item eq $str);
     }
     return 0;
 }
	#!/usr/bin/perl
	#
	# Program: find-cycles.pl
	#
	# Synopsis: Given a list of possibly cyclic dependencies, merge all the
	# cycles. This makes it possible to topologically sort the
	# dependencies between different parts of LLVM.
	#
	# Syntax: find-cycles.pl < LibDeps.txt > FinalLibDeps.txt
	#
	# Input: cycmem1: cycmem2 dep1 dep2
	# cycmem2: cycmem1 dep3 dep4
	# boring: dep4
	#
	# Output: cycmem1 cycmem2: dep1 dep2 dep3 dep4
	# boring: dep4
	#
	# This file was written by Eric Kidd, and is placed into the public domain.
	#

	use 5.006;
	use strict;
	use warnings;

	my %DEPS;
	my @CYCLES;
	sub find_all_cycles;

	# Read our dependency information.
	while (<>) {
	chomp;
	my ($module, $dependency_str) = /^\s([^:]+):\s(.)\s$/;
	die "Malformed data: $_" unless defined $dependency_str;
	my @dependencies = split(/ /, $dependency_str);
	$DEPS{$module} = \@dependencies;
	}

	# Partition our raw dependencies into sets of cyclically-connected nodes.
	find_all_cycles();

	# Print out the finished cycles, with their dependencies.
	my @output;
	my $cycles_found = 0;
	foreach my $cycle (@CYCLES) {
	my @modules = sort keys %{$cycle};

	# Merge the dependencies of all modules in this cycle.
	my %dependencies;
	foreach my $module (@modules) {
	@dependencies{@{$DEPS{$module}}} = 1;
	}

	# Prune the known cyclic dependencies.
	foreach my $module (@modules) {
	delete $dependencies{$module};
	}

	# Warn about possible linker problems.
	my @archives = grep(/\.a$/, @modules);
	if (@archives > 1) {
	$cycles_found = $cycles_found + 1;
	print STDERR "find-cycles.pl: Circular dependency between *.a files:\n";
	print STDERR "find-cycles.pl: ", join(' ', @archives), "\n";
	push @modules, @archives; # WORKAROUND: Duplicate *.a files. Ick.
	}

	# Add to our output. (@modules is already as sorted as we need it to be.)
	push @output, (join(' ', @modules) . ': ' .
	join(' ', sort keys %dependencies) . "\n");
	}
	print sort @output;

	exit $cycles_found;

	#==========================================================================
	# Depedency Cycle Support
	#==========================================================================
	# For now, we have cycles in our dependency graph. Ideally, each cycle
	# would be collapsed down to a single *.a file, saving us all this work.
	#
	# To understand this code, you'll need a working knowledge of Perl 5,
	# and possibly some quality time with 'man perlref'.

	my %SEEN;
	my %CYCLES;
	sub find_cycles ($@);
	sub found_cycles ($@);

	sub find_all_cycles {
	# Find all multi-item cycles.
	my @modules = sort keys %DEPS;
	foreach my $module (@modules) { find_cycles($module); }

	# Build fake one-item "cycles" for the remaining modules, so we can
	# treat them uniformly.
	foreach my $module (@modules) {
	unless (defined $CYCLES{$module}) {
	my %cycle = ($module, 1);
	$CYCLES{$module} = \%cycle;
	}
	}

	# Find all our unique cycles. We have to do this the hard way because
	# we apparently can't store hash references as hash keys without making
	# 'strict refs' sad.
	my %seen;
	foreach my $cycle (values %CYCLES) {
	unless ($seen{$cycle}) {
	$seen{$cycle} = 1;
	push @CYCLES, $cycle;
	}
	}
	}

	# Walk through our graph depth-first (keeping a trail in @path), and report
	# any cycles we find.
	sub find_cycles ($@) {
	my ($module, @path) = @_;
	if (str_in_list($module, @path)) {
	found_cycle($module, @path);
	} else {
	return if defined $SEEN{$module};
	$SEEN{$module} = 1;
	foreach my $dep (@{$DEPS{$module}}) {
	find_cycles($dep, @path, $module);
	}
	}
	}

	# Give a cycle, attempt to merge it with pre-existing cycle data.
	sub found_cycle ($@) {
	my ($module, @path) = @_;

	# Pop any modules which aren't part of our cycle.
	while ($path[0] ne $module) { shift @path; }
	#print join("->", @path, $module) . "\n";

	# Collect the modules in our cycle into a hash.
	my %cycle;
	foreach my $item (@path) {
	$cycle{$item} = 1;
	if (defined $CYCLES{$item}) {
	# Looks like we intersect with an existing cycle, so merge
	# all those in, too.
	foreach my $old_item (keys %{$CYCLES{$item}}) {
	$cycle{$old_item} = 1;
	}
	}
	}

	# Update our global cycle table.
	my $cycle_ref = \%cycle;
	foreach my $item (keys %cycle) {
	$CYCLES{$item} = $cycle_ref;
	}
	#print join(":", sort keys %cycle) . "\n";
	}

	sub str_in_list ($@) {
	my ($str, @list) = @_;
	foreach my $item (@list) {
	return 1 if ($item eq $str);
	}
	return 0;
	}