boost_1_45_0/tools/build/v2/util/order.jam - nest-learning-thermostat/5.0/boost - Git at Google

 #  Copyright (C) 2003 Vladimir Prus
 #  Use, modification, and distribution is subject to the Boost Software
 #  License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy
 #  at http://www.boost.org/LICENSE_1_0.txt)

 #  This module defines a class which allows to order arbitrary object with
 # regard to arbitrary binary relation.
 #
 #  The primary use case is the gcc toolset, which is sensitive to library order:
 #  if library 'a' uses symbols from library 'b', then 'a' must be present before
 #  'b' on the linker's command line.
 #
 #  This requirement can be lifted for gcc with GNU ld, but for gcc with Solaris
 #  LD (and for Solaris toolset as well), the order always matters.
 #
 #  So, we need to store order requirements and then order libraries according to
 #  them. It is not possible to use the dependency graph as order requirements.
 #  What we need is a "use symbols" relationship while dependency graph provides
 #  the "needs to be updated" relationship.
 #
 #  For example::
 #    lib a : a.cpp b;
 #    lib b ;
 #
 #  For static linking, library 'a' need not depend on 'b'. However, it should
 #  still come before 'b' on the command line.

 class order
 {
     rule __init__ ( )
     {
     }

     # Adds the constraint that 'first' should preceede 'second'.
     rule add-pair ( first second )
     {
         .constraits += $(first)--$(second) ;
     }
     NATIVE_RULE class@order : add-pair ;

     # Given a list of objects, reorder them so that the constraints specified by
     # 'add-pair' are satisfied.
     #
     # The algorithm was adopted from an awk script by Nikita Youshchenko
     # (yoush at cs dot msu dot su)
     rule order ( objects * )
     {
         # The algorithm used is the same is standard transitive closure, except
         # that we're not keeping in-degree for all vertices, but rather removing
         # edges.
         local result ;
         if $(objects)
         {
             local constraints = [ eliminate-unused-constraits $(objects) ] ;

             # Find some library that nobody depends upon and add it to the
             # 'result' array.
             local obj ;
             while $(objects)
             {
                 local new_objects ;
                 while $(objects)
                 {
                     obj = $(objects[1]) ;
                     if [ has-no-dependents $(obj) : $(constraints) ]
                     {
                         # Emulate break ;
                         new_objects += $(objects[2-]) ;
                         objects = ;
                     }
                     else
                     {
                         new_objects += $(obj) ;
                         obj = ;
                         objects = $(objects[2-]) ;
                     }
                 }

                 if ! $(obj)
                 {
                     errors.error "Circular order dependencies" ;
                 }
                 # No problem with placing first.
                 result += $(obj) ;
                 # Remove all contraints where 'obj' comes first, since they are
                 # already satisfied.
                 constraints = [ remove-satisfied $(constraints) : $(obj) ] ;

                 # Add the remaining objects for further processing on the next
                 # iteration
                 objects = $(new_objects) ;
             }

         }
         return $(result) ;
     }
     NATIVE_RULE class@order : order ;

     # Eliminate constraints which mention objects not in 'objects'. In
     # graph-theory terms, this is finding a subgraph induced by ordered
     # vertices.
     rule eliminate-unused-constraits ( objects * )
     {
         local result ;
         for local c in $(.constraints)
         {
             local m = [ MATCH (.*)--(.*) : $(c) ] ;
             if $(m[1]) in $(objects) && $(m[2]) in $(objects)
             {
                 result += $(c) ;
             }
         }
         return $(result) ;
     }

     # Returns true if there's no constraint in 'constaraints' where 'obj' comes
     # second.
     rule has-no-dependents ( obj : constraints * )
     {
         local failed ;
         while $(constraints) && ! $(failed)
         {
             local c = $(constraints[1]) ;
             local m = [ MATCH (.*)--(.*) : $(c) ] ;
             if $(m[2]) = $(obj)
             {
                 failed = true ;
             }
             constraints = $(constraints[2-]) ;
         }
         if ! $(failed)
         {
             return true ;
         }
     }

     rule remove-satisfied ( constraints * : obj )
     {
         local result ;
         for local c in $(constraints)
         {
             local m = [ MATCH (.*)--(.*) : $(c) ] ;
             if $(m[1]) != $(obj)
             {
                 result += $(c) ;
             }
         }
         return $(result) ;
     }
 }


 rule __test__ ( )
 {
     import "class" : new ;
     import assert ;

     c1 = [ new order ] ;
     $(c1).add-pair l1 l2 ;

     assert.result l1 l2 : $(c1).order l1 l2 ;
     assert.result l1 l2 : $(c1).order l2 l1 ;

     $(c1).add-pair l2 l3 ;
     assert.result l1 l2 : $(c1).order l2 l1 ;
     $(c1).add-pair x l2 ;
     assert.result l1 l2 : $(c1).order l2 l1 ;
     assert.result l1 l2 l3 : $(c1).order l2 l3 l1 ;
 }
	# Copyright (C) 2003 Vladimir Prus
	# Use, modification, and distribution is subject to the Boost Software
	# License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy
	# at http://www.boost.org/LICENSE_1_0.txt)

	# This module defines a class which allows to order arbitrary object with
	# regard to arbitrary binary relation.
	#
	# The primary use case is the gcc toolset, which is sensitive to library order:
	# if library 'a' uses symbols from library 'b', then 'a' must be present before
	# 'b' on the linker's command line.
	#
	# This requirement can be lifted for gcc with GNU ld, but for gcc with Solaris
	# LD (and for Solaris toolset as well), the order always matters.
	#
	# So, we need to store order requirements and then order libraries according to
	# them. It is not possible to use the dependency graph as order requirements.
	# What we need is a "use symbols" relationship while dependency graph provides
	# the "needs to be updated" relationship.
	#
	# For example::
	# lib a : a.cpp b;
	# lib b ;
	#
	# For static linking, library 'a' need not depend on 'b'. However, it should
	# still come before 'b' on the command line.

	class order
	{
	rule __init__ ( )
	{
	}

	# Adds the constraint that 'first' should preceede 'second'.
	rule add-pair ( first second )
	{
	.constraits += $(first)--$(second) ;
	}
	NATIVE_RULE class@order : add-pair ;

	# Given a list of objects, reorder them so that the constraints specified by
	# 'add-pair' are satisfied.
	#
	# The algorithm was adopted from an awk script by Nikita Youshchenko
	# (yoush at cs dot msu dot su)
	rule order ( objects * )
	{
	# The algorithm used is the same is standard transitive closure, except
	# that we're not keeping in-degree for all vertices, but rather removing
	# edges.
	local result ;
	if $(objects)
	{
	local constraints = [ eliminate-unused-constraits $(objects) ] ;

	# Find some library that nobody depends upon and add it to the
	# 'result' array.
	local obj ;
	while $(objects)
	{
	local new_objects ;
	while $(objects)
	{
	obj = $(objects[1]) ;
	if [ has-no-dependents $(obj) : $(constraints) ]
	{
	# Emulate break ;
	new_objects += $(objects[2-]) ;
	objects = ;
	}
	else
	{
	new_objects += $(obj) ;
	obj = ;
	objects = $(objects[2-]) ;
	}
	}

	if ! $(obj)
	{
	errors.error "Circular order dependencies" ;
	}
	# No problem with placing first.
	result += $(obj) ;
	# Remove all contraints where 'obj' comes first, since they are
	# already satisfied.
	constraints = [ remove-satisfied $(constraints) : $(obj) ] ;

	# Add the remaining objects for further processing on the next
	# iteration
	objects = $(new_objects) ;
	}

	}
	return $(result) ;
	}
	NATIVE_RULE class@order : order ;

	# Eliminate constraints which mention objects not in 'objects'. In
	# graph-theory terms, this is finding a subgraph induced by ordered
	# vertices.
	rule eliminate-unused-constraits ( objects * )
	{
	local result ;
	for local c in $(.constraints)
	{
	local m = [ MATCH (.)--(.) : $(c) ] ;
	if $(m[1]) in $(objects) && $(m[2]) in $(objects)
	{
	result += $(c) ;
	}
	}
	return $(result) ;
	}

	# Returns true if there's no constraint in 'constaraints' where 'obj' comes
	# second.
	rule has-no-dependents ( obj : constraints * )
	{
	local failed ;
	while $(constraints) && ! $(failed)
	{
	local c = $(constraints[1]) ;
	local m = [ MATCH (.)--(.) : $(c) ] ;
	if $(m[2]) = $(obj)
	{
	failed = true ;
	}
	constraints = $(constraints[2-]) ;
	}
	if ! $(failed)
	{
	return true ;
	}
	}

	rule remove-satisfied ( constraints * : obj )
	{
	local result ;
	for local c in $(constraints)
	{
	local m = [ MATCH (.)--(.) : $(c) ] ;
	if $(m[1]) != $(obj)
	{
	result += $(c) ;
	}
	}
	return $(result) ;
	}
	}


	rule __test__ ( )
	{
	import "class" : new ;
	import assert ;

	c1 = [ new order ] ;
	$(c1).add-pair l1 l2 ;

	assert.result l1 l2 : $(c1).order l1 l2 ;
	assert.result l1 l2 : $(c1).order l2 l1 ;

	$(c1).add-pair l2 l3 ;
	assert.result l1 l2 : $(c1).order l2 l1 ;
	$(c1).add-pair x l2 ;
	assert.result l1 l2 : $(c1).order l2 l1 ;
	assert.result l1 l2 l3 : $(c1).order l2 l3 l1 ;
	}