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CMake/Source/cmTarget.cxx

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/*=========================================================================
Program: Insight Segmentation & Registration Toolkit
Module: $RCSfile$
Language: C++
Date: $Date$
Version: $Revision$
Copyright (c) 2002 Insight Consortium. All rights reserved.
See ITKCopyright.txt or http://www.itk.org/HTML/Copyright.htm for details.
This software is distributed WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
PURPOSE. See the above copyright notices for more information.
=========================================================================*/
#include "cmTarget.h"
#include "cmMakefile.h"
#include <map>
#include <set>
void cmTarget::GenerateSourceFilesFromSourceLists( cmMakefile &mf)
{
// this is only done for non install targets
if ((this->m_TargetType == cmTarget::INSTALL_FILES)
|| (this->m_TargetType == cmTarget::INSTALL_PROGRAMS))
{
return;
}
// for each src lists add the classes
for (std::vector<std::string>::const_iterator s = m_SourceLists.begin();
s != m_SourceLists.end(); ++s)
{
// replace any variables
std::string temps = *s;
mf.ExpandVariablesInString(temps);
// look for a srclist
if (mf.GetSources().find(temps) != mf.GetSources().end())
{
const std::vector<cmSourceFile*> &clsList =
mf.GetSources().find(temps)->second;
// if we ahave a limited build list, use it
m_SourceFiles.insert(m_SourceFiles.end(),
clsList.begin(),
clsList.end());
}
// if one wasn't found then assume it is a single class
else
{
cmSourceFile file;
file.SetIsAnAbstractClass(false);
file.SetName(temps.c_str(), mf.GetCurrentDirectory(),
mf.GetSourceExtensions(),
mf.GetHeaderExtensions());
m_SourceFiles.push_back(mf.AddSource(file));
}
}
// expand any link library variables whle we are at it
LinkLibraries::iterator p = m_LinkLibraries.begin();
for (;p != m_LinkLibraries.end(); ++p)
{
mf.ExpandVariablesInString(p->first);
}
}
void cmTarget::AddLinkLibrary(const std::string& lib,
LinkLibraryType llt)
{
m_LinkLibraries.push_back( std::pair<std::string, cmTarget::LinkLibraryType>(lib,llt) );
}
void cmTarget::AddLinkLibrary(cmMakefile& mf,
const char *target, const char* lib,
LinkLibraryType llt)
{
m_LinkLibraries.push_back( std::pair<std::string, cmTarget::LinkLibraryType>(lib,llt) );
mf.AddDependencyToCache( target, lib );
}
bool cmTarget::HasCxx() const
{
for(std::vector<cmSourceFile*>::const_iterator i = m_SourceFiles.begin();
i != m_SourceFiles.end(); ++i)
{
if((*i)->GetSourceExtension() != "c")
{
return true;
}
}
return false;
}
void
cmTarget::AnalyzeLibDependencies( const cmMakefile& mf )
{
typedef std::vector< std::string > LinkLine;
// Maps the canonical names to the full objects of m_LinkLibraries.
LibTypeMap lib_map;
// The unique list of libraries on the orginal link line. They
// correspond to lib_map keys. However, lib_map will also get
// further populated by the dependency analysis.
LinkLine orig_libs;
// The list canonical names in the order they were orginally
// specified on the link line (m_LinkLibraries).
LinkLine lib_order;
// The dependency maps.
DependencyMap dep_map, dep_map_implicit;
LinkLibraries::iterator lib;
for(lib = m_LinkLibraries.begin(); lib != m_LinkLibraries.end(); ++lib)
{
// skip zero size library entries, this may happen
// if a variable expands to nothing.
if (lib->first.size() == 0) continue;
std::string cname = CanonicalLibraryName(lib->first);
lib_order.push_back( cname );
if( lib_map.end() == lib_map.find( cname ) )
{
lib_map[ cname ] = *lib;
orig_libs.push_back( cname );
}
}
// First, get the explicit dependencies for those libraries that
// have specified them
for( LinkLine::iterator i = orig_libs.begin(); i != orig_libs.end(); ++i )
{
GatherDependencies( mf, *i, dep_map, lib_map );
}
// For the rest, get implicit dependencies. A library x depends
// implicitly on a library y if x appears before y on the link
// line. However, x does not implicitly depend on y if y
// *explicitly* depends on x [*1]--such cyclic dependencies must be
// explicitly specified. Note that implicit dependency cycles can
// still occur: "-lx -ly -lx" will generate a implicit dependency
// cycle provided that neither x nor y have explicit dependencies.
//
// [*1] This prevents external libraries from depending on libraries
// generated by this project.
for( LinkLine::iterator i = orig_libs.begin(); i != orig_libs.end(); ++i )
{
if( dep_map.find( *i ) == dep_map.end() )
{
LinkLine::iterator pos = std::find( lib_order.begin(), lib_order.end(), *i );
for( ; pos != lib_order.end(); ++pos )
{
std::set<std::string> visited;
if( !DependsOn( *pos, *i, dep_map, visited ) )
{
dep_map_implicit[ *i ].insert( *pos );
}
}
dep_map_implicit[ *i ].erase( *i ); // cannot depend on itself
}
}
// Combine all the depedency information
// dep_map.insert( dep_map_implicit.begin(), dep_map_implicit.end() );
// doesn't work under MSVC++.
for( DependencyMap::iterator i = dep_map_implicit.begin();
i != dep_map_implicit.end(); ++i )
{
dep_map[ i->first ] = i->second;
}
// Create a new link line order.
std::set<std::string> done, visited;
std::vector<std::string> link_line;
for( LinkLine::iterator i = orig_libs.begin(); i != orig_libs.end(); ++i )
{
Emit( *i, dep_map, done, visited, link_line );
}
// If LIBRARY_OUTPUT_PATH is not set, then we must add search paths
// for all the new libraries added by the dependency analysis.
const char* libOutPath = mf.GetDefinition("LIBRARY_OUTPUT_PATH");
bool addLibDirs = (libOutPath==0 || strcmp(libOutPath,"")==0);
m_LinkLibraries.clear();
for( std::vector<std::string>::reverse_iterator i = link_line.rbegin();
i != link_line.rend(); ++i )
{
// Some of the libraries in the new link line may not have been in
// the orginal link line, but were added by the dependency
// analysis. For these libraries, we assume the GENERAL type and
// add the name of the library.
if( lib_map.find(*i) == lib_map.end() )
{
if( addLibDirs )
{
const char* libpath = mf.GetDefinition( i->c_str() );
if( libpath )
{
// Don't add a link directory that is already present.
if(std::find(m_LinkDirectories.begin(),
m_LinkDirectories.end(), libpath) == m_LinkDirectories.end())
{
m_LinkDirectories.push_back(libpath);
}
}
}
m_LinkLibraries.push_back( std::make_pair(*i,GENERAL) );
}
else
{
m_LinkLibraries.push_back( lib_map[ *i ] );
}
}
}
std::string cmTarget::CanonicalLibraryName( const std::string& lib ) const
{
cmRegularExpression reg("((^[ \t]*\\-l)|(^[ \t]*\\-framework[ \t]*))(.+)");
if(lib.find('/') != std::string::npos
&& !reg.find(lib))
{
std::string dir, file;
cmSystemTools::SplitProgramPath(lib.c_str(),
dir, file);
cmRegularExpression libname("lib(.*)(\\.so|\\.sl|\\.a|\\.dylib).*");
cmRegularExpression libname_noprefix("(.*)(\\.so|\\.sl|\\.a|\\.dylib|\\.lib).*");
if(libname.find(file))
{
return libname.match(1);
}
else if(libname_noprefix.find(file))
{
return libname_noprefix.match(1);
}
else
{
return file;
}
}
else
{
if(!reg.find(lib))
{
return lib;
}
else
{
return reg.match(4);
}
}
}
void cmTarget::Emit( const std::string& lib,
const DependencyMap& dep_map,
std::set<std::string>& emitted,
std::set<std::string>& visited,
std::vector<std::string>& link_line ) const
{
// It's already been emitted
if( emitted.find(lib) != emitted.end() )
{
return;
}
// If this library hasn't been visited before, then emit all its
// dependencies before emitting the library itself. If it has been
// visited before, then there is a dependency cycle. Just emit the
// library itself, and let the recursion that got us here deal with
// emitting the dependencies for the library.
if( visited.insert(lib).second )
{
if( dep_map.find(lib) != dep_map.end() ) // does it have dependencies?
{
const std::set<std::string>& dep_on = dep_map.find( lib )->second;
std::set<std::string>::const_iterator i;
for( i = dep_on.begin(); i != dep_on.end(); ++i )
{
Emit( *i, dep_map, emitted, visited, link_line );
}
}
}
link_line.push_back( lib );
emitted.insert(lib);
}
void cmTarget::GatherDependencies( const cmMakefile& mf,
const std::string& lib,
DependencyMap& dep_map,
LibTypeMap& lib_map ) const
{
// If the library is already in the dependency map, then it has
// already been fully processed.
if( dep_map.find(lib) != dep_map.end() )
return;
const char* deps = mf.GetDefinition( (lib+"_LIB_DEPENDS").c_str() );
if( deps && strcmp(deps,"") != 0 )
{
// Make sure this library is in the map, even if it has an empty
// set of dependencies. This distinguishes the case of explicitly
// no dependencies with that of unspecified dependencies.
dep_map[lib];
// Parse the dependency information, which is simply a set of
// libraries separated by ";". There is always a trailing ";".
std::string depline = deps;
std::string::size_type start = 0;
std::string::size_type end;
end = depline.find( ";", start );
while( end != std::string::npos )
{
std::string l = depline.substr( start, end-start );
if( l.size() != 0 )
{
const std::string cname = CanonicalLibraryName(l);
lib_map[ cname ] = std::make_pair(l,GENERAL); // ** FIXME: we need to store the correct type here
dep_map[ lib ].insert( cname );
GatherDependencies( mf, cname, dep_map, lib_map );
}
start = end+1; // skip the ;
end = depline.find( ";", start );
}
dep_map[lib].erase(lib); // cannot depend on itself
}
}
bool cmTarget::DependsOn( const std::string& lib1, const std::string& lib2,
const DependencyMap& dep_map,
std::set<std::string>& visited ) const
{
if( !visited.insert( lib1 ).second )
return false; // already visited here
if( lib1 == lib2 )
return false;
if( dep_map.find(lib1) == dep_map.end() )
return false; // lib1 doesn't have any dependencies
const std::set<std::string>& dep_set = dep_map.find(lib1)->second;
if( dep_set.end() != dep_set.find( lib2 ) )
return true; // lib1 doesn't directly depend on lib2.
// Do a recursive check: does lib1 depend on x which depends on lib2?
for( std::set<std::string>::const_iterator itr = dep_set.begin();
itr != dep_set.end(); ++itr )
{
if( DependsOn( *itr, lib2, dep_map, visited ) )
return true;
}
return false;
}
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