CMake/Source/cmTarget.cxx

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/*============================================================================
CMake - Cross Platform Makefile Generator
Copyright 2000-2009 Kitware, Inc., Insight Software Consortium
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Distributed under the OSI-approved BSD License (the "License");
see accompanying file Copyright.txt for details.
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This software is distributed WITHOUT ANY WARRANTY; without even the
implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the License for more information.
============================================================================*/
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#include "cmTarget.h"
#include "cmake.h"
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#include "cmMakefile.h"
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#include "cmSourceFile.h"
#include "cmLocalGenerator.h"
#include "cmGlobalGenerator.h"
#include "cmComputeLinkInformation.h"
#include "cmListFileCache.h"
#include "cmGeneratorExpression.h"
#include "cmGeneratorExpressionDAGChecker.h"
#include <cmsys/RegularExpression.hxx>
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#include <map>
#include <set>
#include <stdlib.h> // required for atof
#include <assert.h>
#include <errno.h>
const char* cmTarget::GetTargetTypeName(TargetType targetType)
{
switch( targetType )
{
case cmTarget::STATIC_LIBRARY:
return "STATIC_LIBRARY";
case cmTarget::MODULE_LIBRARY:
return "MODULE_LIBRARY";
case cmTarget::SHARED_LIBRARY:
return "SHARED_LIBRARY";
case cmTarget::OBJECT_LIBRARY:
return "OBJECT_LIBRARY";
case cmTarget::EXECUTABLE:
return "EXECUTABLE";
case cmTarget::UTILITY:
return "UTILITY";
case cmTarget::GLOBAL_TARGET:
return "GLOBAL_TARGET";
case cmTarget::INTERFACE_LIBRARY:
return "INTERFACE_LIBRARY";
case cmTarget::UNKNOWN_LIBRARY:
return "UNKNOWN_LIBRARY";
}
assert(0 && "Unexpected target type");
return 0;
}
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//----------------------------------------------------------------------------
struct cmTarget::OutputInfo
{
std::string OutDir;
std::string ImpDir;
std::string PdbDir;
};
//----------------------------------------------------------------------------
struct cmTarget::ImportInfo
{
bool NoSOName;
std::string Location;
std::string SOName;
std::string ImportLibrary;
cmTarget::LinkInterface LinkInterface;
};
//----------------------------------------------------------------------------
struct cmTarget::CompileInfo
{
std::string CompilePdbDir;
};
struct TargetConfigPair : public std::pair<cmTarget const* , std::string> {
TargetConfigPair(cmTarget const* tgt, const std::string &config)
: std::pair<cmTarget const* , std::string>(tgt, config) {}
};
//----------------------------------------------------------------------------
class cmTargetInternals
{
public:
cmTargetInternals()
{
this->PolicyWarnedCMP0022 = false;
}
cmTargetInternals(cmTargetInternals const&)
{
this->PolicyWarnedCMP0022 = false;
}
~cmTargetInternals();
// The backtrace when the target was created.
cmListFileBacktrace Backtrace;
// Cache link interface computation from each configuration.
struct OptionalLinkInterface: public cmTarget::LinkInterface
{
OptionalLinkInterface():
Exists(false), Complete(false), ExplicitLibraries(0) {}
bool Exists;
bool Complete;
const char* ExplicitLibraries;
};
void ComputeLinkInterface(cmTarget const* thisTarget,
const std::string& config,
OptionalLinkInterface& iface,
cmTarget const* head,
const char *explicitLibraries) const;
typedef std::map<TargetConfigPair, OptionalLinkInterface>
LinkInterfaceMapType;
LinkInterfaceMapType LinkInterfaceMap;
bool PolicyWarnedCMP0022;
typedef std::map<std::string, cmTarget::OutputInfo> OutputInfoMapType;
OutputInfoMapType OutputInfoMap;
typedef std::map<TargetConfigPair, cmTarget::ImportInfo>
ImportInfoMapType;
ImportInfoMapType ImportInfoMap;
typedef std::map<std::string, cmTarget::CompileInfo> CompileInfoMapType;
CompileInfoMapType CompileInfoMap;
// Cache link implementation computation from each configuration.
typedef std::map<TargetConfigPair,
cmTarget::LinkImplementation> LinkImplMapType;
LinkImplMapType LinkImplMap;
typedef std::map<TargetConfigPair, cmTarget::LinkClosure>
LinkClosureMapType;
LinkClosureMapType LinkClosureMap;
struct TargetPropertyEntry {
TargetPropertyEntry(cmsys::auto_ptr<cmCompiledGeneratorExpression> cge,
const std::string &targetName = std::string())
: ge(cge), TargetName(targetName)
{}
const cmsys::auto_ptr<cmCompiledGeneratorExpression> ge;
std::vector<std::string> CachedEntries;
const std::string TargetName;
};
std::vector<TargetPropertyEntry*> IncludeDirectoriesEntries;
std::vector<TargetPropertyEntry*> CompileOptionsEntries;
std::vector<TargetPropertyEntry*> CompileDefinitionsEntries;
std::vector<cmValueWithOrigin> LinkImplementationPropertyEntries;
mutable std::map<std::string, std::vector<TargetPropertyEntry*> >
CachedLinkInterfaceIncludeDirectoriesEntries;
mutable std::map<std::string, std::vector<TargetPropertyEntry*> >
CachedLinkInterfaceCompileOptionsEntries;
mutable std::map<std::string, std::vector<TargetPropertyEntry*> >
CachedLinkInterfaceCompileDefinitionsEntries;
mutable std::map<std::string, bool> CacheLinkInterfaceIncludeDirectoriesDone;
mutable std::map<std::string, bool> CacheLinkInterfaceCompileDefinitionsDone;
mutable std::map<std::string, bool> CacheLinkInterfaceCompileOptionsDone;
};
//----------------------------------------------------------------------------
void deleteAndClear(
std::vector<cmTargetInternals::TargetPropertyEntry*> &entries)
{
for (std::vector<cmTargetInternals::TargetPropertyEntry*>::const_iterator
it = entries.begin(),
end = entries.end();
it != end; ++it)
{
delete *it;
}
entries.clear();
}
//----------------------------------------------------------------------------
void deleteAndClear(
std::map<std::string,
std::vector<cmTargetInternals::TargetPropertyEntry*> > &entries)
{
for (std::map<std::string,
std::vector<cmTargetInternals::TargetPropertyEntry*> >::iterator
it = entries.begin(), end = entries.end(); it != end; ++it)
{
deleteAndClear(it->second);
}
}
//----------------------------------------------------------------------------
cmTargetInternals::~cmTargetInternals()
{
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deleteAndClear(this->CachedLinkInterfaceIncludeDirectoriesEntries);
deleteAndClear(this->CachedLinkInterfaceCompileOptionsEntries);
deleteAndClear(this->CachedLinkInterfaceCompileDefinitionsEntries);
}
//----------------------------------------------------------------------------
cmTarget::cmTarget()
{
#define INITIALIZE_TARGET_POLICY_MEMBER(POLICY) \
this->PolicyStatus ## POLICY = cmPolicies::WARN;
CM_FOR_EACH_TARGET_POLICY(INITIALIZE_TARGET_POLICY_MEMBER)
#undef INITIALIZE_TARGET_POLICY_MEMBER
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this->Makefile = 0;
this->LinkLibrariesAnalyzed = false;
this->HaveInstallRule = false;
this->DLLPlatform = false;
this->IsApple = false;
this->IsImportedTarget = false;
this->BuildInterfaceIncludesAppended = false;
this->DebugIncludesDone = false;
this->DebugCompileOptionsDone = false;
this->DebugCompileDefinitionsDone = false;
}
//----------------------------------------------------------------------------
void cmTarget::DefineProperties(cmake *cm)
{
cm->DefineProperty
("RULE_LAUNCH_COMPILE", cmProperty::TARGET,
"", "", true);
cm->DefineProperty
("RULE_LAUNCH_LINK", cmProperty::TARGET,
"", "", true);
cm->DefineProperty
("RULE_LAUNCH_CUSTOM", cmProperty::TARGET,
"", "", true);
}
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void cmTarget::SetType(TargetType type, const std::string& name)
{
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this->Name = name;
// only add dependency information for library targets
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this->TargetTypeValue = type;
if(this->TargetTypeValue >= STATIC_LIBRARY
&& this->TargetTypeValue <= MODULE_LIBRARY)
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{
this->RecordDependencies = true;
}
else
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{
this->RecordDependencies = false;
}
}
//----------------------------------------------------------------------------
void cmTarget::SetMakefile(cmMakefile* mf)
{
// Set our makefile.
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this->Makefile = mf;
// set the cmake instance of the properties
this->Properties.SetCMakeInstance(mf->GetCMakeInstance());
// Check whether this is a DLL platform.
this->DLLPlatform = (this->Makefile->IsOn("WIN32") ||
this->Makefile->IsOn("CYGWIN") ||
this->Makefile->IsOn("MINGW"));
// Check whether we are targeting an Apple platform.
this->IsApple = this->Makefile->IsOn("APPLE");
// Setup default property values.
if (this->GetType() != INTERFACE_LIBRARY)
{
this->SetPropertyDefault("INSTALL_NAME_DIR", 0);
this->SetPropertyDefault("INSTALL_RPATH", "");
this->SetPropertyDefault("INSTALL_RPATH_USE_LINK_PATH", "OFF");
this->SetPropertyDefault("SKIP_BUILD_RPATH", "OFF");
this->SetPropertyDefault("BUILD_WITH_INSTALL_RPATH", "OFF");
this->SetPropertyDefault("ARCHIVE_OUTPUT_DIRECTORY", 0);
this->SetPropertyDefault("LIBRARY_OUTPUT_DIRECTORY", 0);
this->SetPropertyDefault("RUNTIME_OUTPUT_DIRECTORY", 0);
this->SetPropertyDefault("PDB_OUTPUT_DIRECTORY", 0);
this->SetPropertyDefault("COMPILE_PDB_OUTPUT_DIRECTORY", 0);
this->SetPropertyDefault("Fortran_FORMAT", 0);
this->SetPropertyDefault("Fortran_MODULE_DIRECTORY", 0);
this->SetPropertyDefault("GNUtoMS", 0);
this->SetPropertyDefault("OSX_ARCHITECTURES", 0);
this->SetPropertyDefault("AUTOMOC", 0);
this->SetPropertyDefault("AUTOUIC", 0);
this->SetPropertyDefault("AUTORCC", 0);
this->SetPropertyDefault("AUTOMOC_MOC_OPTIONS", 0);
this->SetPropertyDefault("AUTOUIC_OPTIONS", 0);
this->SetPropertyDefault("AUTORCC_OPTIONS", 0);
this->SetPropertyDefault("LINK_DEPENDS_NO_SHARED", 0);
this->SetPropertyDefault("LINK_INTERFACE_LIBRARIES", 0);
this->SetPropertyDefault("WIN32_EXECUTABLE", 0);
this->SetPropertyDefault("MACOSX_BUNDLE", 0);
this->SetPropertyDefault("MACOSX_RPATH", 0);
this->SetPropertyDefault("NO_SYSTEM_FROM_IMPORTED", 0);
}
// Collect the set of configuration types.
std::vector<std::string> configNames;
mf->GetConfigurations(configNames);
// Setup per-configuration property default values.
const char* configProps[] = {
"ARCHIVE_OUTPUT_DIRECTORY_",
"LIBRARY_OUTPUT_DIRECTORY_",
"RUNTIME_OUTPUT_DIRECTORY_",
"PDB_OUTPUT_DIRECTORY_",
"COMPILE_PDB_OUTPUT_DIRECTORY_",
"MAP_IMPORTED_CONFIG_",
0};
for(std::vector<std::string>::iterator ci = configNames.begin();
ci != configNames.end(); ++ci)
{
std::string configUpper = cmSystemTools::UpperCase(*ci);
for(const char** p = configProps; *p; ++p)
{
if (this->TargetTypeValue == INTERFACE_LIBRARY
&& strcmp(*p, "MAP_IMPORTED_CONFIG_") != 0)
{
continue;
}
std::string property = *p;
property += configUpper;
this->SetPropertyDefault(property.c_str(), 0);
}
// Initialize per-configuration name postfix property from the
// variable only for non-executable targets. This preserves
// compatibility with previous CMake versions in which executables
// did not support this variable. Projects may still specify the
// property directly.
if(this->TargetTypeValue != cmTarget::EXECUTABLE
&& this->TargetTypeValue != cmTarget::INTERFACE_LIBRARY)
{
std::string property = cmSystemTools::UpperCase(*ci);
property += "_POSTFIX";
this->SetPropertyDefault(property.c_str(), 0);
}
}
// Save the backtrace of target construction.
this->Makefile->GetBacktrace(this->Internal->Backtrace);
if (!this->IsImported())
{
// Initialize the INCLUDE_DIRECTORIES property based on the current value
// of the same directory property:
const std::vector<cmValueWithOrigin> parentIncludes =
this->Makefile->GetIncludeDirectoriesEntries();
for (std::vector<cmValueWithOrigin>::const_iterator it
= parentIncludes.begin(); it != parentIncludes.end(); ++it)
{
this->InsertInclude(*it);
}
const std::set<std::string> parentSystemIncludes =
this->Makefile->GetSystemIncludeDirectories();
for (std::set<std::string>::const_iterator it
= parentSystemIncludes.begin();
it != parentSystemIncludes.end(); ++it)
{
this->SystemIncludeDirectories.insert(*it);
}
const std::vector<cmValueWithOrigin> parentOptions =
this->Makefile->GetCompileOptionsEntries();
for (std::vector<cmValueWithOrigin>::const_iterator it
= parentOptions.begin(); it != parentOptions.end(); ++it)
{
this->InsertCompileOption(*it);
}
}
if (this->GetType() != INTERFACE_LIBRARY)
{
this->SetPropertyDefault("C_VISIBILITY_PRESET", 0);
this->SetPropertyDefault("CXX_VISIBILITY_PRESET", 0);
this->SetPropertyDefault("VISIBILITY_INLINES_HIDDEN", 0);
}
if(this->TargetTypeValue == cmTarget::SHARED_LIBRARY
|| this->TargetTypeValue == cmTarget::MODULE_LIBRARY)
{
this->SetProperty("POSITION_INDEPENDENT_CODE", "True");
}
if (this->GetType() != INTERFACE_LIBRARY)
{
this->SetPropertyDefault("POSITION_INDEPENDENT_CODE", 0);
}
// Record current policies for later use.
#define CAPTURE_TARGET_POLICY(POLICY) \
this->PolicyStatus ## POLICY = \
this->Makefile->GetPolicyStatus(cmPolicies::POLICY);
CM_FOR_EACH_TARGET_POLICY(CAPTURE_TARGET_POLICY)
#undef CAPTURE_TARGET_POLICY
if (this->TargetTypeValue == INTERFACE_LIBRARY)
{
// This policy is checked in a few conditions. The properties relevant
// to the policy are always ignored for INTERFACE_LIBRARY targets,
// so ensure that the conditions don't lead to nonsense.
this->PolicyStatusCMP0022 = cmPolicies::NEW;
}
this->SetPropertyDefault("JOB_POOL_COMPILE", 0);
this->SetPropertyDefault("JOB_POOL_LINK", 0);
}
//----------------------------------------------------------------------------
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void cmTarget::AddUtility(const std::string& u, cmMakefile *makefile)
{
this->Utilities.insert(u);
if(makefile)
{
makefile->GetBacktrace(UtilityBacktraces[u]);
}
}
//----------------------------------------------------------------------------
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cmListFileBacktrace const* cmTarget::GetUtilityBacktrace(
const std::string& u) const
{
std::map<std::string, cmListFileBacktrace>::const_iterator i =
this->UtilityBacktraces.find(u);
if(i == this->UtilityBacktraces.end()) return 0;
return &i->second;
}
//----------------------------------------------------------------------------
void cmTarget::FinishConfigure()
{
// Erase any cached link information that might have been comptued
// on-demand during the configuration. This ensures that build
// system generation uses up-to-date information even if other cache
// invalidation code in this source file is buggy.
this->ClearLinkMaps();
// Do old-style link dependency analysis.
this->AnalyzeLibDependencies(*this->Makefile);
}
//----------------------------------------------------------------------------
void cmTarget::ClearLinkMaps()
{
this->Internal->LinkImplMap.clear();
this->Internal->LinkInterfaceMap.clear();
this->Internal->LinkClosureMap.clear();
for (cmTargetLinkInformationMap::const_iterator it
= this->LinkInformation.begin();
it != this->LinkInformation.end(); ++it)
{
delete it->second;
}
this->LinkInformation.clear();
}
//----------------------------------------------------------------------------
cmListFileBacktrace const& cmTarget::GetBacktrace() const
{
return this->Internal->Backtrace;
}
//----------------------------------------------------------------------------
std::string cmTarget::GetSupportDirectory() const
{
std::string dir = this->Makefile->GetCurrentOutputDirectory();
dir += cmake::GetCMakeFilesDirectory();
dir += "/";
dir += this->Name;
#if defined(__VMS)
dir += "_dir";
#else
dir += ".dir";
#endif
return dir;
}
//----------------------------------------------------------------------------
bool cmTarget::IsExecutableWithExports() const
{
return (this->GetType() == cmTarget::EXECUTABLE &&
this->GetPropertyAsBool("ENABLE_EXPORTS"));
}
//----------------------------------------------------------------------------
bool cmTarget::IsLinkable() const
{
return (this->GetType() == cmTarget::STATIC_LIBRARY ||
this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY ||
this->GetType() == cmTarget::UNKNOWN_LIBRARY ||
this->GetType() == cmTarget::INTERFACE_LIBRARY ||
this->IsExecutableWithExports());
}
//----------------------------------------------------------------------------
bool cmTarget::HasImportLibrary() const
{
return (this->DLLPlatform &&
(this->GetType() == cmTarget::SHARED_LIBRARY ||
this->IsExecutableWithExports()));
}
//----------------------------------------------------------------------------
bool cmTarget::IsFrameworkOnApple() const
{
return (this->GetType() == cmTarget::SHARED_LIBRARY &&
this->Makefile->IsOn("APPLE") &&
this->GetPropertyAsBool("FRAMEWORK"));
}
//----------------------------------------------------------------------------
bool cmTarget::IsAppBundleOnApple() const
{
return (this->GetType() == cmTarget::EXECUTABLE &&
this->Makefile->IsOn("APPLE") &&
this->GetPropertyAsBool("MACOSX_BUNDLE"));
}
//----------------------------------------------------------------------------
bool cmTarget::IsCFBundleOnApple() const
{
return (this->GetType() == cmTarget::MODULE_LIBRARY &&
this->Makefile->IsOn("APPLE") &&
this->GetPropertyAsBool("BUNDLE"));
}
//----------------------------------------------------------------------------
bool cmTarget::IsBundleOnApple() const
{
return this->IsFrameworkOnApple() || this->IsAppBundleOnApple() ||
this->IsCFBundleOnApple();
}
//----------------------------------------------------------------------------
void cmTarget::GetSourceFiles(std::vector<cmSourceFile*> &files) const
{
assert(this->GetType() != INTERFACE_LIBRARY);
for(std::vector<cmSourceFile*>::const_iterator
si = this->SourceFiles.begin();
si != this->SourceFiles.end(); ++si)
{
std::string e;
if((*si)->GetFullPath(&e).empty())
{
if(!e.empty())
{
cmake* cm = this->Makefile->GetCMakeInstance();
cm->IssueMessage(cmake::FATAL_ERROR, e,
this->GetBacktrace());
}
return;
}
}
files = this->SourceFiles;
}
//----------------------------------------------------------------------------
void cmTarget::AddSourceFile(cmSourceFile* sf)
{
if (std::find(this->SourceFiles.begin(), this->SourceFiles.end(), sf)
== this->SourceFiles.end())
{
this->SourceFiles.push_back(sf);
}
}
//----------------------------------------------------------------------------
void cmTarget::AddSources(std::vector<std::string> const& srcs)
{
for(std::vector<std::string>::const_iterator i = srcs.begin();
i != srcs.end(); ++i)
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{
const char* src = i->c_str();
if(src[0] == '$' && src[1] == '<')
{
this->ProcessSourceExpression(*i);
}
else
{
this->AddSource(src);
}
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}
}
//----------------------------------------------------------------------------
cmSourceFile* cmTarget::AddSource(const std::string& s)
{
std::string src = s;
// For backwards compatibility replace varibles in source names.
// This should eventually be removed.
this->Makefile->ExpandVariablesInString(src);
if (src != s)
{
cmOStringStream e;
bool noMessage = false;
cmake::MessageType messageType = cmake::AUTHOR_WARNING;
switch(this->Makefile->GetPolicyStatus(cmPolicies::CMP0049))
{
case cmPolicies::WARN:
e << (this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0049)) << "\n";
break;
case cmPolicies::OLD:
noMessage = true;
break;
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::NEW:
messageType = cmake::FATAL_ERROR;
}
if (!noMessage)
{
e << "Legacy variable expansion in source file \""
<< s << "\" expanded to \"" << src << "\" in target \""
<< this->GetName() << "\". This behavior will be removed in a "
"future version of CMake.";
this->Makefile->IssueMessage(messageType, e.str().c_str());
if (messageType == cmake::FATAL_ERROR)
{
return 0;
}
}
}
cmSourceFile* sf = this->Makefile->GetOrCreateSource(src.c_str());
this->AddSourceFile(sf);
return sf;
}
//----------------------------------------------------------------------------
void cmTarget::ProcessSourceExpression(std::string const& expr)
{
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if(cmHasLiteralPrefix(expr.c_str(), "$<TARGET_OBJECTS:") &&
expr[expr.size()-1] == '>')
{
std::string objLibName = expr.substr(17, expr.size()-18);
this->ObjectLibraries.push_back(objLibName);
}
else
{
cmOStringStream e;
e << "Unrecognized generator expression:\n"
<< " " << expr;
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str());
}
}
//----------------------------------------------------------------------------
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void cmTarget::MergeLinkLibraries( cmMakefile& mf,
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const std::string& selfname,
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const LinkLibraryVectorType& libs )
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{
// Only add on libraries we haven't added on before.
// Assumption: the global link libraries could only grow, never shrink
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LinkLibraryVectorType::const_iterator i = libs.begin();
i += this->PrevLinkedLibraries.size();
for( ; i != libs.end(); ++i )
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{
// This is equivalent to the target_link_libraries plain signature.
this->AddLinkLibrary( mf, selfname, i->first.c_str(), i->second );
this->AppendProperty("INTERFACE_LINK_LIBRARIES",
this->GetDebugGeneratorExpressions(i->first.c_str(), i->second).c_str());
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}
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this->PrevLinkedLibraries = libs;
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}
//----------------------------------------------------------------------------
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void cmTarget::AddLinkDirectory(const std::string& d)
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{
// Make sure we don't add unnecessary search directories.
if(this->LinkDirectoriesEmmitted.insert(d).second)
{
this->LinkDirectories.push_back(d);
}
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}
//----------------------------------------------------------------------------
const std::vector<std::string>& cmTarget::GetLinkDirectories() const
{
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return this->LinkDirectories;
}
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//----------------------------------------------------------------------------
cmTarget::LinkLibraryType cmTarget::ComputeLinkType(
const std::string& config) const
{
// No configuration is always optimized.
if(config.empty())
{
return cmTarget::OPTIMIZED;
}
// Get the list of configurations considered to be DEBUG.
std::vector<std::string> const& debugConfigs =
this->Makefile->GetCMakeInstance()->GetDebugConfigs();
// Check if any entry in the list matches this configuration.
std::string configUpper = cmSystemTools::UpperCase(config);
for(std::vector<std::string>::const_iterator i = debugConfigs.begin();
i != debugConfigs.end(); ++i)
{
if(*i == configUpper)
{
return cmTarget::DEBUG;
}
}
// The current configuration is not a debug configuration.
return cmTarget::OPTIMIZED;
}
//----------------------------------------------------------------------------
void cmTarget::ClearDependencyInformation( cmMakefile& mf,
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const std::string& target )
{
// Clear the dependencies. The cache variable must exist iff we are
// recording dependency information for this target.
std::string depname = target;
depname += "_LIB_DEPENDS";
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if (this->RecordDependencies)
{
mf.AddCacheDefinition(depname.c_str(), "",
"Dependencies for target", cmCacheManager::STATIC);
}
else
{
if (mf.GetDefinition( depname.c_str() ))
{
std::string message = "Target ";
message += target;
message += " has dependency information when it shouldn't.\n";
message += "Your cache is probably stale. Please remove the entry\n ";
message += depname;
message += "\nfrom the cache.";
cmSystemTools::Error( message.c_str() );
}
}
}
//----------------------------------------------------------------------------
bool cmTarget::NameResolvesToFramework(const std::string& libname) const
{
return this->Makefile->GetLocalGenerator()->GetGlobalGenerator()->
NameResolvesToFramework(libname);
}
//----------------------------------------------------------------------------
void cmTarget::GetDirectLinkLibraries(const std::string& config,
std::vector<std::string> &libs,
cmTarget const* head) const
{
const char *prop = this->GetProperty("LINK_LIBRARIES");
if (prop)
{
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
const cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(prop);
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
this->GetName(),
"LINK_LIBRARIES", 0, 0);
cmSystemTools::ExpandListArgument(cge->Evaluate(this->Makefile,
config,
false,
head,
&dagChecker),
libs);
std::set<std::string> seenProps = cge->GetSeenTargetProperties();
for (std::set<std::string>::const_iterator it = seenProps.begin();
it != seenProps.end(); ++it)
{
if (!this->GetProperty(it->c_str()))
{
this->LinkImplicitNullProperties.insert(*it);
}
}
}
}
//----------------------------------------------------------------------------
void cmTarget::GetInterfaceLinkLibraries(const std::string& config,
std::vector<std::string> &libs,
cmTarget const* head) const
{
const char *prop = this->GetProperty("INTERFACE_LINK_LIBRARIES");
if (prop)
{
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
const cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(prop);
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
this->GetName(),
"INTERFACE_LINK_LIBRARIES", 0, 0);
cmSystemTools::ExpandListArgument(cge->Evaluate(this->Makefile,
config,
false,
head,
&dagChecker),
libs);
}
}
//----------------------------------------------------------------------------
std::string cmTarget::GetDebugGeneratorExpressions(const std::string &value,
cmTarget::LinkLibraryType llt) const
{
if (llt == GENERAL)
{
return value;
}
// Get the list of configurations considered to be DEBUG.
std::vector<std::string> const& debugConfigs =
this->Makefile->GetCMakeInstance()->GetDebugConfigs();
std::string configString = "$<CONFIG:" + debugConfigs[0] + ">";
if (debugConfigs.size() > 1)
{
for(std::vector<std::string>::const_iterator
li = debugConfigs.begin() + 1; li != debugConfigs.end(); ++li)
{
configString += ",$<CONFIG:" + *li + ">";
}
configString = "$<OR:" + configString + ">";
}
if (llt == OPTIMIZED)
{
configString = "$<NOT:" + configString + ">";
}
return "$<" + configString + ":" + value + ">";
}
//----------------------------------------------------------------------------
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static std::string targetNameGenex(const std::string& lib)
{
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return "$<TARGET_NAME:" + lib + ">";
}
//----------------------------------------------------------------------------
bool cmTarget::PushTLLCommandTrace(TLLSignature signature)
{
bool ret = true;
if (!this->TLLCommands.empty())
{
if (this->TLLCommands.back().first != signature)
{
ret = false;
}
}
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
this->TLLCommands.push_back(std::make_pair(signature, lfbt));
return ret;
}
//----------------------------------------------------------------------------
void cmTarget::GetTllSignatureTraces(cmOStringStream &s,
TLLSignature sig) const
{
std::vector<cmListFileBacktrace> sigs;
typedef std::vector<std::pair<TLLSignature, cmListFileBacktrace> > Container;
for(Container::const_iterator it = this->TLLCommands.begin();
it != this->TLLCommands.end(); ++it)
{
if (it->first == sig)
{
sigs.push_back(it->second);
}
}
if (!sigs.empty())
{
const char *sigString
= (sig == cmTarget::KeywordTLLSignature ? "keyword"
: "plain");
s << "The uses of the " << sigString << " signature are here:\n";
std::set<std::string> emitted;
for(std::vector<cmListFileBacktrace>::const_iterator it = sigs.begin();
it != sigs.end(); ++it)
{
cmListFileBacktrace::const_iterator i = it->begin();
if(i != it->end())
{
cmListFileContext const& lfc = *i;
cmOStringStream line;
line << " * " << (lfc.Line? "": " in ") << lfc << std::endl;
if (emitted.insert(line.str()).second)
{
s << line.str();
}
++i;
}
}
}
}
//----------------------------------------------------------------------------
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void cmTarget::AddLinkLibrary(cmMakefile& mf,
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const std::string& target,
const std::string& lib,
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LinkLibraryType llt)
{
cmTarget *tgt = this->Makefile->FindTargetToUse(lib);
{
const bool isNonImportedTarget = tgt && !tgt->IsImported();
const std::string libName = (isNonImportedTarget && llt != GENERAL)
? targetNameGenex(lib)
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: lib;
this->AppendProperty("LINK_LIBRARIES",
this->GetDebugGeneratorExpressions(libName,
llt).c_str());
}
if (cmGeneratorExpression::Find(lib) != std::string::npos
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|| (tgt && tgt->GetType() == INTERFACE_LIBRARY)
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|| (target == lib ))
{
return;
}
cmTarget::LibraryID tmp;
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tmp.first = lib;
tmp.second = llt;
this->LinkLibraries.push_back( tmp );
this->OriginalLinkLibraries.push_back(tmp);
this->ClearLinkMaps();
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// Add the explicit dependency information for this target. This is
// simply a set of libraries separated by ";". There should always
// be a trailing ";". These library names are not canonical, in that
// they may be "-framework x", "-ly", "/path/libz.a", etc.
// We shouldn't remove duplicates here because external libraries
// may be purposefully duplicated to handle recursive dependencies,
// and we removing one instance will break the link line. Duplicates
// will be appropriately eliminated at emit time.
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if(this->RecordDependencies)
{
std::string targetEntry = target;
targetEntry += "_LIB_DEPENDS";
std::string dependencies;
const char* old_val = mf.GetDefinition( targetEntry.c_str() );
if( old_val )
{
dependencies += old_val;
}
switch (llt)
{
case cmTarget::GENERAL:
dependencies += "general";
break;
case cmTarget::DEBUG:
dependencies += "debug";
break;
case cmTarget::OPTIMIZED:
dependencies += "optimized";
break;
}
dependencies += ";";
dependencies += lib;
dependencies += ";";
mf.AddCacheDefinition( targetEntry.c_str(), dependencies.c_str(),
"Dependencies for the target",
cmCacheManager::STATIC );
}
}
//----------------------------------------------------------------------------
void
cmTarget::AddSystemIncludeDirectories(const std::set<std::string> &incs)
{
for(std::set<std::string>::const_iterator li = incs.begin();
li != incs.end(); ++li)
{
this->SystemIncludeDirectories.insert(*li);
}
}
//----------------------------------------------------------------------------
void
cmTarget::AddSystemIncludeDirectories(const std::vector<std::string> &incs)
{
for(std::vector<std::string>::const_iterator li = incs.begin();
li != incs.end(); ++li)
{
this->SystemIncludeDirectories.insert(*li);
}
}
//----------------------------------------------------------------------------
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void
cmTarget::AnalyzeLibDependencies( const cmMakefile& mf )
{
// There are two key parts of the dependency analysis: (1)
// determining the libraries in the link line, and (2) constructing
// the dependency graph for those libraries.
//
// The latter is done using the cache entries that record the
// dependencies of each library.
//
// The former is a more thorny issue, since it is not clear how to
// determine if two libraries listed on the link line refer to the a
// single library or not. For example, consider the link "libraries"
// /usr/lib/libtiff.so -ltiff
// Is this one library or two? The solution implemented here is the
// simplest (and probably the only practical) one: two libraries are
// the same if their "link strings" are identical. Thus, the two
// libraries above are considered distinct. This also means that for
// dependency analysis to be effective, the CMake user must specify
// libraries build by his project without using any linker flags or
// file extensions. That is,
// LINK_LIBRARIES( One Two )
// instead of
// LINK_LIBRARIES( -lOne ${binarypath}/libTwo.a )
// The former is probably what most users would do, but it never
// hurts to document the assumptions. :-) Therefore, in the analysis
// code, the "canonical name" of a library is simply its name as
// given to a LINK_LIBRARIES command.
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//
// Also, we will leave the original link line intact; we will just add any
// dependencies that were missing.
//
// There is a problem with recursive external libraries
// (i.e. libraries with no dependency information that are
// recursively dependent). We must make sure that the we emit one of
// the libraries twice to satisfy the recursion, but we shouldn't
// emit it more times than necessary. In particular, we must make
// sure that handling this improbable case doesn't cost us when
// dealing with the common case of non-recursive libraries. The
// solution is to assume that the recursion is satisfied at one node
// of the dependency tree. To illustrate, assume libA and libB are
// extrenal and mutually dependent. Suppose libX depends on
// libA, and libY on libA and libX. Then
// TARGET_LINK_LIBRARIES( Y X A B A )
// TARGET_LINK_LIBRARIES( X A B A )
// TARGET_LINK_LIBRARIES( Exec Y )
// would result in "-lY -lX -lA -lB -lA". This is the correct way to
// specify the dependencies, since the mutual dependency of A and B
// is resolved *every time libA is specified*.
//
// Something like
// TARGET_LINK_LIBRARIES( Y X A B A )
// TARGET_LINK_LIBRARIES( X A B )
// TARGET_LINK_LIBRARIES( Exec Y )
// would result in "-lY -lX -lA -lB", and the mutual dependency
// information is lost. This is because in some case (Y), the mutual
// dependency of A and B is listed, while in another other case (X),
// it is not. Depending on which line actually emits A, the mutual
// dependency may or may not be on the final link line. We can't
// handle this pathalogical case cleanly without emitting extra
// libraries for the normal cases. Besides, the dependency
// information for X is wrong anyway: if we build an executable
// depending on X alone, we would not have the mutual dependency on
// A and B resolved.
//
// IMPROVEMENTS:
// -- The current algorithm will not always pick the "optimal" link line
// when recursive dependencies are present. It will instead break the
// cycles at an aribtrary point. The majority of projects won't have
// cyclic dependencies, so this is probably not a big deal. Note that
// the link line is always correct, just not necessary optimal.
{
// Expand variables in link library names. This is for backwards
// compatibility with very early CMake versions and should
// eventually be removed. This code was moved here from the end of
// old source list processing code which was called just before this
// method.
for(LinkLibraryVectorType::iterator p = this->LinkLibraries.begin();
p != this->LinkLibraries.end(); ++p)
{
this->Makefile->ExpandVariablesInString(p->first, true, true);
}
}
// The dependency map.
DependencyMap dep_map;
// 1. Build the dependency graph
//
for(LinkLibraryVectorType::reverse_iterator lib
= this->LinkLibraries.rbegin();
lib != this->LinkLibraries.rend(); ++lib)
{
this->GatherDependencies( mf, *lib, dep_map);
}
// 2. Remove any dependencies that are already satisfied in the original
// link line.
//
for(LinkLibraryVectorType::iterator lib = this->LinkLibraries.begin();
lib != this->LinkLibraries.end(); ++lib)
{
for( LinkLibraryVectorType::iterator lib2 = lib;
lib2 != this->LinkLibraries.end(); ++lib2)
{
this->DeleteDependency( dep_map, *lib, *lib2);
}
}
// 3. Create the new link line by simply emitting any dependencies that are
// missing. Start from the back and keep adding.
//
std::set<DependencyMap::key_type> done, visited;
std::vector<DependencyMap::key_type> newLinkLibraries;
for(LinkLibraryVectorType::reverse_iterator lib =
this->LinkLibraries.rbegin();
lib != this->LinkLibraries.rend(); ++lib)
{
// skip zero size library entries, this may happen
// if a variable expands to nothing.
if (lib->first.size() != 0)
{
this->Emit( *lib, dep_map, done, visited, newLinkLibraries );
}
}
// 4. Add the new libraries to the link line.
//
for( std::vector<DependencyMap::key_type>::reverse_iterator k =
newLinkLibraries.rbegin();
k != newLinkLibraries.rend(); ++k )
{
// get the llt from the dep_map
this->LinkLibraries.push_back( std::make_pair(k->first,k->second) );
}
this->LinkLibrariesAnalyzed = true;
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}
//----------------------------------------------------------------------------
void cmTarget::InsertDependency( DependencyMap& depMap,
const LibraryID& lib,
const LibraryID& dep)
{
depMap[lib].push_back(dep);
}
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//----------------------------------------------------------------------------
void cmTarget::DeleteDependency( DependencyMap& depMap,
const LibraryID& lib,
const LibraryID& dep)
{
// Make sure there is an entry in the map for lib. If so, delete all
// dependencies to dep. There may be repeated entries because of
// external libraries that are specified multiple times.
DependencyMap::iterator map_itr = depMap.find( lib );
if( map_itr != depMap.end() )
{
DependencyList& depList = map_itr->second;
DependencyList::iterator itr;
while( (itr = std::find(depList.begin(), depList.end(), dep)) !=
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depList.end() )
{
depList.erase( itr );
}
}
}
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//----------------------------------------------------------------------------
void cmTarget::Emit(const LibraryID lib,
const DependencyMap& dep_map,
std::set<LibraryID>& emitted,
std::set<LibraryID>& visited,
DependencyList& link_line )
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{
// It's already been emitted
if( emitted.find(lib) != emitted.end() )
{
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return;
}
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// Emit the dependencies only if this library node hasn't been
// visited before. If it has, then we have a cycle. The recursion
// that got us here should take care of everything.
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if( visited.insert(lib).second )
{
if( dep_map.find(lib) != dep_map.end() ) // does it have dependencies?
{
const DependencyList& dep_on = dep_map.find( lib )->second;
DependencyList::const_reverse_iterator i;
// To cater for recursive external libraries, we must emit
// duplicates on this link line *unless* they were emitted by
// some other node, in which case we assume that the recursion
// was resolved then. We making the simplifying assumption that
// any duplicates on a single link line are on purpose, and must
// be preserved.
// This variable will keep track of the libraries that were
// emitted directly from the current node, and not from a
// recursive call. This way, if we come across a library that
// has already been emitted, we repeat it iff it has been
// emitted here.
std::set<DependencyMap::key_type> emitted_here;
for( i = dep_on.rbegin(); i != dep_on.rend(); ++i )
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{
if( emitted_here.find(*i) != emitted_here.end() )
{
// a repeat. Must emit.
emitted.insert(*i);
link_line.push_back( *i );
}
else
{
// Emit only if no-one else has
if( emitted.find(*i) == emitted.end() )
{
// emit dependencies
Emit( *i, dep_map, emitted, visited, link_line );
// emit self
emitted.insert(*i);
emitted_here.insert(*i);
link_line.push_back( *i );
}
}
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}
}
}
}
//----------------------------------------------------------------------------
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void cmTarget::GatherDependencies( const cmMakefile& mf,
const LibraryID& lib,
DependencyMap& dep_map)
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{
// If the library is already in the dependency map, then it has
// already been fully processed.
if( dep_map.find(lib) != dep_map.end() )
{
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return;
}
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const char* deps = mf.GetDefinition( (lib.first+"_LIB_DEPENDS").c_str() );
if( deps && strcmp(deps,"") != 0 )
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{
// 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 a set of
// type, library pairs separated by ";". There is always a trailing ";".
cmTarget::LinkLibraryType llt = cmTarget::GENERAL;
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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 )
{
if (l == "debug")
{
llt = cmTarget::DEBUG;
}
else if (l == "optimized")
{
llt = cmTarget::OPTIMIZED;
}
else if (l == "general")
{
llt = cmTarget::GENERAL;
}
else
{
LibraryID lib2(l,llt);
this->InsertDependency( dep_map, lib, lib2);
this->GatherDependencies( mf, lib2, dep_map);
llt = cmTarget::GENERAL;
}
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}
start = end+1; // skip the ;
end = depline.find( ";", start );
}
// cannot depend on itself
this->DeleteDependency( dep_map, lib, lib);
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}
}
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//----------------------------------------------------------------------------
static bool whiteListedInterfaceProperty(const std::string& prop)
{
if(cmHasLiteralPrefix(prop, "INTERFACE_"))
{
return true;
}
static const char* builtIns[] = {
// ###: This must remain sorted. It is processed with a binary search.
"COMPATIBLE_INTERFACE_BOOL",
"COMPATIBLE_INTERFACE_NUMBER_MAX",
"COMPATIBLE_INTERFACE_NUMBER_MIN",
"COMPATIBLE_INTERFACE_STRING",
"EXPORT_NAME",
"IMPORTED",
"NAME",
"TYPE"
};
if (std::binary_search(cmArrayBegin(builtIns),
cmArrayEnd(builtIns),
prop.c_str(),
2014-01-17 22:38:27 +04:00
cmStrCmp(prop)))
{
return true;
}
if (cmHasLiteralPrefix(prop, "MAP_IMPORTED_CONFIG_"))
{
return true;
}
return false;
}
//----------------------------------------------------------------------------
void cmTarget::SetProperty(const std::string& prop, const char* value)
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{
if (this->GetType() == INTERFACE_LIBRARY
&& !whiteListedInterfaceProperty(prop))
{
cmOStringStream e;
e << "INTERFACE_LIBRARY targets may only have whitelisted properties. "
"The property \"" << prop << "\" is not allowed.";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return;
}
if (prop == "NAME")
{
cmOStringStream e;
e << "NAME property is read-only\n";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return;
}
if(prop == "INCLUDE_DIRECTORIES")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmGeneratorExpression ge(lfbt);
deleteAndClear(this->Internal->IncludeDirectoriesEntries);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(value);
this->Internal->IncludeDirectoriesEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(cge));
return;
}
if(prop == "COMPILE_OPTIONS")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmGeneratorExpression ge(lfbt);
deleteAndClear(this->Internal->CompileOptionsEntries);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(value);
this->Internal->CompileOptionsEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(cge));
return;
}
if(prop == "COMPILE_DEFINITIONS")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmGeneratorExpression ge(lfbt);
deleteAndClear(this->Internal->CompileDefinitionsEntries);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(value);
this->Internal->CompileDefinitionsEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(cge));
return;
}
if(prop == "EXPORT_NAME" && this->IsImported())
{
cmOStringStream e;
e << "EXPORT_NAME property can't be set on imported targets (\""
<< this->Name << "\")\n";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return;
}
if (prop == "LINK_LIBRARIES")
{
this->Internal->LinkImplementationPropertyEntries.clear();
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmValueWithOrigin entry(value, lfbt);
this->Internal->LinkImplementationPropertyEntries.push_back(entry);
return;
}
this->Properties.SetProperty(prop, value, cmProperty::TARGET);
this->MaybeInvalidatePropertyCache(prop);
}
//----------------------------------------------------------------------------
void cmTarget::AppendProperty(const std::string& prop, const char* value,
bool asString)
{
if (this->GetType() == INTERFACE_LIBRARY
&& !whiteListedInterfaceProperty(prop))
{
cmOStringStream e;
e << "INTERFACE_LIBRARY targets may only have whitelisted properties. "
"The property \"" << prop << "\" is not allowed.";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return;
}
if (prop == "NAME")
{
cmOStringStream e;
e << "NAME property is read-only\n";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return;
}
if(prop == "INCLUDE_DIRECTORIES")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmGeneratorExpression ge(lfbt);
this->Internal->IncludeDirectoriesEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(ge.Parse(value)));
return;
}
if(prop == "COMPILE_OPTIONS")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmGeneratorExpression ge(lfbt);
this->Internal->CompileOptionsEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(ge.Parse(value)));
return;
}
if(prop == "COMPILE_DEFINITIONS")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmGeneratorExpression ge(lfbt);
this->Internal->CompileDefinitionsEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(ge.Parse(value)));
return;
}
if(prop == "EXPORT_NAME" && this->IsImported())
{
cmOStringStream e;
e << "EXPORT_NAME property can't be set on imported targets (\""
<< this->Name << "\")\n";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return;
}
if (prop == "LINK_LIBRARIES")
{
cmListFileBacktrace lfbt;
this->Makefile->GetBacktrace(lfbt);
cmValueWithOrigin entry(value, lfbt);
this->Internal->LinkImplementationPropertyEntries.push_back(entry);
return;
}
this->Properties.AppendProperty(prop, value, cmProperty::TARGET, asString);
this->MaybeInvalidatePropertyCache(prop);
}
//----------------------------------------------------------------------------
2014-02-07 02:31:47 +04:00
std::string cmTarget::GetExportName() const
{
const char *exportName = this->GetProperty("EXPORT_NAME");
if (exportName && *exportName)
{
if (!cmGeneratorExpression::IsValidTargetName(exportName))
{
cmOStringStream e;
e << "EXPORT_NAME property \"" << exportName << "\" for \""
<< this->GetName() << "\": is not valid.";
cmSystemTools::Error(e.str().c_str());
return "";
}
return exportName;
}
return this->GetName();
}
//----------------------------------------------------------------------------
void cmTarget::AppendBuildInterfaceIncludes()
{
if(this->GetType() != cmTarget::SHARED_LIBRARY &&
this->GetType() != cmTarget::STATIC_LIBRARY &&
this->GetType() != cmTarget::MODULE_LIBRARY &&
this->GetType() != cmTarget::INTERFACE_LIBRARY &&
!this->IsExecutableWithExports())
{
return;
}
if (this->BuildInterfaceIncludesAppended)
{
return;
}
this->BuildInterfaceIncludesAppended = true;
if (this->Makefile->IsOn("CMAKE_INCLUDE_CURRENT_DIR_IN_INTERFACE"))
{
const char *binDir = this->Makefile->GetStartOutputDirectory();
const char *srcDir = this->Makefile->GetStartDirectory();
const std::string dirs = std::string(binDir ? binDir : "")
+ std::string(binDir ? ";" : "")
+ std::string(srcDir ? srcDir : "");
if (!dirs.empty())
{
this->AppendProperty("INTERFACE_INCLUDE_DIRECTORIES",
("$<BUILD_INTERFACE:" + dirs + ">").c_str());
}
}
}
//----------------------------------------------------------------------------
void cmTarget::InsertInclude(const cmValueWithOrigin &entry,
bool before)
{
cmGeneratorExpression ge(entry.Backtrace);
std::vector<cmTargetInternals::TargetPropertyEntry*>::iterator position
= before ? this->Internal->IncludeDirectoriesEntries.begin()
: this->Internal->IncludeDirectoriesEntries.end();
this->Internal->IncludeDirectoriesEntries.insert(position,
new cmTargetInternals::TargetPropertyEntry(ge.Parse(entry.Value)));
}
//----------------------------------------------------------------------------
void cmTarget::InsertCompileOption(const cmValueWithOrigin &entry,
bool before)
{
cmGeneratorExpression ge(entry.Backtrace);
std::vector<cmTargetInternals::TargetPropertyEntry*>::iterator position
= before ? this->Internal->CompileOptionsEntries.begin()
: this->Internal->CompileOptionsEntries.end();
this->Internal->CompileOptionsEntries.insert(position,
new cmTargetInternals::TargetPropertyEntry(ge.Parse(entry.Value)));
}
//----------------------------------------------------------------------------
void cmTarget::InsertCompileDefinition(const cmValueWithOrigin &entry)
{
cmGeneratorExpression ge(entry.Backtrace);
this->Internal->CompileDefinitionsEntries.push_back(
new cmTargetInternals::TargetPropertyEntry(ge.Parse(entry.Value)));
}
//----------------------------------------------------------------------------
static void processIncludeDirectories(cmTarget const* tgt,
const std::vector<cmTargetInternals::TargetPropertyEntry*> &entries,
std::vector<std::string> &includes,
std::set<std::string> &uniqueIncludes,
cmGeneratorExpressionDAGChecker *dagChecker,
const std::string& config, bool debugIncludes)
{
cmMakefile *mf = tgt->GetMakefile();
for (std::vector<cmTargetInternals::TargetPropertyEntry*>::const_iterator
it = entries.begin(), end = entries.end(); it != end; ++it)
{
bool testIsOff = true;
bool cacheIncludes = false;
std::vector<std::string>& entryIncludes = (*it)->CachedEntries;
if(!entryIncludes.empty())
{
testIsOff = false;
}
else
{
cmSystemTools::ExpandListArgument((*it)->ge->Evaluate(mf,
config,
false,
tgt,
dagChecker),
entryIncludes);
if (mf->IsGeneratingBuildSystem()
&& !(*it)->ge->GetHadContextSensitiveCondition())
{
cacheIncludes = true;
}
}
std::string usedIncludes;
cmListFileBacktrace lfbt;
for(std::vector<std::string>::iterator
li = entryIncludes.begin(); li != entryIncludes.end(); ++li)
{
std::string targetName = (*it)->TargetName;
std::string evaluatedTargetName;
{
cmGeneratorExpression ge(lfbt);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge =
ge.Parse(targetName);
evaluatedTargetName = cge->Evaluate(mf, config, false, tgt, 0, 0);
}
cmTarget *dependentTarget = mf->FindTargetToUse(targetName);
const bool fromImported = dependentTarget
&& dependentTarget->IsImported();
cmTarget *evaluatedDependentTarget =
(targetName != evaluatedTargetName)
? mf->FindTargetToUse(evaluatedTargetName)
: 0;
targetName = evaluatedTargetName;
const bool fromEvaluatedImported = evaluatedDependentTarget
&& evaluatedDependentTarget->IsImported();
if ((fromImported || fromEvaluatedImported)
&& !cmSystemTools::FileExists(li->c_str()))
{
cmOStringStream e;
cmake::MessageType messageType = cmake::FATAL_ERROR;
if (fromEvaluatedImported)
{
switch(mf->GetPolicyStatus(cmPolicies::CMP0027))
{
case cmPolicies::WARN:
e << (mf->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0027)) << "\n";
case cmPolicies::OLD:
messageType = cmake::AUTHOR_WARNING;
break;
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::NEW:
break;
}
}
e << "Imported target \"" << targetName << "\" includes "
"non-existent path\n \"" << *li << "\"\nin its "
"INTERFACE_INCLUDE_DIRECTORIES. Possible reasons include:\n"
"* The path was deleted, renamed, or moved to another "
"location.\n"
"* An install or uninstall procedure did not complete "
"successfully.\n"
"* The installation package was faulty and references files it "
"does not provide.\n";
tgt->GetMakefile()->IssueMessage(messageType, e.str().c_str());
return;
}
if (!cmSystemTools::FileIsFullPath(li->c_str()))
{
cmOStringStream e;
bool noMessage = false;
cmake::MessageType messageType = cmake::FATAL_ERROR;
if (!targetName.empty())
{
e << "Target \"" << targetName << "\" contains relative "
"path in its INTERFACE_INCLUDE_DIRECTORIES:\n"
" \"" << *li << "\"";
}
else
{
switch(tgt->GetPolicyStatusCMP0021())
{
case cmPolicies::WARN:
{
e << (mf->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0021)) << "\n";
messageType = cmake::AUTHOR_WARNING;
}
break;
case cmPolicies::OLD:
noMessage = true;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::NEW:
// Issue the fatal message.
break;
}
e << "Found relative path while evaluating include directories of "
"\"" << tgt->GetName() << "\":\n \"" << *li << "\"\n";
}
if (!noMessage)
{
tgt->GetMakefile()->IssueMessage(messageType, e.str().c_str());
if (messageType == cmake::FATAL_ERROR)
{
return;
}
}
}
if (testIsOff && !cmSystemTools::IsOff(li->c_str()))
{
cmSystemTools::ConvertToUnixSlashes(*li);
}
std::string inc = *li;
if(uniqueIncludes.insert(inc).second)
{
includes.push_back(inc);
if (debugIncludes)
{
usedIncludes += " * " + inc + "\n";
}
}
}
if (cacheIncludes)
{
(*it)->CachedEntries = entryIncludes;
}
if (!usedIncludes.empty())
{
mf->GetCMakeInstance()->IssueMessage(cmake::LOG,
std::string("Used includes for target ")
+ tgt->GetName() + ":\n"
+ usedIncludes, (*it)->ge->GetBacktrace());
}
}
}
//----------------------------------------------------------------------------
std::vector<std::string>
cmTarget::GetIncludeDirectories(const std::string& config) const
{
std::vector<std::string> includes;
std::set<std::string> uniqueIncludes;
cmListFileBacktrace lfbt;
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
2013-05-27 19:45:47 +04:00
this->GetName(),
"INCLUDE_DIRECTORIES", 0, 0);
std::vector<std::string> debugProperties;
const char *debugProp =
this->Makefile->GetDefinition("CMAKE_DEBUG_TARGET_PROPERTIES");
if (debugProp)
{
cmSystemTools::ExpandListArgument(debugProp, debugProperties);
}
bool debugIncludes = !this->DebugIncludesDone
&& std::find(debugProperties.begin(),
debugProperties.end(),
"INCLUDE_DIRECTORIES")
!= debugProperties.end();
if (this->Makefile->IsGeneratingBuildSystem())
{
this->DebugIncludesDone = true;
}
processIncludeDirectories(this,
this->Internal->IncludeDirectoriesEntries,
includes,
uniqueIncludes,
&dagChecker,
config,
debugIncludes);
if (!this->Internal->CacheLinkInterfaceIncludeDirectoriesDone[config])
{
for (std::vector<cmValueWithOrigin>::const_iterator
it = this->Internal->LinkImplementationPropertyEntries.begin(),
end = this->Internal->LinkImplementationPropertyEntries.end();
it != end; ++it)
{
if (!cmGeneratorExpression::IsValidTargetName(it->Value)
&& cmGeneratorExpression::Find(it->Value) == std::string::npos)
{
continue;
}
{
cmGeneratorExpression ge(lfbt);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge =
ge.Parse(it->Value);
std::string result = cge->Evaluate(this->Makefile, config,
false, this, 0, 0);
if (!this->Makefile->FindTargetToUse(result))
{
continue;
}
}
std::string includeGenex = "$<TARGET_PROPERTY:" +
it->Value + ",INTERFACE_INCLUDE_DIRECTORIES>";
if (cmGeneratorExpression::Find(it->Value) != std::string::npos)
{
// Because it->Value is a generator expression, ensure that it
// evaluates to the non-empty string before being used in the
// TARGET_PROPERTY expression.
includeGenex = "$<$<BOOL:" + it->Value + ">:" + includeGenex + ">";
}
cmGeneratorExpression ge(it->Backtrace);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(
includeGenex);
this->Internal
->CachedLinkInterfaceIncludeDirectoriesEntries[config].push_back(
new cmTargetInternals::TargetPropertyEntry(cge,
it->Value));
}
if(this->Makefile->IsOn("APPLE"))
{
LinkImplementation const* impl = this->GetLinkImplementation(config,
this);
for(std::vector<std::string>::const_iterator
it = impl->Libraries.begin();
it != impl->Libraries.end(); ++it)
{
std::string libDir = cmSystemTools::CollapseFullPath(it->c_str());
static cmsys::RegularExpression
frameworkCheck("(.*\\.framework)(/Versions/[^/]+)?/[^/]+$");
if(!frameworkCheck.find(libDir))
{
continue;
}
libDir = frameworkCheck.match(1);
cmGeneratorExpression ge(lfbt);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge =
ge.Parse(libDir.c_str());
this->Internal
->CachedLinkInterfaceIncludeDirectoriesEntries[config]
.push_back(new cmTargetInternals::TargetPropertyEntry(cge));
}
}
}
processIncludeDirectories(this,
this->Internal->CachedLinkInterfaceIncludeDirectoriesEntries[config],
includes,
uniqueIncludes,
&dagChecker,
config,
debugIncludes);
if (!this->Makefile->IsGeneratingBuildSystem())
{
deleteAndClear(
this->Internal->CachedLinkInterfaceIncludeDirectoriesEntries);
}
else
{
this->Internal->CacheLinkInterfaceIncludeDirectoriesDone[config]
= true;
}
return includes;
}
//----------------------------------------------------------------------------
static void processCompileOptionsInternal(cmTarget const* tgt,
const std::vector<cmTargetInternals::TargetPropertyEntry*> &entries,
std::vector<std::string> &options,
std::set<std::string> &uniqueOptions,
cmGeneratorExpressionDAGChecker *dagChecker,
const std::string& config, bool debugOptions, const char *logName)
{
cmMakefile *mf = tgt->GetMakefile();
for (std::vector<cmTargetInternals::TargetPropertyEntry*>::const_iterator
it = entries.begin(), end = entries.end(); it != end; ++it)
{
bool cacheOptions = false;
std::vector<std::string> entryOptions = (*it)->CachedEntries;
if(entryOptions.empty())
{
cmSystemTools::ExpandListArgument((*it)->ge->Evaluate(mf,
config,
false,
tgt,
dagChecker),
entryOptions);
if (mf->IsGeneratingBuildSystem()
&& !(*it)->ge->GetHadContextSensitiveCondition())
{
cacheOptions = true;
}
}
std::string usedOptions;
for(std::vector<std::string>::iterator
li = entryOptions.begin(); li != entryOptions.end(); ++li)
{
std::string opt = *li;
if(uniqueOptions.insert(opt).second)
{
options.push_back(opt);
if (debugOptions)
{
usedOptions += " * " + opt + "\n";
}
}
}
if (cacheOptions)
{
(*it)->CachedEntries = entryOptions;
}
if (!usedOptions.empty())
{
mf->GetCMakeInstance()->IssueMessage(cmake::LOG,
std::string("Used compile ") + logName
+ std::string(" for target ")
+ tgt->GetName() + ":\n"
+ usedOptions, (*it)->ge->GetBacktrace());
}
}
}
//----------------------------------------------------------------------------
static void processCompileOptions(cmTarget const* tgt,
const std::vector<cmTargetInternals::TargetPropertyEntry*> &entries,
std::vector<std::string> &options,
std::set<std::string> &uniqueOptions,
cmGeneratorExpressionDAGChecker *dagChecker,
const std::string& config, bool debugOptions)
{
processCompileOptionsInternal(tgt, entries, options, uniqueOptions,
dagChecker, config, debugOptions, "options");
}
//----------------------------------------------------------------------------
void cmTarget::GetAutoUicOptions(std::vector<std::string> &result,
const std::string& config) const
{
const char *prop
= this->GetLinkInterfaceDependentStringProperty("AUTOUIC_OPTIONS",
config);
if (!prop)
{
return;
}
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
this->GetName(),
"AUTOUIC_OPTIONS", 0, 0);
cmSystemTools::ExpandListArgument(ge.Parse(prop)
->Evaluate(this->Makefile,
config,
false,
this,
&dagChecker),
result);
}
//----------------------------------------------------------------------------
void cmTarget::GetCompileOptions(std::vector<std::string> &result,
const std::string& config) const
{
std::set<std::string> uniqueOptions;
cmListFileBacktrace lfbt;
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
this->GetName(),
"COMPILE_OPTIONS", 0, 0);
std::vector<std::string> debugProperties;
const char *debugProp =
this->Makefile->GetDefinition("CMAKE_DEBUG_TARGET_PROPERTIES");
if (debugProp)
{
cmSystemTools::ExpandListArgument(debugProp, debugProperties);
}
bool debugOptions = !this->DebugCompileOptionsDone
&& std::find(debugProperties.begin(),
debugProperties.end(),
"COMPILE_OPTIONS")
!= debugProperties.end();
if (this->Makefile->IsGeneratingBuildSystem())
{
this->DebugCompileOptionsDone = true;
}
processCompileOptions(this,
this->Internal->CompileOptionsEntries,
result,
uniqueOptions,
&dagChecker,
config,
debugOptions);
if (!this->Internal->CacheLinkInterfaceCompileOptionsDone[config])
{
for (std::vector<cmValueWithOrigin>::const_iterator
it = this->Internal->LinkImplementationPropertyEntries.begin(),
end = this->Internal->LinkImplementationPropertyEntries.end();
it != end; ++it)
{
if (!cmGeneratorExpression::IsValidTargetName(it->Value)
&& cmGeneratorExpression::Find(it->Value) == std::string::npos)
{
continue;
}
{
cmGeneratorExpression ge(lfbt);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge =
ge.Parse(it->Value);
std::string targetResult = cge->Evaluate(this->Makefile, config,
false, this, 0, 0);
if (!this->Makefile->FindTargetToUse(targetResult))
{
continue;
}
}
std::string optionGenex = "$<TARGET_PROPERTY:" +
it->Value + ",INTERFACE_COMPILE_OPTIONS>";
if (cmGeneratorExpression::Find(it->Value) != std::string::npos)
{
// Because it->Value is a generator expression, ensure that it
// evaluates to the non-empty string before being used in the
// TARGET_PROPERTY expression.
optionGenex = "$<$<BOOL:" + it->Value + ">:" + optionGenex + ">";
}
cmGeneratorExpression ge(it->Backtrace);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(
optionGenex);
this->Internal
->CachedLinkInterfaceCompileOptionsEntries[config].push_back(
new cmTargetInternals::TargetPropertyEntry(cge,
it->Value));
}
}
processCompileOptions(this,
this->Internal->CachedLinkInterfaceCompileOptionsEntries[config],
result,
uniqueOptions,
&dagChecker,
config,
debugOptions);
if (!this->Makefile->IsGeneratingBuildSystem())
{
deleteAndClear(this->Internal->CachedLinkInterfaceCompileOptionsEntries);
}
else
{
this->Internal->CacheLinkInterfaceCompileOptionsDone[config] = true;
}
}
//----------------------------------------------------------------------------
static void processCompileDefinitions(cmTarget const* tgt,
const std::vector<cmTargetInternals::TargetPropertyEntry*> &entries,
std::vector<std::string> &options,
std::set<std::string> &uniqueOptions,
cmGeneratorExpressionDAGChecker *dagChecker,
const std::string& config, bool debugOptions)
{
processCompileOptionsInternal(tgt, entries, options, uniqueOptions,
dagChecker, config, debugOptions,
"definitions");
}
//----------------------------------------------------------------------------
void cmTarget::GetCompileDefinitions(std::vector<std::string> &list,
const std::string& config) const
{
std::set<std::string> uniqueOptions;
cmListFileBacktrace lfbt;
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
this->GetName(),
"COMPILE_DEFINITIONS", 0, 0);
std::vector<std::string> debugProperties;
const char *debugProp =
this->Makefile->GetDefinition("CMAKE_DEBUG_TARGET_PROPERTIES");
if (debugProp)
{
cmSystemTools::ExpandListArgument(debugProp, debugProperties);
}
bool debugDefines = !this->DebugCompileDefinitionsDone
&& std::find(debugProperties.begin(),
debugProperties.end(),
"COMPILE_DEFINITIONS")
!= debugProperties.end();
if (this->Makefile->IsGeneratingBuildSystem())
{
this->DebugCompileDefinitionsDone = true;
}
processCompileDefinitions(this,
this->Internal->CompileDefinitionsEntries,
list,
uniqueOptions,
&dagChecker,
config,
debugDefines);
if (!this->Internal->CacheLinkInterfaceCompileDefinitionsDone[config])
{
for (std::vector<cmValueWithOrigin>::const_iterator
it = this->Internal->LinkImplementationPropertyEntries.begin(),
end = this->Internal->LinkImplementationPropertyEntries.end();
it != end; ++it)
{
if (!cmGeneratorExpression::IsValidTargetName(it->Value)
&& cmGeneratorExpression::Find(it->Value) == std::string::npos)
{
continue;
}
{
cmGeneratorExpression ge(lfbt);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge =
ge.Parse(it->Value);
std::string targetResult = cge->Evaluate(this->Makefile, config,
false, this, 0, 0);
if (!this->Makefile->FindTargetToUse(targetResult))
{
continue;
}
}
std::string defsGenex = "$<TARGET_PROPERTY:" +
it->Value + ",INTERFACE_COMPILE_DEFINITIONS>";
if (cmGeneratorExpression::Find(it->Value) != std::string::npos)
{
// Because it->Value is a generator expression, ensure that it
// evaluates to the non-empty string before being used in the
// TARGET_PROPERTY expression.
defsGenex = "$<$<BOOL:" + it->Value + ">:" + defsGenex + ">";
}
cmGeneratorExpression ge(it->Backtrace);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge = ge.Parse(
defsGenex);
this->Internal
->CachedLinkInterfaceCompileDefinitionsEntries[config].push_back(
new cmTargetInternals::TargetPropertyEntry(cge,
it->Value));
}
if (!config.empty())
{
std::string configPropName = "COMPILE_DEFINITIONS_"
+ cmSystemTools::UpperCase(config);
const char *configProp = this->GetProperty(configPropName.c_str());
if (configProp)
{
switch(this->Makefile->GetPolicyStatus(cmPolicies::CMP0043))
{
case cmPolicies::WARN:
{
cmOStringStream e;
e << this->Makefile->GetCMakeInstance()->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0043);
this->Makefile->IssueMessage(cmake::AUTHOR_WARNING,
e.str().c_str());
}
case cmPolicies::OLD:
{
cmGeneratorExpression ge(lfbt);
cmsys::auto_ptr<cmCompiledGeneratorExpression> cge =
ge.Parse(configProp);
this->Internal
->CachedLinkInterfaceCompileDefinitionsEntries[config]
.push_back(new cmTargetInternals::TargetPropertyEntry(cge));
}
break;
case cmPolicies::NEW:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::REQUIRED_IF_USED:
break;
}
}
}
}
processCompileDefinitions(this,
this->Internal->CachedLinkInterfaceCompileDefinitionsEntries[config],
list,
uniqueOptions,
&dagChecker,
config,
debugDefines);
if (!this->Makefile->IsGeneratingBuildSystem())
{
deleteAndClear(this->Internal
->CachedLinkInterfaceCompileDefinitionsEntries);
}
else
{
this->Internal->CacheLinkInterfaceCompileDefinitionsDone[config]
= true;
}
}
//----------------------------------------------------------------------------
void cmTarget::MaybeInvalidatePropertyCache(const std::string& prop)
{
// Wipe out maps caching information affected by this property.
2013-11-20 05:12:00 +04:00
if(this->IsImported() && cmHasLiteralPrefix(prop, "IMPORTED"))
{
this->Internal->ImportInfoMap.clear();
}
2013-11-20 05:12:00 +04:00
if(!this->IsImported() && cmHasLiteralPrefix(prop, "LINK_INTERFACE_"))
{
this->ClearLinkMaps();
}
2002-12-21 01:15:45 +03:00
}
//----------------------------------------------------------------------------
static void cmTargetCheckLINK_INTERFACE_LIBRARIES(
const std::string& prop, const char* value, cmMakefile* context,
bool imported)
{
// Look for link-type keywords in the value.
static cmsys::RegularExpression
keys("(^|;)(debug|optimized|general)(;|$)");
if(!keys.find(value))
{
return;
}
// Support imported and non-imported versions of the property.
const char* base = (imported?
"IMPORTED_LINK_INTERFACE_LIBRARIES" :
"LINK_INTERFACE_LIBRARIES");
// Report an error.
cmOStringStream e;
e << "Property " << prop << " may not contain link-type keyword \""
<< keys.match(2) << "\". "
<< "The " << base << " property has a per-configuration "
<< "version called " << base << "_<CONFIG> which may be "
<< "used to specify per-configuration rules.";
if(!imported)
{
e << " "
<< "Alternatively, an IMPORTED library may be created, configured "
<< "with a per-configuration location, and then named in the "
<< "property value. "
<< "See the add_library command's IMPORTED mode for details."
<< "\n"
<< "If you have a list of libraries that already contains the "
<< "keyword, use the target_link_libraries command with its "
<< "LINK_INTERFACE_LIBRARIES mode to set the property. "
<< "The command automatically recognizes link-type keywords and sets "
<< "the LINK_INTERFACE_LIBRARIES and LINK_INTERFACE_LIBRARIES_DEBUG "
<< "properties accordingly.";
}
context->IssueMessage(cmake::FATAL_ERROR, e.str());
}
//----------------------------------------------------------------------------
static void cmTargetCheckINTERFACE_LINK_LIBRARIES(const char* value,
cmMakefile* context)
{
// Look for link-type keywords in the value.
static cmsys::RegularExpression
keys("(^|;)(debug|optimized|general)(;|$)");
if(!keys.find(value))
{
return;
}
// Report an error.
cmOStringStream e;
e << "Property INTERFACE_LINK_LIBRARIES may not contain link-type "
"keyword \"" << keys.match(2) << "\". The INTERFACE_LINK_LIBRARIES "
"property may contain configuration-sensitive generator-expressions "
"which may be used to specify per-configuration rules.";
context->IssueMessage(cmake::FATAL_ERROR, e.str());
}
//----------------------------------------------------------------------------
void cmTarget::CheckProperty(const std::string& prop,
cmMakefile* context) const
{
// Certain properties need checking.
2013-11-20 05:12:00 +04:00
if(cmHasLiteralPrefix(prop, "LINK_INTERFACE_LIBRARIES"))
{
if(const char* value = this->GetProperty(prop))
{
cmTargetCheckLINK_INTERFACE_LIBRARIES(prop, value, context, false);
}
}
2013-11-20 05:12:00 +04:00
if(cmHasLiteralPrefix(prop, "IMPORTED_LINK_INTERFACE_LIBRARIES"))
{
if(const char* value = this->GetProperty(prop))
{
cmTargetCheckLINK_INTERFACE_LIBRARIES(prop, value, context, true);
}
}
2013-11-20 05:12:00 +04:00
if(cmHasLiteralPrefix(prop, "INTERFACE_LINK_LIBRARIES"))
{
if(const char* value = this->GetProperty(prop))
{
cmTargetCheckINTERFACE_LINK_LIBRARIES(value, context);
}
}
}
//----------------------------------------------------------------------------
void cmTarget::MarkAsImported()
{
this->IsImportedTarget = true;
}
//----------------------------------------------------------------------------
bool cmTarget::HaveWellDefinedOutputFiles() const
{
return
this->GetType() == cmTarget::STATIC_LIBRARY ||
this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY ||
this->GetType() == cmTarget::EXECUTABLE;
}
//----------------------------------------------------------------------------
cmTarget::OutputInfo const* cmTarget::GetOutputInfo(
const std::string& config) const
{
// There is no output information for imported targets.
if(this->IsImported())
{
return 0;
}
// Only libraries and executables have well-defined output files.
if(!this->HaveWellDefinedOutputFiles())
{
std::string msg = "cmTarget::GetOutputInfo called for ";
msg += this->GetName();
msg += " which has type ";
msg += cmTarget::GetTargetTypeName(this->GetType());
this->GetMakefile()->IssueMessage(cmake::INTERNAL_ERROR, msg);
2009-07-10 17:12:39 +04:00
abort();
return 0;
}
// Lookup/compute/cache the output information for this configuration.
std::string config_upper;
if(!config.empty())
{
config_upper = cmSystemTools::UpperCase(config);
}
typedef cmTargetInternals::OutputInfoMapType OutputInfoMapType;
OutputInfoMapType::const_iterator i =
this->Internal->OutputInfoMap.find(config_upper);
if(i == this->Internal->OutputInfoMap.end())
{
OutputInfo info;
this->ComputeOutputDir(config, false, info.OutDir);
this->ComputeOutputDir(config, true, info.ImpDir);
if(!this->ComputePDBOutputDir("PDB", config, info.PdbDir))
{
info.PdbDir = info.OutDir;
}
OutputInfoMapType::value_type entry(config_upper, info);
i = this->Internal->OutputInfoMap.insert(entry).first;
}
return &i->second;
}
//----------------------------------------------------------------------------
cmTarget::CompileInfo const* cmTarget::GetCompileInfo(
const std::string& config) const
{
// There is no compile information for imported targets.
if(this->IsImported())
{
return 0;
}
if(this->GetType() > cmTarget::OBJECT_LIBRARY)
{
std::string msg = "cmTarget::GetCompileInfo called for ";
msg += this->GetName();
msg += " which has type ";
msg += cmTarget::GetTargetTypeName(this->GetType());
this->GetMakefile()->IssueMessage(cmake::INTERNAL_ERROR, msg);
abort();
return 0;
}
// Lookup/compute/cache the compile information for this configuration.
std::string config_upper;
if(!config.empty())
{
config_upper = cmSystemTools::UpperCase(config);
}
typedef cmTargetInternals::CompileInfoMapType CompileInfoMapType;
CompileInfoMapType::const_iterator i =
this->Internal->CompileInfoMap.find(config_upper);
if(i == this->Internal->CompileInfoMap.end())
{
CompileInfo info;
this->ComputePDBOutputDir("COMPILE_PDB", config, info.CompilePdbDir);
CompileInfoMapType::value_type entry(config_upper, info);
i = this->Internal->CompileInfoMap.insert(entry).first;
}
return &i->second;
}
//----------------------------------------------------------------------------
std::string cmTarget::GetDirectory(const std::string& config,
bool implib) const
{
if (this->IsImported())
{
// Return the directory from which the target is imported.
return
cmSystemTools::GetFilenamePath(
this->ImportedGetFullPath(config, implib));
}
else if(OutputInfo const* info = this->GetOutputInfo(config))
{
// Return the directory in which the target will be built.
return implib? info->ImpDir : info->OutDir;
}
return "";
}
//----------------------------------------------------------------------------
std::string cmTarget::GetPDBDirectory(const std::string& config) const
{
if(OutputInfo const* info = this->GetOutputInfo(config))
{
// Return the directory in which the target will be built.
return info->PdbDir;
}
return "";
}
//----------------------------------------------------------------------------
std::string cmTarget::GetCompilePDBDirectory(const std::string& config) const
{
if(CompileInfo const* info = this->GetCompileInfo(config))
{
return info->CompilePdbDir;
}
return "";
}
//----------------------------------------------------------------------------
const char* cmTarget::GetLocation(const std::string& config) const
{
static std::string location;
if (this->IsImported())
{
location = this->ImportedGetFullPath(config, false);
}
else
{
location = this->GetFullPath(config, false);
}
return location.c_str();
}
//----------------------------------------------------------------------------
const char* cmTarget::GetLocationForBuild() const
{
static std::string location;
if(this->IsImported())
{
location = this->ImportedGetFullPath("", false);
return location.c_str();
}
// Now handle the deprecated build-time configuration location.
location = this->GetDirectory();
if(!location.empty())
{
location += "/";
}
const char* cfgid = this->Makefile->GetDefinition("CMAKE_CFG_INTDIR");
if(cfgid && strcmp(cfgid, ".") != 0)
{
location += "/";
location += cfgid;
location += "/";
}
if(this->IsAppBundleOnApple())
{
std::string macdir = this->BuildMacContentDirectory("", "", false);
if(!macdir.empty())
{
location += "/";
location += macdir;
}
}
location += "/";
location += this->GetFullName("", false);
return location.c_str();
}
//----------------------------------------------------------------------------
void cmTarget::GetTargetVersion(int& major, int& minor) const
{
int patch;
this->GetTargetVersion(false, major, minor, patch);
}
//----------------------------------------------------------------------------
void cmTarget::GetTargetVersion(bool soversion,
int& major, int& minor, int& patch) const
{
// Set the default values.
major = 0;
minor = 0;
patch = 0;
assert(this->GetType() != INTERFACE_LIBRARY);
// Look for a VERSION or SOVERSION property.
const char* prop = soversion? "SOVERSION" : "VERSION";
if(const char* version = this->GetProperty(prop))
{
// Try to parse the version number and store the results that were
// successfully parsed.
int parsed_major;
int parsed_minor;
int parsed_patch;
switch(sscanf(version, "%d.%d.%d",
&parsed_major, &parsed_minor, &parsed_patch))
{
case 3: patch = parsed_patch; // no break!
case 2: minor = parsed_minor; // no break!
case 1: major = parsed_major; // no break!
default: break;
}
}
}
//----------------------------------------------------------------------------
const char* cmTarget::GetFeature(const std::string& feature,
const std::string& config) const
{
if(!config.empty())
{
std::string featureConfig = feature;
featureConfig += "_";
featureConfig += cmSystemTools::UpperCase(config);
if(const char* value = this->GetProperty(featureConfig.c_str()))
{
return value;
}
}
if(const char* value = this->GetProperty(feature))
{
return value;
}
return this->Makefile->GetFeature(feature, config);
}
//----------------------------------------------------------------------------
const char *cmTarget::GetProperty(const std::string& prop) const
{
return this->GetProperty(prop, cmProperty::TARGET);
}
//----------------------------------------------------------------------------
bool cmTarget::HandleLocationPropertyPolicy() const
{
if (this->IsImported())
{
return true;
}
const char *modal = 0;
cmake::MessageType messageType = cmake::AUTHOR_WARNING;
switch (this->Makefile->GetPolicyStatus(cmPolicies::CMP0026))
{
case cmPolicies::WARN:
modal = "should";
case cmPolicies::OLD:
break;
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::NEW:
modal = "may";
messageType = cmake::FATAL_ERROR;
}
if (modal)
{
cmOStringStream e;
e << (this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0026)) << "\n";
e << "The LOCATION property " << modal << " not be read from target \""
<< this->GetName() << "\". Use the target name directly with "
"add_custom_command, or use the generator expression $<TARGET_FILE>, "
"as appropriate.\n";
this->Makefile->IssueMessage(messageType, e.str().c_str());
}
return messageType != cmake::FATAL_ERROR;
}
//----------------------------------------------------------------------------
const char *cmTarget::GetProperty(const std::string& prop,
cmProperty::ScopeType scope) const
{
if (this->GetType() == INTERFACE_LIBRARY
&& !whiteListedInterfaceProperty(prop))
{
cmOStringStream e;
e << "INTERFACE_LIBRARY targets may only have whitelisted properties. "
"The property \"" << prop << "\" is not allowed.";
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str().c_str());
return 0;
}
if (prop == "NAME")
{
2014-02-07 02:31:47 +04:00
return this->GetName().c_str();
}
// Watch for special "computed" properties that are dependent on
// other properties or variables. Always recompute them.
if(this->GetType() == cmTarget::EXECUTABLE ||
this->GetType() == cmTarget::STATIC_LIBRARY ||
this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY ||
this->GetType() == cmTarget::UNKNOWN_LIBRARY)
{
if(prop == "LOCATION")
{
if (!this->HandleLocationPropertyPolicy())
{
return 0;
}
// Set the LOCATION property of the target.
//
// For an imported target this is the location of an arbitrary
// available configuration.
//
// For a non-imported target this is deprecated because it
// cannot take into account the per-configuration name of the
// target because the configuration type may not be known at
// CMake time.
this->Properties.SetProperty("LOCATION", this->GetLocationForBuild(),
cmProperty::TARGET);
}
// Support "LOCATION_<CONFIG>".
2013-11-20 05:12:00 +04:00
if(cmHasLiteralPrefix(prop, "LOCATION_"))
{
if (!this->HandleLocationPropertyPolicy())
{
return 0;
}
const char* configName = prop.c_str() + 9;
this->Properties.SetProperty(prop,
this->GetLocation(configName),
cmProperty::TARGET);
}
}
if(prop == "INCLUDE_DIRECTORIES")
{
static std::string output;
output = "";
std::string sep;
typedef cmTargetInternals::TargetPropertyEntry
TargetPropertyEntry;
for (std::vector<TargetPropertyEntry*>::const_iterator
it = this->Internal->IncludeDirectoriesEntries.begin(),
end = this->Internal->IncludeDirectoriesEntries.end();
it != end; ++it)
{
output += sep;
output += (*it)->ge->GetInput();
sep = ";";
}
return output.c_str();
}
if(prop == "COMPILE_OPTIONS")
{
static std::string output;
output = "";
std::string sep;
typedef cmTargetInternals::TargetPropertyEntry
TargetPropertyEntry;
for (std::vector<TargetPropertyEntry*>::const_iterator
it = this->Internal->CompileOptionsEntries.begin(),
end = this->Internal->CompileOptionsEntries.end();
it != end; ++it)
{
output += sep;
output += (*it)->ge->GetInput();
sep = ";";
}
return output.c_str();
}
if(prop == "COMPILE_DEFINITIONS")
{
static std::string output;
output = "";
std::string sep;
typedef cmTargetInternals::TargetPropertyEntry
TargetPropertyEntry;
for (std::vector<TargetPropertyEntry*>::const_iterator
it = this->Internal->CompileDefinitionsEntries.begin(),
end = this->Internal->CompileDefinitionsEntries.end();
it != end; ++it)
{
output += sep;
output += (*it)->ge->GetInput();
sep = ";";
}
return output.c_str();
}
if(prop == "LINK_LIBRARIES")
{
static std::string output;
output = "";
std::string sep;
for (std::vector<cmValueWithOrigin>::const_iterator
it = this->Internal->LinkImplementationPropertyEntries.begin(),
end = this->Internal->LinkImplementationPropertyEntries.end();
it != end; ++it)
{
output += sep;
output += it->Value;
sep = ";";
}
return output.c_str();
}
if (prop == "IMPORTED")
{
return this->IsImported()?"TRUE":"FALSE";
}
2007-02-19 21:20:27 +03:00
if(prop == "SOURCES")
{
cmOStringStream ss;
const char* sep = "";
for(std::vector<cmSourceFile*>::const_iterator
i = this->SourceFiles.begin();
i != this->SourceFiles.end(); ++i)
{
// Separate from the previous list entries.
ss << sep;
sep = ";";
// Construct what is known about this source file location.
cmSourceFileLocation const& location = (*i)->GetLocation();
std::string sname = location.GetDirectory();
if(!sname.empty())
{
sname += "/";
}
sname += location.GetName();
// Append this list entry.
ss << sname;
}
this->Properties.SetProperty("SOURCES", ss.str().c_str(),
cmProperty::TARGET);
}
// the type property returns what type the target is
if (prop == "TYPE")
{
return cmTarget::GetTargetTypeName(this->GetType());
}
bool chain = false;
const char *retVal =
this->Properties.GetPropertyValue(prop, scope, chain);
if (chain)
2002-12-21 01:15:45 +03:00
{
return this->Makefile->GetProperty(prop,scope);
2002-12-21 01:15:45 +03:00
}
return retVal;
2002-12-21 01:15:45 +03:00
}
//----------------------------------------------------------------------------
bool cmTarget::GetPropertyAsBool(const std::string& prop) const
2002-12-21 01:15:45 +03:00
{
return cmSystemTools::IsOn(this->GetProperty(prop));
2002-12-21 01:15:45 +03:00
}
//----------------------------------------------------------------------------
class cmTargetCollectLinkLanguages
{
public:
cmTargetCollectLinkLanguages(cmTarget const* target,
const std::string& config,
std::set<std::string>& languages,
cmTarget const* head):
Config(config), Languages(languages), HeadTarget(head),
Makefile(target->GetMakefile()), Target(target)
{ this->Visited.insert(target); }
void Visit(const std::string& name)
{
cmTarget *target = this->Makefile->FindTargetToUse(name);
if(!target)
{
if(name.find("::") != std::string::npos)
{
bool noMessage = false;
cmake::MessageType messageType = cmake::FATAL_ERROR;
cmOStringStream e;
switch(this->Makefile->GetPolicyStatus(cmPolicies::CMP0028))
{
case cmPolicies::WARN:
{
e << (this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0028)) << "\n";
messageType = cmake::AUTHOR_WARNING;
}
break;
case cmPolicies::OLD:
noMessage = true;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::NEW:
// Issue the fatal message.
break;
}
if(!noMessage)
{
e << "Target \"" << this->Target->GetName()
<< "\" links to target \"" << name
<< "\" but the target was not found. Perhaps a find_package() "
"call is missing for an IMPORTED target, or an ALIAS target is "
"missing?";
this->Makefile->GetCMakeInstance()->IssueMessage(messageType,
e.str(),
this->Target->GetBacktrace());
}
}
return;
}
if(!this->Visited.insert(target).second)
{
return;
}
cmTarget::LinkInterface const* iface =
target->GetLinkInterface(this->Config, this->HeadTarget);
if(!iface) { return; }
for(std::vector<std::string>::const_iterator
li = iface->Languages.begin(); li != iface->Languages.end(); ++li)
{
this->Languages.insert(*li);
}
for(std::vector<std::string>::const_iterator
li = iface->Libraries.begin(); li != iface->Libraries.end(); ++li)
{
this->Visit(*li);
}
}
private:
std::string Config;
std::set<std::string>& Languages;
cmTarget const* HeadTarget;
cmMakefile* Makefile;
const cmTarget* Target;
std::set<cmTarget const*> Visited;
};
//----------------------------------------------------------------------------
std::string cmTarget::GetLinkerLanguage(const std::string& config,
cmTarget const* head) const
{
cmTarget const* headTarget = head ? head : this;
return this->GetLinkClosure(config, headTarget)->LinkerLanguage;
}
//----------------------------------------------------------------------------
cmTarget::LinkClosure const* cmTarget::GetLinkClosure(
const std::string& config,
cmTarget const* head) const
{
TargetConfigPair key(head, cmSystemTools::UpperCase(config));
cmTargetInternals::LinkClosureMapType::iterator
i = this->Internal->LinkClosureMap.find(key);
if(i == this->Internal->LinkClosureMap.end())
{
LinkClosure lc;
this->ComputeLinkClosure(config, lc, head);
cmTargetInternals::LinkClosureMapType::value_type entry(key, lc);
i = this->Internal->LinkClosureMap.insert(entry).first;
}
return &i->second;
}
//----------------------------------------------------------------------------
class cmTargetSelectLinker
{
int Preference;
cmTarget const* Target;
cmMakefile* Makefile;
cmGlobalGenerator* GG;
std::set<std::string> Preferred;
public:
cmTargetSelectLinker(cmTarget const* target): Preference(0), Target(target)
{
this->Makefile = this->Target->GetMakefile();
this->GG = this->Makefile->GetLocalGenerator()->GetGlobalGenerator();
}
void Consider(const std::string& lang)
{
int preference = this->GG->GetLinkerPreference(lang);
if(preference > this->Preference)
{
this->Preference = preference;
this->Preferred.clear();
}
if(preference == this->Preference)
{
this->Preferred.insert(lang);
}
}
std::string Choose()
{
if(this->Preferred.empty())
{
return "";
}
else if(this->Preferred.size() > 1)
{
cmOStringStream e;
e << "Target " << this->Target->GetName()
<< " contains multiple languages with the highest linker preference"
<< " (" << this->Preference << "):\n";
for(std::set<std::string>::const_iterator
li = this->Preferred.begin(); li != this->Preferred.end(); ++li)
{
e << " " << *li << "\n";
}
e << "Set the LINKER_LANGUAGE property for this target.";
cmake* cm = this->Makefile->GetCMakeInstance();
cm->IssueMessage(cmake::FATAL_ERROR, e.str(),
this->Target->GetBacktrace());
}
return *this->Preferred.begin();
}
};
//----------------------------------------------------------------------------
void cmTarget::ComputeLinkClosure(const std::string& config, LinkClosure& lc,
cmTarget const* head) const
{
// Get languages built in this target.
std::set<std::string> languages;
LinkImplementation const* impl = this->GetLinkImplementation(config, head);
for(std::vector<std::string>::const_iterator li = impl->Languages.begin();
li != impl->Languages.end(); ++li)
{
languages.insert(*li);
}
// Add interface languages from linked targets.
cmTargetCollectLinkLanguages cll(this, config, languages, head);
for(std::vector<std::string>::const_iterator li = impl->Libraries.begin();
li != impl->Libraries.end(); ++li)
{
cll.Visit(*li);
}
// Store the transitive closure of languages.
for(std::set<std::string>::const_iterator li = languages.begin();
li != languages.end(); ++li)
{
lc.Languages.push_back(*li);
}
// Choose the language whose linker should be used.
if(this->GetProperty("HAS_CXX"))
{
lc.LinkerLanguage = "CXX";
}
else if(const char* linkerLang = this->GetProperty("LINKER_LANGUAGE"))
{
lc.LinkerLanguage = linkerLang;
}
else
{
// Find the language with the highest preference value.
cmTargetSelectLinker tsl(this);
// First select from the languages compiled directly in this target.
for(std::vector<std::string>::const_iterator li = impl->Languages.begin();
li != impl->Languages.end(); ++li)
{
tsl.Consider(li->c_str());
}
// Now consider languages that propagate from linked targets.
for(std::set<std::string>::const_iterator sit = languages.begin();
sit != languages.end(); ++sit)
{
std::string propagates = "CMAKE_"+*sit+"_LINKER_PREFERENCE_PROPAGATES";
if(this->Makefile->IsOn(propagates.c_str()))
{
tsl.Consider(sit->c_str());
}
}
lc.LinkerLanguage = tsl.Choose();
}
}
//----------------------------------------------------------------------------
const char* cmTarget::GetSuffixVariableInternal(bool implib) const
{
switch(this->GetType())
{
case cmTarget::STATIC_LIBRARY:
return "CMAKE_STATIC_LIBRARY_SUFFIX";
case cmTarget::SHARED_LIBRARY:
return (implib
? "CMAKE_IMPORT_LIBRARY_SUFFIX"
: "CMAKE_SHARED_LIBRARY_SUFFIX");
case cmTarget::MODULE_LIBRARY:
return (implib
? "CMAKE_IMPORT_LIBRARY_SUFFIX"
: "CMAKE_SHARED_MODULE_SUFFIX");
case cmTarget::EXECUTABLE:
return (implib
? "CMAKE_IMPORT_LIBRARY_SUFFIX"
: "CMAKE_EXECUTABLE_SUFFIX");
default:
break;
}
return "";
}
//----------------------------------------------------------------------------
const char* cmTarget::GetPrefixVariableInternal(bool implib) const
{
switch(this->GetType())
{
case cmTarget::STATIC_LIBRARY:
return "CMAKE_STATIC_LIBRARY_PREFIX";
case cmTarget::SHARED_LIBRARY:
return (implib
? "CMAKE_IMPORT_LIBRARY_PREFIX"
: "CMAKE_SHARED_LIBRARY_PREFIX");
case cmTarget::MODULE_LIBRARY:
return (implib
? "CMAKE_IMPORT_LIBRARY_PREFIX"
: "CMAKE_SHARED_MODULE_PREFIX");
case cmTarget::EXECUTABLE:
return (implib? "CMAKE_IMPORT_LIBRARY_PREFIX" : "");
default:
break;
}
return "";
}
//----------------------------------------------------------------------------
std::string cmTarget::GetPDBName(const std::string& config) const
{
std::string prefix;
std::string base;
std::string suffix;
this->GetFullNameInternal(config, false, prefix, base, suffix);
std::vector<std::string> props;
std::string configUpper = cmSystemTools::UpperCase(config);
if(!configUpper.empty())
{
// PDB_NAME_<CONFIG>
props.push_back("PDB_NAME_" + configUpper);
}
// PDB_NAME
props.push_back("PDB_NAME");
for(std::vector<std::string>::const_iterator i = props.begin();
i != props.end(); ++i)
{
if(const char* outName = this->GetProperty(i->c_str()))
{
base = outName;
break;
}
}
return prefix+base+".pdb";
}
//----------------------------------------------------------------------------
std::string cmTarget::GetCompilePDBName(const std::string& config) const
{
std::string prefix;
std::string base;
std::string suffix;
this->GetFullNameInternal(config, false, prefix, base, suffix);
// Check for a per-configuration output directory target property.
std::string configUpper = cmSystemTools::UpperCase(config);
std::string configProp = "COMPILE_PDB_NAME_";
configProp += configUpper;
const char* config_name = this->GetProperty(configProp.c_str());
if(config_name && *config_name)
{
return prefix + config_name + ".pdb";
}
const char* name = this->GetProperty("COMPILE_PDB_NAME");
if(name && *name)
{
return prefix + name + ".pdb";
}
return "";
}
//----------------------------------------------------------------------------
std::string cmTarget::GetCompilePDBPath(const std::string& config) const
{
std::string dir = this->GetCompilePDBDirectory(config);
std::string name = this->GetCompilePDBName(config);
if(dir.empty() && !name.empty())
{
dir = this->GetPDBDirectory(config);
}
if(!dir.empty())
{
dir += "/";
}
return dir + name;
}
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
//----------------------------------------------------------------------------
bool cmTarget::HasSOName(const std::string& config) const
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
{
// soname is supported only for shared libraries and modules,
// and then only when the platform supports an soname flag.
return ((this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY) &&
!this->GetPropertyAsBool("NO_SONAME") &&
this->Makefile->GetSONameFlag(this->GetLinkerLanguage(config,
this)));
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
}
//----------------------------------------------------------------------------
std::string cmTarget::GetSOName(const std::string& config) const
{
if(this->IsImported())
{
// Lookup the imported soname.
if(cmTarget::ImportInfo const* info = this->GetImportInfo(config, this))
{
if(info->NoSOName)
{
// The imported library has no builtin soname so the name
// searched at runtime will be just the filename.
return cmSystemTools::GetFilenameName(info->Location);
}
else
{
// Use the soname given if any.
if(info->SOName.find("@rpath/") == 0)
{
return info->SOName.substr(6);
}
return info->SOName;
}
}
else
{
return "";
}
}
else
{
// Compute the soname that will be built.
std::string name;
std::string soName;
std::string realName;
std::string impName;
std::string pdbName;
this->GetLibraryNames(name, soName, realName, impName, pdbName, config);
return soName;
}
}
//----------------------------------------------------------------------------
bool cmTarget::HasMacOSXRpathInstallNameDir(const std::string& config) const
{
bool install_name_is_rpath = false;
bool macosx_rpath = false;
if(!this->IsImportedTarget)
{
if(this->GetType() != cmTarget::SHARED_LIBRARY)
{
return false;
}
const char* install_name = this->GetProperty("INSTALL_NAME_DIR");
bool use_install_name =
this->GetPropertyAsBool("BUILD_WITH_INSTALL_RPATH");
if(install_name && use_install_name &&
std::string(install_name) == "@rpath")
{
install_name_is_rpath = true;
}
else if(install_name && use_install_name)
{
return false;
}
if(!install_name_is_rpath)
{
macosx_rpath = this->MacOSXRpathInstallNameDirDefault();
}
}
else
{
// Lookup the imported soname.
if(cmTarget::ImportInfo const* info = this->GetImportInfo(config, this))
{
if(!info->NoSOName && !info->SOName.empty())
{
if(info->SOName.find("@rpath/") == 0)
{
install_name_is_rpath = true;
}
}
else
{
std::string install_name;
cmSystemTools::GuessLibraryInstallName(info->Location, install_name);
if(install_name.find("@rpath") != std::string::npos)
{
install_name_is_rpath = true;
}
}
}
}
if(!install_name_is_rpath && !macosx_rpath)
{
return false;
}
if(!this->Makefile->IsSet("CMAKE_SHARED_LIBRARY_RUNTIME_C_FLAG"))
{
cmOStringStream w;
w << "Attempting to use";
if(macosx_rpath)
{
w << " MACOSX_RPATH";
}
else
{
w << " @rpath";
}
w << " without CMAKE_SHARED_LIBRARY_RUNTIME_C_FLAG being set.";
w << " This could be because you are using a Mac OS X version";
w << " less than 10.5 or because CMake's platform configuration is";
w << " corrupt.";
cmake* cm = this->Makefile->GetCMakeInstance();
cm->IssueMessage(cmake::FATAL_ERROR, w.str(), this->GetBacktrace());
}
return true;
}
//----------------------------------------------------------------------------
bool cmTarget::MacOSXRpathInstallNameDirDefault() const
{
// we can't do rpaths when unsupported
if(!this->Makefile->IsSet("CMAKE_SHARED_LIBRARY_RUNTIME_C_FLAG"))
{
return false;
}
const char* macosx_rpath_str = this->GetProperty("MACOSX_RPATH");
if(macosx_rpath_str)
{
return this->GetPropertyAsBool("MACOSX_RPATH");
}
cmPolicies::PolicyStatus cmp0042 = this->GetPolicyStatusCMP0042();
if(cmp0042 == cmPolicies::WARN)
{
this->Makefile->GetLocalGenerator()->GetGlobalGenerator()->
AddCMP0042WarnTarget(this->GetName());
}
if(cmp0042 == cmPolicies::NEW)
{
return true;
}
return false;
}
//----------------------------------------------------------------------------
bool cmTarget::IsImportedSharedLibWithoutSOName(
const std::string& config) const
{
if(this->IsImported() && this->GetType() == cmTarget::SHARED_LIBRARY)
{
if(cmTarget::ImportInfo const* info = this->GetImportInfo(config, this))
{
return info->NoSOName;
}
}
return false;
}
//----------------------------------------------------------------------------
std::string cmTarget::NormalGetRealName(const std::string& config) const
{
// This should not be called for imported targets.
// TODO: Split cmTarget into a class hierarchy to get compile-time
// enforcement of the limited imported target API.
if(this->IsImported())
{
std::string msg = "NormalGetRealName called on imported target: ";
msg += this->GetName();
this->GetMakefile()->
IssueMessage(cmake::INTERNAL_ERROR,
msg.c_str());
}
if(this->GetType() == cmTarget::EXECUTABLE)
{
// Compute the real name that will be built.
std::string name;
std::string realName;
std::string impName;
std::string pdbName;
this->GetExecutableNames(name, realName, impName, pdbName, config);
return realName;
}
else
{
// Compute the real name that will be built.
std::string name;
std::string soName;
std::string realName;
std::string impName;
std::string pdbName;
this->GetLibraryNames(name, soName, realName, impName, pdbName, config);
return realName;
}
}
//----------------------------------------------------------------------------
std::string cmTarget::GetFullName(const std::string& config,
bool implib) const
{
if(this->IsImported())
{
return this->GetFullNameImported(config, implib);
}
else
{
return this->GetFullNameInternal(config, implib);
}
}
//----------------------------------------------------------------------------
std::string
cmTarget::GetFullNameImported(const std::string& config, bool implib) const
{
return cmSystemTools::GetFilenameName(
this->ImportedGetFullPath(config, implib));
}
//----------------------------------------------------------------------------
void cmTarget::GetFullNameComponents(std::string& prefix, std::string& base,
std::string& suffix,
const std::string& config,
2013-11-04 01:26:26 +04:00
bool implib) const
{
this->GetFullNameInternal(config, implib, prefix, base, suffix);
}
//----------------------------------------------------------------------------
std::string cmTarget::GetFullPath(const std::string& config, bool implib,
bool realname) const
{
if(this->IsImported())
{
return this->ImportedGetFullPath(config, implib);
}
else
{
return this->NormalGetFullPath(config, implib, realname);
}
}
//----------------------------------------------------------------------------
std::string cmTarget::NormalGetFullPath(const std::string& config,
bool implib, bool realname) const
{
std::string fpath = this->GetDirectory(config, implib);
fpath += "/";
if(this->IsAppBundleOnApple())
{
fpath = this->BuildMacContentDirectory(fpath, config, false);
fpath += "/";
}
// Add the full name of the target.
if(implib)
{
fpath += this->GetFullName(config, true);
}
else if(realname)
{
fpath += this->NormalGetRealName(config);
}
else
{
fpath += this->GetFullName(config, false);
}
return fpath;
}
//----------------------------------------------------------------------------
std::string
cmTarget::ImportedGetFullPath(const std::string& config, bool implib) const
{
std::string result;
if(cmTarget::ImportInfo const* info = this->GetImportInfo(config, this))
{
result = implib? info->ImportLibrary : info->Location;
}
if(result.empty())
{
result = this->GetName();
result += "-NOTFOUND";
}
return result;
}
//----------------------------------------------------------------------------
std::string
cmTarget::GetFullNameInternal(const std::string& config, bool implib) const
{
std::string prefix;
std::string base;
std::string suffix;
this->GetFullNameInternal(config, implib, prefix, base, suffix);
return prefix+base+suffix;
}
//----------------------------------------------------------------------------
void cmTarget::GetFullNameInternal(const std::string& config,
bool implib,
std::string& outPrefix,
std::string& outBase,
std::string& outSuffix) const
{
// Use just the target name for non-main target types.
if(this->GetType() != cmTarget::STATIC_LIBRARY &&
this->GetType() != cmTarget::SHARED_LIBRARY &&
this->GetType() != cmTarget::MODULE_LIBRARY &&
this->GetType() != cmTarget::EXECUTABLE)
{
outPrefix = "";
outBase = this->GetName();
outSuffix = "";
return;
}
// Return an empty name for the import library if this platform
// does not support import libraries.
if(implib &&
!this->Makefile->GetDefinition("CMAKE_IMPORT_LIBRARY_SUFFIX"))
{
outPrefix = "";
outBase = "";
outSuffix = "";
return;
}
// The implib option is only allowed for shared libraries, module
// libraries, and executables.
if(this->GetType() != cmTarget::SHARED_LIBRARY &&
this->GetType() != cmTarget::MODULE_LIBRARY &&
this->GetType() != cmTarget::EXECUTABLE)
{
implib = false;
}
// Compute the full name for main target types.
const char* targetPrefix = (implib
? this->GetProperty("IMPORT_PREFIX")
: this->GetProperty("PREFIX"));
const char* targetSuffix = (implib
? this->GetProperty("IMPORT_SUFFIX")
: this->GetProperty("SUFFIX"));
const char* configPostfix = 0;
if(!config.empty())
{
std::string configProp = cmSystemTools::UpperCase(config);
configProp += "_POSTFIX";
configPostfix = this->GetProperty(configProp.c_str());
// Mac application bundles and frameworks have no postfix.
if(configPostfix &&
(this->IsAppBundleOnApple() || this->IsFrameworkOnApple()))
{
configPostfix = 0;
}
}
const char* prefixVar = this->GetPrefixVariableInternal(implib);
const char* suffixVar = this->GetSuffixVariableInternal(implib);
// Check for language-specific default prefix and suffix.
std::string ll = this->GetLinkerLanguage(config, this);
if(!ll.empty())
{
if(!targetSuffix && suffixVar && *suffixVar)
{
std::string langSuff = suffixVar + std::string("_") + ll;
targetSuffix = this->Makefile->GetDefinition(langSuff.c_str());
}
if(!targetPrefix && prefixVar && *prefixVar)
{
std::string langPrefix = prefixVar + std::string("_") + ll;
targetPrefix = this->Makefile->GetDefinition(langPrefix.c_str());
}
}
// if there is no prefix on the target use the cmake definition
if(!targetPrefix && prefixVar)
{
2006-03-15 19:02:08 +03:00
targetPrefix = this->Makefile->GetSafeDefinition(prefixVar);
}
// if there is no suffix on the target use the cmake definition
if(!targetSuffix && suffixVar)
{
2006-03-15 19:02:08 +03:00
targetSuffix = this->Makefile->GetSafeDefinition(suffixVar);
}
// frameworks have directory prefix but no suffix
std::string fw_prefix;
if(this->IsFrameworkOnApple())
{
fw_prefix = this->GetOutputName(config, false);
fw_prefix += ".framework/";
targetPrefix = fw_prefix.c_str();
targetSuffix = 0;
}
if(this->IsCFBundleOnApple())
{
fw_prefix = this->GetOutputName(config, false);
fw_prefix += ".";
const char *ext = this->GetProperty("BUNDLE_EXTENSION");
if (!ext)
{
ext = "bundle";
}
fw_prefix += ext;
fw_prefix += "/Contents/MacOS/";
targetPrefix = fw_prefix.c_str();
targetSuffix = 0;
}
// Begin the final name with the prefix.
outPrefix = targetPrefix?targetPrefix:"";
// Append the target name or property-specified name.
outBase += this->GetOutputName(config, implib);
// Append the per-configuration postfix.
outBase += configPostfix?configPostfix:"";
// Name shared libraries with their version number on some platforms.
if(const char* soversion = this->GetProperty("SOVERSION"))
{
if(this->GetType() == cmTarget::SHARED_LIBRARY && !implib &&
this->Makefile->IsOn("CMAKE_SHARED_LIBRARY_NAME_WITH_VERSION"))
{
outBase += "-";
outBase += soversion;
}
}
// Append the suffix.
outSuffix = targetSuffix?targetSuffix:"";
}
//----------------------------------------------------------------------------
void cmTarget::GetLibraryNames(std::string& name,
std::string& soName,
std::string& realName,
std::string& impName,
std::string& pdbName,
const std::string& config) const
{
// This should not be called for imported targets.
// TODO: Split cmTarget into a class hierarchy to get compile-time
// enforcement of the limited imported target API.
if(this->IsImported())
{
std::string msg = "GetLibraryNames called on imported target: ";
msg += this->GetName();
this->Makefile->IssueMessage(cmake::INTERNAL_ERROR,
msg.c_str());
return;
}
assert(this->GetType() != INTERFACE_LIBRARY);
// Check for library version properties.
const char* version = this->GetProperty("VERSION");
const char* soversion = this->GetProperty("SOVERSION");
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
if(!this->HasSOName(config) ||
this->IsFrameworkOnApple())
{
// Versioning is supported only for shared libraries and modules,
// and then only when the platform supports an soname flag.
version = 0;
soversion = 0;
}
if(version && !soversion)
{
// The soversion must be set if the library version is set. Use
// the library version as the soversion.
soversion = version;
}
if(!version && soversion)
{
// Use the soversion as the library version.
version = soversion;
}
// Get the components of the library name.
std::string prefix;
std::string base;
std::string suffix;
this->GetFullNameInternal(config, false, prefix, base, suffix);
// The library name.
name = prefix+base+suffix;
if(this->IsFrameworkOnApple())
{
realName = prefix;
realName += "Versions/";
realName += this->GetFrameworkVersion();
realName += "/";
realName += base;
soName = realName;
}
else
{
// The library's soname.
this->ComputeVersionedName(soName, prefix, base, suffix,
name, soversion);
// The library's real name on disk.
this->ComputeVersionedName(realName, prefix, base, suffix,
name, version);
}
// The import library name.
if(this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY)
{
impName = this->GetFullNameInternal(config, true);
}
else
{
impName = "";
}
// The program database file name.
pdbName = this->GetPDBName(config);
}
//----------------------------------------------------------------------------
void cmTarget::ComputeVersionedName(std::string& vName,
std::string const& prefix,
std::string const& base,
std::string const& suffix,
std::string const& name,
const char* version) const
{
vName = this->IsApple? (prefix+base) : name;
if(version)
{
vName += ".";
vName += version;
}
vName += this->IsApple? suffix : std::string();
}
//----------------------------------------------------------------------------
void cmTarget::GetExecutableNames(std::string& name,
std::string& realName,
std::string& impName,
std::string& pdbName,
const std::string& config) const
{
// This should not be called for imported targets.
// TODO: Split cmTarget into a class hierarchy to get compile-time
// enforcement of the limited imported target API.
if(this->IsImported())
{
std::string msg =
"GetExecutableNames called on imported target: ";
msg += this->GetName();
this->GetMakefile()->IssueMessage(cmake::INTERNAL_ERROR, msg.c_str());
}
// This versioning is supported only for executables and then only
// when the platform supports symbolic links.
#if defined(_WIN32) && !defined(__CYGWIN__)
const char* version = 0;
#else
// Check for executable version properties.
const char* version = this->GetProperty("VERSION");
if(this->GetType() != cmTarget::EXECUTABLE || this->Makefile->IsOn("XCODE"))
{
version = 0;
}
#endif
// Get the components of the executable name.
std::string prefix;
std::string base;
std::string suffix;
this->GetFullNameInternal(config, false, prefix, base, suffix);
// The executable name.
name = prefix+base+suffix;
// The executable's real name on disk.
#if defined(__CYGWIN__)
realName = prefix+base;
#else
realName = name;
#endif
if(version)
{
realName += "-";
realName += version;
}
#if defined(__CYGWIN__)
realName += suffix;
#endif
// The import library name.
impName = this->GetFullNameInternal(config, true);
// The program database file name.
pdbName = this->GetPDBName(config);
}
//----------------------------------------------------------------------------
bool cmTarget::HasImplibGNUtoMS() const
{
return this->HasImportLibrary() && this->GetPropertyAsBool("GNUtoMS");
}
//----------------------------------------------------------------------------
bool cmTarget::GetImplibGNUtoMS(std::string const& gnuName,
std::string& out, const char* newExt) const
{
if(this->HasImplibGNUtoMS() &&
gnuName.size() > 6 && gnuName.substr(gnuName.size()-6) == ".dll.a")
{
out = gnuName.substr(0, gnuName.size()-6);
out += newExt? newExt : ".lib";
return true;
}
return false;
}
//----------------------------------------------------------------------------
void cmTarget::SetPropertyDefault(const std::string& property,
const char* default_value)
{
// Compute the name of the variable holding the default value.
std::string var = "CMAKE_";
var += property;
2006-03-15 19:02:08 +03:00
if(const char* value = this->Makefile->GetDefinition(var.c_str()))
{
this->SetProperty(property, value);
}
else if(default_value)
{
this->SetProperty(property, default_value);
}
}
//----------------------------------------------------------------------------
bool cmTarget::HaveBuildTreeRPATH(const std::string& config) const
{
if (this->GetPropertyAsBool("SKIP_BUILD_RPATH"))
{
return false;
}
std::vector<std::string> libs;
this->GetDirectLinkLibraries(config, libs, this);
return !libs.empty();
}
//----------------------------------------------------------------------------
bool cmTarget::HaveInstallTreeRPATH() const
{
const char* install_rpath = this->GetProperty("INSTALL_RPATH");
return (install_rpath && *install_rpath) &&
!this->Makefile->IsOn("CMAKE_SKIP_INSTALL_RPATH");
}
//----------------------------------------------------------------------------
bool cmTarget::NeedRelinkBeforeInstall(const std::string& config) const
{
// Only executables and shared libraries can have an rpath and may
// need relinking.
2006-03-15 19:02:08 +03:00
if(this->TargetTypeValue != cmTarget::EXECUTABLE &&
this->TargetTypeValue != cmTarget::SHARED_LIBRARY &&
this->TargetTypeValue != cmTarget::MODULE_LIBRARY)
{
return false;
}
// If there is no install location this target will not be installed
// and therefore does not need relinking.
if(!this->GetHaveInstallRule())
{
return false;
}
// If skipping all rpaths completely then no relinking is needed.
2006-03-15 19:02:08 +03:00
if(this->Makefile->IsOn("CMAKE_SKIP_RPATH"))
{
return false;
}
// If building with the install-tree rpath no relinking is needed.
if(this->GetPropertyAsBool("BUILD_WITH_INSTALL_RPATH"))
{
return false;
}
// If chrpath is going to be used no relinking is needed.
if(this->IsChrpathUsed(config))
{
return false;
}
// Check for rpath support on this platform.
std::string ll = this->GetLinkerLanguage(config, this);
if(!ll.empty())
{
std::string flagVar = "CMAKE_SHARED_LIBRARY_RUNTIME_";
flagVar += ll;
flagVar += "_FLAG";
2006-03-15 19:02:08 +03:00
if(!this->Makefile->IsSet(flagVar.c_str()))
{
// There is no rpath support on this platform so nothing needs
// relinking.
return false;
}
}
else
{
// No linker language is known. This error will be reported by
// other code.
return false;
}
// If either a build or install tree rpath is set then the rpath
// will likely change between the build tree and install tree and
// this target must be relinked.
return this->HaveBuildTreeRPATH(config) || this->HaveInstallTreeRPATH();
}
//----------------------------------------------------------------------------
std::string cmTarget::GetInstallNameDirForBuildTree(
const std::string& config) const
{
// If building directly for installation then the build tree install_name
// is the same as the install tree.
if(this->GetPropertyAsBool("BUILD_WITH_INSTALL_RPATH"))
{
return GetInstallNameDirForInstallTree();
}
// Use the build tree directory for the target.
2006-03-15 19:02:08 +03:00
if(this->Makefile->IsOn("CMAKE_PLATFORM_HAS_INSTALLNAME") &&
!this->Makefile->IsOn("CMAKE_SKIP_RPATH") &&
!this->GetPropertyAsBool("SKIP_BUILD_RPATH"))
{
std::string dir;
bool macosx_rpath = this->MacOSXRpathInstallNameDirDefault();
if(macosx_rpath)
{
dir = "@rpath";
}
else
{
dir = this->GetDirectory(config);
}
dir += "/";
return dir;
}
else
{
return "";
}
}
//----------------------------------------------------------------------------
2013-11-04 01:26:26 +04:00
std::string cmTarget::GetInstallNameDirForInstallTree() const
{
if(this->Makefile->IsOn("CMAKE_PLATFORM_HAS_INSTALLNAME"))
{
std::string dir;
const char* install_name_dir = this->GetProperty("INSTALL_NAME_DIR");
if(!this->Makefile->IsOn("CMAKE_SKIP_RPATH") &&
!this->Makefile->IsOn("CMAKE_SKIP_INSTALL_RPATH"))
{
if(install_name_dir && *install_name_dir)
{
dir = install_name_dir;
dir += "/";
}
}
if(!install_name_dir)
{
if(this->MacOSXRpathInstallNameDirDefault())
{
dir = "@rpath/";
}
}
return dir;
}
else
{
return "";
}
}
//----------------------------------------------------------------------------
const char* cmTarget::GetOutputTargetType(bool implib) const
{
switch(this->GetType())
{
case cmTarget::SHARED_LIBRARY:
if(this->DLLPlatform)
{
if(implib)
{
// A DLL import library is treated as an archive target.
return "ARCHIVE";
}
else
{
// A DLL shared library is treated as a runtime target.
return "RUNTIME";
}
}
else
{
// For non-DLL platforms shared libraries are treated as
// library targets.
return "LIBRARY";
}
case cmTarget::STATIC_LIBRARY:
// Static libraries are always treated as archive targets.
return "ARCHIVE";
case cmTarget::MODULE_LIBRARY:
if(implib)
{
// Module libraries are always treated as library targets.
return "ARCHIVE";
}
else
{
// Module import libraries are treated as archive targets.
return "LIBRARY";
}
case cmTarget::EXECUTABLE:
if(implib)
{
// Executable import libraries are treated as archive targets.
return "ARCHIVE";
}
else
{
// Executables are always treated as runtime targets.
return "RUNTIME";
}
default:
break;
}
return "";
}
//----------------------------------------------------------------------------
bool cmTarget::ComputeOutputDir(const std::string& config,
bool implib, std::string& out) const
{
bool usesDefaultOutputDir = false;
std::string conf = config;
// Look for a target property defining the target output directory
// based on the target type.
std::string targetTypeName = this->GetOutputTargetType(implib);
const char* propertyName = 0;
std::string propertyNameStr = targetTypeName;
if(!propertyNameStr.empty())
{
propertyNameStr += "_OUTPUT_DIRECTORY";
propertyName = propertyNameStr.c_str();
}
// Check for a per-configuration output directory target property.
std::string configUpper = cmSystemTools::UpperCase(conf);
const char* configProp = 0;
std::string configPropStr = targetTypeName;
if(!configPropStr.empty())
{
configPropStr += "_OUTPUT_DIRECTORY_";
configPropStr += configUpper;
configProp = configPropStr.c_str();
}
// Select an output directory.
if(const char* config_outdir = this->GetProperty(configProp))
{
// Use the user-specified per-configuration output directory.
out = config_outdir;
// Skip per-configuration subdirectory.
conf = "";
}
else if(const char* outdir = this->GetProperty(propertyName))
{
// Use the user-specified output directory.
out = outdir;
}
else if(this->GetType() == cmTarget::EXECUTABLE)
{
// Lookup the output path for executables.
out = this->Makefile->GetSafeDefinition("EXECUTABLE_OUTPUT_PATH");
}
else if(this->GetType() == cmTarget::STATIC_LIBRARY ||
this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY)
{
// Lookup the output path for libraries.
out = this->Makefile->GetSafeDefinition("LIBRARY_OUTPUT_PATH");
}
if(out.empty())
{
// Default to the current output directory.
usesDefaultOutputDir = true;
out = ".";
}
// Convert the output path to a full path in case it is
// specified as a relative path. Treat a relative path as
// relative to the current output directory for this makefile.
out = (cmSystemTools::CollapseFullPath
(out.c_str(), this->Makefile->GetStartOutputDirectory()));
// The generator may add the configuration's subdirectory.
if(!conf.empty())
{
const char *platforms = this->Makefile->GetDefinition(
"CMAKE_XCODE_EFFECTIVE_PLATFORMS");
std::string suffix =
usesDefaultOutputDir && platforms ? "$(EFFECTIVE_PLATFORM_NAME)" : "";
this->Makefile->GetLocalGenerator()->GetGlobalGenerator()->
AppendDirectoryForConfig("/", conf, suffix.c_str(), out);
}
return usesDefaultOutputDir;
}
//----------------------------------------------------------------------------
bool cmTarget::ComputePDBOutputDir(const std::string& kind,
const std::string& config,
std::string& out) const
{
// Look for a target property defining the target output directory
// based on the target type.
const char* propertyName = 0;
std::string propertyNameStr = kind;
if(!propertyNameStr.empty())
{
propertyNameStr += "_OUTPUT_DIRECTORY";
propertyName = propertyNameStr.c_str();
}
std::string conf = config;
// Check for a per-configuration output directory target property.
std::string configUpper = cmSystemTools::UpperCase(conf);
const char* configProp = 0;
std::string configPropStr = kind;
if(!configPropStr.empty())
{
configPropStr += "_OUTPUT_DIRECTORY_";
configPropStr += configUpper;
configProp = configPropStr.c_str();
}
// Select an output directory.
if(const char* config_outdir = this->GetProperty(configProp))
{
// Use the user-specified per-configuration output directory.
out = config_outdir;
// Skip per-configuration subdirectory.
conf = "";
}
else if(const char* outdir = this->GetProperty(propertyName))
{
// Use the user-specified output directory.
out = outdir;
}
if(out.empty())
{
return false;
}
// Convert the output path to a full path in case it is
// specified as a relative path. Treat a relative path as
// relative to the current output directory for this makefile.
out = (cmSystemTools::CollapseFullPath
(out.c_str(), this->Makefile->GetStartOutputDirectory()));
// The generator may add the configuration's subdirectory.
if(!conf.empty())
{
this->Makefile->GetLocalGenerator()->GetGlobalGenerator()->
AppendDirectoryForConfig("/", conf, "", out);
}
return true;
}
//----------------------------------------------------------------------------
bool cmTarget::UsesDefaultOutputDir(const std::string& config,
bool implib) const
{
std::string dir;
return this->ComputeOutputDir(config, implib, dir);
}
//----------------------------------------------------------------------------
std::string cmTarget::GetOutputName(const std::string& config,
bool implib) const
{
std::vector<std::string> props;
std::string type = this->GetOutputTargetType(implib);
std::string configUpper = cmSystemTools::UpperCase(config);
if(!type.empty() && !configUpper.empty())
{
// <ARCHIVE|LIBRARY|RUNTIME>_OUTPUT_NAME_<CONFIG>
props.push_back(type + "_OUTPUT_NAME_" + configUpper);
}
if(!type.empty())
{
// <ARCHIVE|LIBRARY|RUNTIME>_OUTPUT_NAME
props.push_back(type + "_OUTPUT_NAME");
}
if(!configUpper.empty())
{
// OUTPUT_NAME_<CONFIG>
props.push_back("OUTPUT_NAME_" + configUpper);
// <CONFIG>_OUTPUT_NAME
props.push_back(configUpper + "_OUTPUT_NAME");
}
// OUTPUT_NAME
props.push_back("OUTPUT_NAME");
for(std::vector<std::string>::const_iterator i = props.begin();
i != props.end(); ++i)
{
if(const char* outName = this->GetProperty(i->c_str()))
{
return outName;
}
}
return this->GetName();
}
//----------------------------------------------------------------------------
std::string cmTarget::GetFrameworkVersion() const
{
assert(this->GetType() != INTERFACE_LIBRARY);
if(const char* fversion = this->GetProperty("FRAMEWORK_VERSION"))
{
return fversion;
}
else if(const char* tversion = this->GetProperty("VERSION"))
{
return tversion;
}
else
{
return "A";
}
}
//----------------------------------------------------------------------------
const char* cmTarget::GetExportMacro() const
{
// Define the symbol for targets that export symbols.
if(this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY ||
this->IsExecutableWithExports())
{
if(const char* custom_export_name = this->GetProperty("DEFINE_SYMBOL"))
{
this->ExportMacro = custom_export_name;
}
else
{
std::string in = this->GetName();
in += "_EXPORTS";
this->ExportMacro = cmSystemTools::MakeCindentifier(in.c_str());
}
return this->ExportMacro.c_str();
}
else
{
return 0;
}
}
//----------------------------------------------------------------------------
bool cmTarget::IsNullImpliedByLinkLibraries(const std::string &p) const
{
return this->LinkImplicitNullProperties.find(p)
!= this->LinkImplicitNullProperties.end();
}
//----------------------------------------------------------------------------
template<typename PropertyType>
PropertyType getTypedProperty(cmTarget const* tgt, const char *prop,
PropertyType *);
//----------------------------------------------------------------------------
template<>
bool getTypedProperty<bool>(cmTarget const* tgt, const char *prop, bool *)
{
return tgt->GetPropertyAsBool(prop);
}
//----------------------------------------------------------------------------
template<>
const char *getTypedProperty<const char *>(cmTarget const* tgt,
const char *prop,
const char **)
{
return tgt->GetProperty(prop);
}
enum CompatibleType
{
BoolType,
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
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StringType,
NumberMinType,
NumberMaxType
};
//----------------------------------------------------------------------------
template<typename PropertyType>
std::pair<bool, PropertyType> consistentProperty(PropertyType lhs,
PropertyType rhs,
CompatibleType t);
//----------------------------------------------------------------------------
template<>
std::pair<bool, bool> consistentProperty(bool lhs, bool rhs, CompatibleType)
{
return std::make_pair(lhs == rhs, lhs);
}
//----------------------------------------------------------------------------
std::pair<bool, const char*> consistentStringProperty(const char *lhs,
const char *rhs)
{
const bool b = strcmp(lhs, rhs) == 0;
return std::make_pair(b, b ? lhs : 0);
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
#if defined(_MSC_VER) && _MSC_VER <= 1200
template<typename T> const T&
cmMaximum(const T& l, const T& r) {return l > r ? l : r;}
template<typename T> const T&
cmMinimum(const T& l, const T& r) {return l < r ? l : r;}
#else
#define cmMinimum std::min
#define cmMaximum std::max
#endif
//----------------------------------------------------------------------------
std::pair<bool, const char*> consistentNumberProperty(const char *lhs,
const char *rhs,
CompatibleType t)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
char *pEnd;
#if defined(_MSC_VER)
static const char* const null_ptr = 0;
#else
# define null_ptr 0
#endif
long lnum = strtol(lhs, &pEnd, 0);
if (pEnd == lhs || *pEnd != '\0' || errno == ERANGE)
{
return std::pair<bool, const char*>(false, null_ptr);
}
long rnum = strtol(rhs, &pEnd, 0);
if (pEnd == rhs || *pEnd != '\0' || errno == ERANGE)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
return std::pair<bool, const char*>(false, null_ptr);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
}
#if !defined(_MSC_VER)
#undef null_ptr
#endif
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
if (t == NumberMaxType)
{
return std::make_pair(true, cmMaximum(lnum, rnum) == lnum ? lhs : rhs);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
}
else
{
return std::make_pair(true, cmMinimum(lnum, rnum) == lnum ? lhs : rhs);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
}
}
//----------------------------------------------------------------------------
template<>
std::pair<bool, const char*> consistentProperty(const char *lhs,
const char *rhs,
CompatibleType t)
{
if (!lhs && !rhs)
{
return std::make_pair(true, lhs);
}
if (!lhs)
{
return std::make_pair(true, rhs);
}
if (!rhs)
{
return std::make_pair(true, lhs);
}
#if defined(_MSC_VER)
static const char* const null_ptr = 0;
#else
# define null_ptr 0
#endif
switch(t)
{
case BoolType:
assert(!"consistentProperty for strings called with BoolType");
return std::pair<bool, const char*>(false, null_ptr);
case StringType:
return consistentStringProperty(lhs, rhs);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
case NumberMinType:
case NumberMaxType:
return consistentNumberProperty(lhs, rhs, t);
}
assert(!"Unreachable!");
return std::pair<bool, const char*>(false, null_ptr);
#if !defined(_MSC_VER)
#undef null_ptr
#endif
}
template<typename PropertyType>
PropertyType impliedValue(PropertyType);
template<>
bool impliedValue<bool>(bool)
{
return false;
}
template<>
const char* impliedValue<const char*>(const char*)
{
return "";
}
template<typename PropertyType>
std::string valueAsString(PropertyType);
template<>
std::string valueAsString<bool>(bool value)
{
return value ? "TRUE" : "FALSE";
}
template<>
std::string valueAsString<const char*>(const char* value)
{
return value ? value : "(unset)";
}
//----------------------------------------------------------------------------
void
cmTarget::ReportPropertyOrigin(const std::string &p,
const std::string &result,
const std::string &report,
const std::string &compatibilityType) const
{
std::vector<std::string> debugProperties;
const char *debugProp =
this->Makefile->GetDefinition("CMAKE_DEBUG_TARGET_PROPERTIES");
if (debugProp)
{
cmSystemTools::ExpandListArgument(debugProp, debugProperties);
}
bool debugOrigin = !this->DebugCompatiblePropertiesDone[p]
&& std::find(debugProperties.begin(),
debugProperties.end(),
p)
!= debugProperties.end();
if (this->Makefile->IsGeneratingBuildSystem())
{
this->DebugCompatiblePropertiesDone[p] = true;
}
if (!debugOrigin)
{
return;
}
std::string areport = compatibilityType;
areport += std::string(" of property \"") + p + "\" for target \"";
areport += std::string(this->GetName());
areport += "\" (result: \"";
areport += result;
areport += "\"):\n" + report;
cmListFileBacktrace lfbt;
this->Makefile->GetCMakeInstance()->IssueMessage(cmake::LOG, areport, lfbt);
}
//----------------------------------------------------------------------------
std::string compatibilityType(CompatibleType t)
{
switch(t)
{
case BoolType:
return "Boolean compatibility";
case StringType:
return "String compatibility";
case NumberMaxType:
return "Numeric maximum compatibility";
case NumberMinType:
return "Numeric minimum compatibility";
}
assert(!"Unreachable!");
return "";
}
//----------------------------------------------------------------------------
std::string compatibilityAgree(CompatibleType t, bool dominant)
{
switch(t)
{
case BoolType:
case StringType:
return dominant ? "(Disagree)\n" : "(Agree)\n";
case NumberMaxType:
case NumberMinType:
return dominant ? "(Dominant)\n" : "(Ignored)\n";
}
assert(!"Unreachable!");
return "";
}
//----------------------------------------------------------------------------
template<typename PropertyType>
PropertyType checkInterfacePropertyCompatibility(cmTarget const* tgt,
const std::string &p,
const std::string& config,
const char *defaultValue,
CompatibleType t,
PropertyType *)
{
PropertyType propContent = getTypedProperty<PropertyType>(tgt, p.c_str(),
0);
const bool explicitlySet = tgt->GetProperties()
.find(p.c_str())
!= tgt->GetProperties().end();
const bool impliedByUse =
tgt->IsNullImpliedByLinkLibraries(p);
assert((impliedByUse ^ explicitlySet)
|| (!impliedByUse && !explicitlySet));
std::vector<cmTarget*> deps;
tgt->GetTransitiveTargetClosure(config, tgt, deps);
if(deps.empty())
{
return propContent;
}
bool propInitialized = explicitlySet;
std::string report = " * Target \"";
report += tgt->GetName();
if (explicitlySet)
{
report += "\" has property content \"";
report += valueAsString<PropertyType>(propContent);
report += "\"\n";
}
else if (impliedByUse)
{
report += "\" property is implied by use.\n";
}
else
{
report += "\" property not set.\n";
}
for(std::vector<cmTarget*>::const_iterator li =
deps.begin();
li != deps.end(); ++li)
{
// An error should be reported if one dependency
// has INTERFACE_POSITION_INDEPENDENT_CODE ON and the other
// has INTERFACE_POSITION_INDEPENDENT_CODE OFF, or if the
// target itself has a POSITION_INDEPENDENT_CODE which disagrees
// with a dependency.
cmTarget const* theTarget = *li;
const bool ifaceIsSet = theTarget->GetProperties()
.find("INTERFACE_" + p)
!= theTarget->GetProperties().end();
PropertyType ifacePropContent =
getTypedProperty<PropertyType>(theTarget,
("INTERFACE_" + p).c_str(), 0);
std::string reportEntry;
if (ifaceIsSet)
{
reportEntry += " * Target \"";
reportEntry += theTarget->GetName();
reportEntry += "\" property value \"";
reportEntry += valueAsString<PropertyType>(ifacePropContent);
reportEntry += "\" ";
}
if (explicitlySet)
{
if (ifaceIsSet)
{
std::pair<bool, PropertyType> consistent =
consistentProperty(propContent,
ifacePropContent, t);
report += reportEntry;
report += compatibilityAgree(t, propContent != consistent.second);
if (!consistent.first)
{
cmOStringStream e;
e << "Property " << p << " on target \""
<< tgt->GetName() << "\" does\nnot match the "
"INTERFACE_" << p << " property requirement\nof "
"dependency \"" << theTarget->GetName() << "\".\n";
cmSystemTools::Error(e.str().c_str());
break;
}
else
{
propContent = consistent.second;
continue;
}
}
else
{
// Explicitly set on target and not set in iface. Can't disagree.
continue;
}
}
else if (impliedByUse)
{
propContent = impliedValue<PropertyType>(propContent);
if (ifaceIsSet)
{
std::pair<bool, PropertyType> consistent =
consistentProperty(propContent,
ifacePropContent, t);
report += reportEntry;
report += compatibilityAgree(t, propContent != consistent.second);
if (!consistent.first)
{
cmOStringStream e;
e << "Property " << p << " on target \""
<< tgt->GetName() << "\" is\nimplied to be " << defaultValue
<< " because it was used to determine the link libraries\n"
"already. The INTERFACE_" << p << " property on\ndependency \""
<< theTarget->GetName() << "\" is in conflict.\n";
cmSystemTools::Error(e.str().c_str());
break;
}
else
{
propContent = consistent.second;
continue;
}
}
else
{
// Implicitly set on target and not set in iface. Can't disagree.
continue;
}
}
else
{
if (ifaceIsSet)
{
if (propInitialized)
{
std::pair<bool, PropertyType> consistent =
consistentProperty(propContent,
ifacePropContent, t);
report += reportEntry;
report += compatibilityAgree(t, propContent != consistent.second);
if (!consistent.first)
{
cmOStringStream e;
e << "The INTERFACE_" << p << " property of \""
<< theTarget->GetName() << "\" does\nnot agree with the value "
"of " << p << " already determined\nfor \""
<< tgt->GetName() << "\".\n";
cmSystemTools::Error(e.str().c_str());
break;
}
else
{
propContent = consistent.second;
continue;
}
}
else
{
report += reportEntry + "(Interface set)\n";
propContent = ifacePropContent;
propInitialized = true;
}
}
else
{
// Not set. Nothing to agree on.
continue;
}
}
}
tgt->ReportPropertyOrigin(p, valueAsString<PropertyType>(propContent),
report, compatibilityType(t));
return propContent;
}
//----------------------------------------------------------------------------
bool cmTarget::GetLinkInterfaceDependentBoolProperty(const std::string &p,
const std::string& config) const
{
return checkInterfacePropertyCompatibility<bool>(this, p, config, "FALSE",
BoolType, 0);
}
//----------------------------------------------------------------------------
const char * cmTarget::GetLinkInterfaceDependentStringProperty(
const std::string &p,
const std::string& config) const
{
return checkInterfacePropertyCompatibility<const char *>(this,
p,
config,
"empty",
StringType, 0);
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
//----------------------------------------------------------------------------
const char * cmTarget::GetLinkInterfaceDependentNumberMinProperty(
const std::string &p,
const std::string& config) const
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
return checkInterfacePropertyCompatibility<const char *>(this,
p,
config,
"empty",
NumberMinType, 0);
}
//----------------------------------------------------------------------------
const char * cmTarget::GetLinkInterfaceDependentNumberMaxProperty(
const std::string &p,
const std::string& config) const
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
return checkInterfacePropertyCompatibility<const char *>(this,
p,
config,
"empty",
NumberMaxType, 0);
}
//----------------------------------------------------------------------------
bool isLinkDependentProperty(cmTarget const* tgt, const std::string &p,
const std::string& interfaceProperty,
const std::string& config)
{
std::vector<cmTarget*> deps;
tgt->GetTransitiveTargetClosure(config, tgt, deps);
if(deps.empty())
{
return false;
}
for(std::vector<cmTarget*>::const_iterator li =
deps.begin();
li != deps.end(); ++li)
{
const char *prop = (*li)->GetProperty(interfaceProperty);
if (!prop)
{
continue;
}
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(prop, props);
for(std::vector<std::string>::iterator pi = props.begin();
pi != props.end(); ++pi)
{
if (*pi == p)
{
return true;
}
}
}
return false;
}
//----------------------------------------------------------------------------
bool cmTarget::IsLinkInterfaceDependentBoolProperty(const std::string &p,
const std::string& config) const
{
if (this->TargetTypeValue == OBJECT_LIBRARY
|| this->TargetTypeValue == INTERFACE_LIBRARY)
{
return false;
}
return (p == "POSITION_INDEPENDENT_CODE") ||
isLinkDependentProperty(this, p, "COMPATIBLE_INTERFACE_BOOL",
config);
}
//----------------------------------------------------------------------------
bool cmTarget::IsLinkInterfaceDependentStringProperty(const std::string &p,
const std::string& config) const
{
if (this->TargetTypeValue == OBJECT_LIBRARY
|| this->TargetTypeValue == INTERFACE_LIBRARY)
{
return false;
}
return (p == "AUTOUIC_OPTIONS") ||
isLinkDependentProperty(this, p, "COMPATIBLE_INTERFACE_STRING",
config);
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
//----------------------------------------------------------------------------
bool cmTarget::IsLinkInterfaceDependentNumberMinProperty(const std::string &p,
const std::string& config) const
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
if (this->TargetTypeValue == OBJECT_LIBRARY
|| this->TargetTypeValue == INTERFACE_LIBRARY)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
return false;
}
return isLinkDependentProperty(this, p, "COMPATIBLE_INTERFACE_NUMBER_MIN",
config);
}
//----------------------------------------------------------------------------
bool cmTarget::IsLinkInterfaceDependentNumberMaxProperty(const std::string &p,
const std::string& config) const
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
if (this->TargetTypeValue == OBJECT_LIBRARY
|| this->TargetTypeValue == INTERFACE_LIBRARY)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
return false;
}
return isLinkDependentProperty(this, p, "COMPATIBLE_INTERFACE_NUMBER_MAX",
config);
}
//----------------------------------------------------------------------------
void cmTarget::GetLanguages(std::set<std::string>& languages) const
{
for(std::vector<cmSourceFile*>::const_iterator
i = this->SourceFiles.begin(); i != this->SourceFiles.end(); ++i)
{
const std::string& lang = (*i)->GetLanguage();
if(!lang.empty())
{
languages.insert(lang);
}
}
}
//----------------------------------------------------------------------------
bool cmTarget::IsChrpathUsed(const std::string& config) const
{
// Only certain target types have an rpath.
if(!(this->GetType() == cmTarget::SHARED_LIBRARY ||
this->GetType() == cmTarget::MODULE_LIBRARY ||
this->GetType() == cmTarget::EXECUTABLE))
{
return false;
}
// If the target will not be installed we do not need to change its
// rpath.
if(!this->GetHaveInstallRule())
{
return false;
}
// Skip chrpath if skipping rpath altogether.
if(this->Makefile->IsOn("CMAKE_SKIP_RPATH"))
{
return false;
}
// Skip chrpath if it does not need to be changed at install time.
if(this->GetPropertyAsBool("BUILD_WITH_INSTALL_RPATH"))
{
return false;
}
// Allow the user to disable builtin chrpath explicitly.
if(this->Makefile->IsOn("CMAKE_NO_BUILTIN_CHRPATH"))
{
return false;
}
if(this->Makefile->IsOn("CMAKE_PLATFORM_HAS_INSTALLNAME"))
{
return true;
}
#if defined(CMAKE_USE_ELF_PARSER)
// Enable if the rpath flag uses a separator and the target uses ELF
// binaries.
std::string ll = this->GetLinkerLanguage(config, this);
if(!ll.empty())
{
std::string sepVar = "CMAKE_SHARED_LIBRARY_RUNTIME_";
sepVar += ll;
sepVar += "_FLAG_SEP";
const char* sep = this->Makefile->GetDefinition(sepVar.c_str());
if(sep && *sep)
{
// TODO: Add ELF check to ABI detection and get rid of
// CMAKE_EXECUTABLE_FORMAT.
if(const char* fmt =
this->Makefile->GetDefinition("CMAKE_EXECUTABLE_FORMAT"))
{
return strcmp(fmt, "ELF") == 0;
}
}
}
#endif
static_cast<void>(config);
return false;
}
//----------------------------------------------------------------------------
cmTarget::ImportInfo const*
cmTarget::GetImportInfo(const std::string& config,
cmTarget const* headTarget) const
{
// There is no imported information for non-imported targets.
if(!this->IsImported())
{
return 0;
}
// Lookup/compute/cache the import information for this
// configuration.
std::string config_upper;
if(!config.empty())
{
config_upper = cmSystemTools::UpperCase(config);
}
else
{
config_upper = "NOCONFIG";
}
TargetConfigPair key(headTarget, config_upper);
typedef cmTargetInternals::ImportInfoMapType ImportInfoMapType;
ImportInfoMapType::const_iterator i =
this->Internal->ImportInfoMap.find(key);
if(i == this->Internal->ImportInfoMap.end())
{
ImportInfo info;
this->ComputeImportInfo(config_upper, info, headTarget);
ImportInfoMapType::value_type entry(key, info);
i = this->Internal->ImportInfoMap.insert(entry).first;
}
if(this->GetType() == INTERFACE_LIBRARY)
{
return &i->second;
}
// If the location is empty then the target is not available for
// this configuration.
if(i->second.Location.empty() && i->second.ImportLibrary.empty())
{
return 0;
}
// Return the import information.
return &i->second;
}
bool cmTarget::GetMappedConfig(std::string const& desired_config,
const char** loc,
const char** imp,
std::string& suffix) const
{
if (this->GetType() == INTERFACE_LIBRARY)
{
// This method attempts to find a config-specific LOCATION for the
// IMPORTED library. In the case of INTERFACE_LIBRARY, there is no
// LOCATION at all, so leaving *loc and *imp unchanged is the appropriate
// and valid response.
return true;
}
// Track the configuration-specific property suffix.
suffix = "_";
suffix += desired_config;
std::vector<std::string> mappedConfigs;
{
std::string mapProp = "MAP_IMPORTED_CONFIG_";
mapProp += desired_config;
if(const char* mapValue = this->GetProperty(mapProp.c_str()))
{
cmSystemTools::ExpandListArgument(mapValue, mappedConfigs);
}
}
// If we needed to find one of the mapped configurations but did not
// On a DLL platform there may be only IMPORTED_IMPLIB for a shared
// library or an executable with exports.
bool allowImp = this->HasImportLibrary();
// If a mapping was found, check its configurations.
for(std::vector<std::string>::const_iterator mci = mappedConfigs.begin();
!*loc && !*imp && mci != mappedConfigs.end(); ++mci)
{
// Look for this configuration.
std::string mcUpper = cmSystemTools::UpperCase(mci->c_str());
std::string locProp = "IMPORTED_LOCATION_";
locProp += mcUpper;
*loc = this->GetProperty(locProp.c_str());
if(allowImp)
{
std::string impProp = "IMPORTED_IMPLIB_";
impProp += mcUpper;
*imp = this->GetProperty(impProp.c_str());
}
// If it was found, use it for all properties below.
if(*loc || *imp)
{
suffix = "_";
suffix += mcUpper;
}
}
// If we needed to find one of the mapped configurations but did not
// then the target is not found. The project does not want any
// other configuration.
if(!mappedConfigs.empty() && !*loc && !*imp)
{
return false;
}
// If we have not yet found it then there are no mapped
// configurations. Look for an exact-match.
if(!*loc && !*imp)
{
std::string locProp = "IMPORTED_LOCATION";
locProp += suffix;
*loc = this->GetProperty(locProp.c_str());
if(allowImp)
{
std::string impProp = "IMPORTED_IMPLIB";
impProp += suffix;
*imp = this->GetProperty(impProp.c_str());
}
}
// If we have not yet found it then there are no mapped
// configurations and no exact match.
if(!*loc && !*imp)
{
// The suffix computed above is not useful.
suffix = "";
// Look for a configuration-less location. This may be set by
// manually-written code.
*loc = this->GetProperty("IMPORTED_LOCATION");
if(allowImp)
{
*imp = this->GetProperty("IMPORTED_IMPLIB");
}
}
// If we have not yet found it then the project is willing to try
// any available configuration.
if(!*loc && !*imp)
{
std::vector<std::string> availableConfigs;
if(const char* iconfigs = this->GetProperty("IMPORTED_CONFIGURATIONS"))
{
cmSystemTools::ExpandListArgument(iconfigs, availableConfigs);
}
for(std::vector<std::string>::const_iterator
aci = availableConfigs.begin();
!*loc && !*imp && aci != availableConfigs.end(); ++aci)
{
suffix = "_";
suffix += cmSystemTools::UpperCase(*aci);
std::string locProp = "IMPORTED_LOCATION";
locProp += suffix;
*loc = this->GetProperty(locProp.c_str());
if(allowImp)
{
std::string impProp = "IMPORTED_IMPLIB";
impProp += suffix;
*imp = this->GetProperty(impProp.c_str());
}
}
}
// If we have not yet found it then the target is not available.
if(!*loc && !*imp)
{
return false;
}
return true;
}
//----------------------------------------------------------------------------
void cmTarget::ComputeImportInfo(std::string const& desired_config,
ImportInfo& info,
cmTarget const* headTarget) const
{
// This method finds information about an imported target from its
// properties. The "IMPORTED_" namespace is reserved for properties
// defined by the project exporting the target.
// Initialize members.
info.NoSOName = false;
const char* loc = 0;
const char* imp = 0;
std::string suffix;
if (!this->GetMappedConfig(desired_config, &loc, &imp, suffix))
{
return;
}
// Get the link interface.
{
std::string linkProp = "INTERFACE_LINK_LIBRARIES";
const char *propertyLibs = this->GetProperty(linkProp.c_str());
if (this->GetType() != INTERFACE_LIBRARY)
{
if(!propertyLibs)
{
linkProp = "IMPORTED_LINK_INTERFACE_LIBRARIES";
linkProp += suffix;
propertyLibs = this->GetProperty(linkProp.c_str());
}
if(!propertyLibs)
{
linkProp = "IMPORTED_LINK_INTERFACE_LIBRARIES";
propertyLibs = this->GetProperty(linkProp.c_str());
}
}
if(propertyLibs)
{
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
cmGeneratorExpressionDAGChecker dagChecker(lfbt,
this->GetName(),
linkProp, 0, 0);
cmSystemTools::ExpandListArgument(ge.Parse(propertyLibs)
->Evaluate(this->Makefile,
desired_config.c_str(),
false,
headTarget,
this,
&dagChecker),
info.LinkInterface.Libraries);
}
}
if(this->GetType() == INTERFACE_LIBRARY)
{
return;
}
// A provided configuration has been chosen. Load the
// configuration's properties.
// Get the location.
if(loc)
{
info.Location = loc;
}
else
{
std::string impProp = "IMPORTED_LOCATION";
impProp += suffix;
if(const char* config_location = this->GetProperty(impProp.c_str()))
{
info.Location = config_location;
}
else if(const char* location = this->GetProperty("IMPORTED_LOCATION"))
{
info.Location = location;
}
}
// Get the soname.
if(this->GetType() == cmTarget::SHARED_LIBRARY)
{
std::string soProp = "IMPORTED_SONAME";
soProp += suffix;
if(const char* config_soname = this->GetProperty(soProp.c_str()))
{
info.SOName = config_soname;
}
else if(const char* soname = this->GetProperty("IMPORTED_SONAME"))
{
info.SOName = soname;
}
}
// Get the "no-soname" mark.
if(this->GetType() == cmTarget::SHARED_LIBRARY)
{
std::string soProp = "IMPORTED_NO_SONAME";
soProp += suffix;
if(const char* config_no_soname = this->GetProperty(soProp.c_str()))
{
info.NoSOName = cmSystemTools::IsOn(config_no_soname);
}
else if(const char* no_soname = this->GetProperty("IMPORTED_NO_SONAME"))
{
info.NoSOName = cmSystemTools::IsOn(no_soname);
}
}
// Get the import library.
if(imp)
{
info.ImportLibrary = imp;
}
else if(this->GetType() == cmTarget::SHARED_LIBRARY ||
this->IsExecutableWithExports())
{
std::string impProp = "IMPORTED_IMPLIB";
impProp += suffix;
if(const char* config_implib = this->GetProperty(impProp.c_str()))
{
info.ImportLibrary = config_implib;
}
else if(const char* implib = this->GetProperty("IMPORTED_IMPLIB"))
{
info.ImportLibrary = implib;
}
}
// Get the link dependencies.
{
std::string linkProp = "IMPORTED_LINK_DEPENDENT_LIBRARIES";
linkProp += suffix;
if(const char* config_libs = this->GetProperty(linkProp.c_str()))
{
cmSystemTools::ExpandListArgument(config_libs,
info.LinkInterface.SharedDeps);
}
else if(const char* libs =
this->GetProperty("IMPORTED_LINK_DEPENDENT_LIBRARIES"))
{
cmSystemTools::ExpandListArgument(libs, info.LinkInterface.SharedDeps);
}
}
// Get the link languages.
if(this->LinkLanguagePropagatesToDependents())
{
std::string linkProp = "IMPORTED_LINK_INTERFACE_LANGUAGES";
linkProp += suffix;
if(const char* config_libs = this->GetProperty(linkProp.c_str()))
{
cmSystemTools::ExpandListArgument(config_libs,
info.LinkInterface.Languages);
}
else if(const char* libs =
this->GetProperty("IMPORTED_LINK_INTERFACE_LANGUAGES"))
{
cmSystemTools::ExpandListArgument(libs,
info.LinkInterface.Languages);
}
}
// Get the cyclic repetition count.
if(this->GetType() == cmTarget::STATIC_LIBRARY)
{
std::string linkProp = "IMPORTED_LINK_INTERFACE_MULTIPLICITY";
linkProp += suffix;
if(const char* config_reps = this->GetProperty(linkProp.c_str()))
{
sscanf(config_reps, "%u", &info.LinkInterface.Multiplicity);
}
else if(const char* reps =
this->GetProperty("IMPORTED_LINK_INTERFACE_MULTIPLICITY"))
{
sscanf(reps, "%u", &info.LinkInterface.Multiplicity);
}
}
}
//----------------------------------------------------------------------------
cmTarget::LinkInterface const* cmTarget::GetLinkInterface(
const std::string& config,
cmTarget const* head) const
{
// Imported targets have their own link interface.
if(this->IsImported())
{
if(cmTarget::ImportInfo const* info = this->GetImportInfo(config, head))
{
return &info->LinkInterface;
}
return 0;
}
// Link interfaces are not supported for executables that do not
// export symbols.
if(this->GetType() == cmTarget::EXECUTABLE &&
!this->IsExecutableWithExports())
{
return 0;
}
// Lookup any existing link interface for this configuration.
TargetConfigPair key(head, cmSystemTools::UpperCase(config));
cmTargetInternals::LinkInterfaceMapType::iterator
i = this->Internal->LinkInterfaceMap.find(key);
if(i == this->Internal->LinkInterfaceMap.end())
{
// Compute the link interface for this configuration.
cmTargetInternals::OptionalLinkInterface iface;
iface.ExplicitLibraries =
this->ComputeLinkInterfaceLibraries(config, iface, head, iface.Exists);
if (iface.Exists)
{
this->Internal->ComputeLinkInterface(this, config, iface,
head, iface.ExplicitLibraries);
}
// Store the information for this configuration.
cmTargetInternals::LinkInterfaceMapType::value_type entry(key, iface);
i = this->Internal->LinkInterfaceMap.insert(entry).first;
}
else if(!i->second.Complete && i->second.Exists)
{
this->Internal->ComputeLinkInterface(this, config, i->second, head,
i->second.ExplicitLibraries);
}
return i->second.Exists ? &i->second : 0;
}
//----------------------------------------------------------------------------
cmTarget::LinkInterface const*
cmTarget::GetLinkInterfaceLibraries(const std::string& config,
cmTarget const* head) const
{
// Imported targets have their own link interface.
if(this->IsImported())
{
if(cmTarget::ImportInfo const* info = this->GetImportInfo(config, head))
{
return &info->LinkInterface;
}
return 0;
}
// Link interfaces are not supported for executables that do not
// export symbols.
if(this->GetType() == cmTarget::EXECUTABLE &&
!this->IsExecutableWithExports())
{
return 0;
}
// Lookup any existing link interface for this configuration.
TargetConfigPair key(head, cmSystemTools::UpperCase(config));
cmTargetInternals::LinkInterfaceMapType::iterator
i = this->Internal->LinkInterfaceMap.find(key);
if(i == this->Internal->LinkInterfaceMap.end())
{
// Compute the link interface for this configuration.
cmTargetInternals::OptionalLinkInterface iface;
iface.ExplicitLibraries = this->ComputeLinkInterfaceLibraries(config,
iface,
head,
iface.Exists);
// Store the information for this configuration.
cmTargetInternals::LinkInterfaceMapType::value_type entry(key, iface);
i = this->Internal->LinkInterfaceMap.insert(entry).first;
}
return i->second.Exists ? &i->second : 0;
}
//----------------------------------------------------------------------------
void processILibs(const std::string& config,
cmTarget const* headTarget,
std::string const& name,
std::vector<cmTarget*>& tgts, std::set<cmTarget*>& emitted)
{
if (cmTarget* tgt = headTarget->GetMakefile()
->FindTargetToUse(name.c_str()))
{
if (emitted.insert(tgt).second)
{
tgts.push_back(tgt);
std::vector<std::string> ilibs;
cmTarget::LinkInterface const* iface =
tgt->GetLinkInterfaceLibraries(config, headTarget);
if (iface)
{
for(std::vector<std::string>::const_iterator
it = iface->Libraries.begin();
it != iface->Libraries.end(); ++it)
{
processILibs(config, headTarget, *it, tgts, emitted);
}
}
}
}
}
//----------------------------------------------------------------------------
void cmTarget::GetTransitiveTargetClosure(const std::string& config,
cmTarget const* headTarget,
std::vector<cmTarget*> &tgts) const
{
std::set<cmTarget*> emitted;
cmTarget::LinkImplementation const* impl
= this->GetLinkImplementationLibraries(config, headTarget);
for(std::vector<std::string>::const_iterator it = impl->Libraries.begin();
it != impl->Libraries.end(); ++it)
{
processILibs(config, headTarget, *it, tgts, emitted);
}
}
//----------------------------------------------------------------------------
void cmTarget::GetTransitivePropertyTargets(const std::string& config,
cmTarget const* headTarget,
std::vector<cmTarget*> &tgts) const
{
cmTarget::LinkInterface const* iface
= this->GetLinkInterfaceLibraries(config, headTarget);
if (!iface)
{
return;
}
if(this->GetType() != STATIC_LIBRARY
|| this->GetPolicyStatusCMP0022() == cmPolicies::WARN
|| this->GetPolicyStatusCMP0022() == cmPolicies::OLD)
{
for(std::vector<std::string>::const_iterator it = iface->Libraries.begin();
it != iface->Libraries.end(); ++it)
{
if (cmTarget* tgt = headTarget->GetMakefile()
->FindTargetToUse(it->c_str()))
{
tgts.push_back(tgt);
}
}
return;
}
const char* linkIfaceProp = "INTERFACE_LINK_LIBRARIES";
const char* interfaceLibs = this->GetProperty(linkIfaceProp);
if (!interfaceLibs)
{
return;
}
// The interface libraries have been explicitly set.
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
cmGeneratorExpressionDAGChecker dagChecker(lfbt, this->GetName(),
linkIfaceProp, 0, 0);
dagChecker.SetTransitivePropertiesOnly();
std::vector<std::string> libs;
cmSystemTools::ExpandListArgument(ge.Parse(interfaceLibs)->Evaluate(
this->Makefile,
config,
false,
headTarget,
this, &dagChecker), libs);
for(std::vector<std::string>::const_iterator it = libs.begin();
it != libs.end(); ++it)
{
if (cmTarget* tgt = headTarget->GetMakefile()
->FindTargetToUse(it->c_str()))
{
tgts.push_back(tgt);
}
}
}
//----------------------------------------------------------------------------
const char* cmTarget::ComputeLinkInterfaceLibraries(const std::string& config,
LinkInterface& iface,
cmTarget const* headTarget,
bool &exists) const
{
// Construct the property name suffix for this configuration.
std::string suffix = "_";
if(!config.empty())
{
suffix += cmSystemTools::UpperCase(config);
}
else
{
suffix += "NOCONFIG";
}
// An explicit list of interface libraries may be set for shared
// libraries and executables that export symbols.
const char* explicitLibraries = 0;
Allow generator expressions in LINK_INTERFACE_LIBRARIES. The Config and IMPORTED_ variants may also contain generator expressions. If 'the implementation is the interface', then the result of evaluating the expressions at generate time is used to populate the IMPORTED_LINK_INTERFACE_LIBRARIES property. 1) In the case of non-static libraries, this is fine because the user still has the option to populate the LINK_INTERFACE_LIBRARIES with generator expressions if that is what is wanted. 2) In the case of static libraries, this prevents a footgun, enforcing that the interface and the implementation are really the same. Otherwise, the LINK_LIBRARIES could contain a generator expression which is evaluated with a different context at build time, and when used as an imported target. That would mean that the result of evaluating the INTERFACE_LINK_LIBRARIES property for a static library would not necessarily be the 'link implementation'. For example: add_library(libone STATIC libone.cpp) add_library(libtwo STATIC libtwo.cpp) add_library(libthree STATIC libthree.cpp) target_link_libraries(libtwo $<$<STREQUAL:$<TARGET_PROPERTY:TYPE>,STATIC_LIBRARY>:libone>) target_link_libraries(libthree libtwo) If the LINK_LIBRARIES content was simply copied to the IMPORTED_LINK_INTERFACE_LIBRARIES, then libthree links to libone, but executables linking to libthree will not link to libone. 3) As the 'implementation is the interface' concept is to be deprecated in the future anyway, this should be fine.
2013-01-04 16:36:18 +04:00
std::string linkIfaceProp;
if(this->PolicyStatusCMP0022 != cmPolicies::OLD &&
this->PolicyStatusCMP0022 != cmPolicies::WARN)
{
// CMP0022 NEW behavior is to use INTERFACE_LINK_LIBRARIES.
linkIfaceProp = "INTERFACE_LINK_LIBRARIES";
explicitLibraries = this->GetProperty(linkIfaceProp.c_str());
}
else if(this->GetType() == cmTarget::SHARED_LIBRARY ||
this->IsExecutableWithExports())
{
// CMP0022 OLD behavior is to use LINK_INTERFACE_LIBRARIES if set on a
// shared lib or executable.
// Lookup the per-configuration property.
Allow generator expressions in LINK_INTERFACE_LIBRARIES. The Config and IMPORTED_ variants may also contain generator expressions. If 'the implementation is the interface', then the result of evaluating the expressions at generate time is used to populate the IMPORTED_LINK_INTERFACE_LIBRARIES property. 1) In the case of non-static libraries, this is fine because the user still has the option to populate the LINK_INTERFACE_LIBRARIES with generator expressions if that is what is wanted. 2) In the case of static libraries, this prevents a footgun, enforcing that the interface and the implementation are really the same. Otherwise, the LINK_LIBRARIES could contain a generator expression which is evaluated with a different context at build time, and when used as an imported target. That would mean that the result of evaluating the INTERFACE_LINK_LIBRARIES property for a static library would not necessarily be the 'link implementation'. For example: add_library(libone STATIC libone.cpp) add_library(libtwo STATIC libtwo.cpp) add_library(libthree STATIC libthree.cpp) target_link_libraries(libtwo $<$<STREQUAL:$<TARGET_PROPERTY:TYPE>,STATIC_LIBRARY>:libone>) target_link_libraries(libthree libtwo) If the LINK_LIBRARIES content was simply copied to the IMPORTED_LINK_INTERFACE_LIBRARIES, then libthree links to libone, but executables linking to libthree will not link to libone. 3) As the 'implementation is the interface' concept is to be deprecated in the future anyway, this should be fine.
2013-01-04 16:36:18 +04:00
linkIfaceProp = "LINK_INTERFACE_LIBRARIES";
linkIfaceProp += suffix;
explicitLibraries = this->GetProperty(linkIfaceProp.c_str());
// If not set, try the generic property.
if(!explicitLibraries)
{
Allow generator expressions in LINK_INTERFACE_LIBRARIES. The Config and IMPORTED_ variants may also contain generator expressions. If 'the implementation is the interface', then the result of evaluating the expressions at generate time is used to populate the IMPORTED_LINK_INTERFACE_LIBRARIES property. 1) In the case of non-static libraries, this is fine because the user still has the option to populate the LINK_INTERFACE_LIBRARIES with generator expressions if that is what is wanted. 2) In the case of static libraries, this prevents a footgun, enforcing that the interface and the implementation are really the same. Otherwise, the LINK_LIBRARIES could contain a generator expression which is evaluated with a different context at build time, and when used as an imported target. That would mean that the result of evaluating the INTERFACE_LINK_LIBRARIES property for a static library would not necessarily be the 'link implementation'. For example: add_library(libone STATIC libone.cpp) add_library(libtwo STATIC libtwo.cpp) add_library(libthree STATIC libthree.cpp) target_link_libraries(libtwo $<$<STREQUAL:$<TARGET_PROPERTY:TYPE>,STATIC_LIBRARY>:libone>) target_link_libraries(libthree libtwo) If the LINK_LIBRARIES content was simply copied to the IMPORTED_LINK_INTERFACE_LIBRARIES, then libthree links to libone, but executables linking to libthree will not link to libone. 3) As the 'implementation is the interface' concept is to be deprecated in the future anyway, this should be fine.
2013-01-04 16:36:18 +04:00
linkIfaceProp = "LINK_INTERFACE_LIBRARIES";
explicitLibraries = this->GetProperty(linkIfaceProp.c_str());
}
}
if(explicitLibraries && this->PolicyStatusCMP0022 == cmPolicies::WARN &&
!this->Internal->PolicyWarnedCMP0022)
{
// Compare the explicitly set old link interface properties to the
// preferred new link interface property one and warn if different.
const char* newExplicitLibraries =
this->GetProperty("INTERFACE_LINK_LIBRARIES");
if (newExplicitLibraries
&& strcmp(newExplicitLibraries, explicitLibraries) != 0)
{
cmOStringStream w;
w <<
(this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0022)) << "\n"
"Target \"" << this->GetName() << "\" has an "
"INTERFACE_LINK_LIBRARIES property which differs from its " <<
linkIfaceProp << " properties."
"\n"
"INTERFACE_LINK_LIBRARIES:\n"
" " << newExplicitLibraries << "\n" <<
linkIfaceProp << ":\n"
" " << (explicitLibraries ? explicitLibraries : "(empty)") << "\n";
this->Makefile->IssueMessage(cmake::AUTHOR_WARNING, w.str());
this->Internal->PolicyWarnedCMP0022 = true;
}
}
// There is no implicit link interface for executables or modules
// so if none was explicitly set then there is no link interface.
if(!explicitLibraries &&
(this->GetType() == cmTarget::EXECUTABLE ||
(this->GetType() == cmTarget::MODULE_LIBRARY)))
{
exists = false;
return 0;
}
exists = true;
if(explicitLibraries)
{
// The interface libraries have been explicitly set.
Allow generator expressions in LINK_INTERFACE_LIBRARIES. The Config and IMPORTED_ variants may also contain generator expressions. If 'the implementation is the interface', then the result of evaluating the expressions at generate time is used to populate the IMPORTED_LINK_INTERFACE_LIBRARIES property. 1) In the case of non-static libraries, this is fine because the user still has the option to populate the LINK_INTERFACE_LIBRARIES with generator expressions if that is what is wanted. 2) In the case of static libraries, this prevents a footgun, enforcing that the interface and the implementation are really the same. Otherwise, the LINK_LIBRARIES could contain a generator expression which is evaluated with a different context at build time, and when used as an imported target. That would mean that the result of evaluating the INTERFACE_LINK_LIBRARIES property for a static library would not necessarily be the 'link implementation'. For example: add_library(libone STATIC libone.cpp) add_library(libtwo STATIC libtwo.cpp) add_library(libthree STATIC libthree.cpp) target_link_libraries(libtwo $<$<STREQUAL:$<TARGET_PROPERTY:TYPE>,STATIC_LIBRARY>:libone>) target_link_libraries(libthree libtwo) If the LINK_LIBRARIES content was simply copied to the IMPORTED_LINK_INTERFACE_LIBRARIES, then libthree links to libone, but executables linking to libthree will not link to libone. 3) As the 'implementation is the interface' concept is to be deprecated in the future anyway, this should be fine.
2013-01-04 16:36:18 +04:00
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
cmGeneratorExpressionDAGChecker dagChecker(lfbt, this->GetName(),
linkIfaceProp, 0, 0);
cmSystemTools::ExpandListArgument(ge.Parse(explicitLibraries)->Evaluate(
this->Makefile,
config,
false,
headTarget,
this, &dagChecker), iface.Libraries);
}
else if (this->PolicyStatusCMP0022 == cmPolicies::WARN
|| this->PolicyStatusCMP0022 == cmPolicies::OLD)
// If CMP0022 is NEW then the plain tll signature sets the
// INTERFACE_LINK_LIBRARIES, so if we get here then the project
// cleared the property explicitly and we should not fall back
// to the link implementation.
{
// The link implementation is the default link interface.
LinkImplementation const* impl =
this->GetLinkImplementationLibraries(config, headTarget);
iface.Libraries = impl->Libraries;
if(this->PolicyStatusCMP0022 == cmPolicies::WARN &&
!this->Internal->PolicyWarnedCMP0022)
{
// Compare the link implementation fallback link interface to the
// preferred new link interface property and warn if different.
cmListFileBacktrace lfbt;
cmGeneratorExpression ge(lfbt);
cmGeneratorExpressionDAGChecker dagChecker(lfbt, this->GetName(),
"INTERFACE_LINK_LIBRARIES", 0, 0);
std::vector<std::string> ifaceLibs;
const char* newExplicitLibraries =
this->GetProperty("INTERFACE_LINK_LIBRARIES");
cmSystemTools::ExpandListArgument(
ge.Parse(newExplicitLibraries)->Evaluate(this->Makefile,
config,
false,
headTarget,
this, &dagChecker),
ifaceLibs);
if (ifaceLibs != impl->Libraries)
{
std::string oldLibraries;
std::string newLibraries;
const char *sep = "";
for(std::vector<std::string>::const_iterator it
= impl->Libraries.begin(); it != impl->Libraries.end(); ++it)
{
oldLibraries += sep;
oldLibraries += *it;
sep = ";";
}
sep = "";
for(std::vector<std::string>::const_iterator it
= ifaceLibs.begin(); it != ifaceLibs.end(); ++it)
{
newLibraries += sep;
newLibraries += *it;
sep = ";";
}
if(oldLibraries.empty())
{ oldLibraries = "(empty)"; }
if(newLibraries.empty())
{ newLibraries = "(empty)"; }
cmOStringStream w;
w <<
(this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0022)) << "\n"
"Target \"" << this->GetName() << "\" has an "
"INTERFACE_LINK_LIBRARIES property. "
"This should be preferred as the source of the link interface "
"for this library but because CMP0022 is not set CMake is "
"ignoring the property and using the link implementation "
"as the link interface instead."
"\n"
"INTERFACE_LINK_LIBRARIES:\n"
" " << newLibraries << "\n"
"Link implementation:\n"
" " << oldLibraries << "\n";
this->Makefile->IssueMessage(cmake::AUTHOR_WARNING, w.str());
this->Internal->PolicyWarnedCMP0022 = true;
}
}
}
return explicitLibraries;
}
//----------------------------------------------------------------------------
void cmTargetInternals::ComputeLinkInterface(cmTarget const* thisTarget,
const std::string& config,
OptionalLinkInterface& iface,
cmTarget const* headTarget,
const char* explicitLibraries) const
{
if(explicitLibraries)
{
if(thisTarget->GetType() == cmTarget::SHARED_LIBRARY
|| thisTarget->GetType() == cmTarget::STATIC_LIBRARY
|| thisTarget->GetType() == cmTarget::INTERFACE_LIBRARY)
{
// Shared libraries may have runtime implementation dependencies
// on other shared libraries that are not in the interface.
std::set<std::string> emitted;
for(std::vector<std::string>::const_iterator
li = iface.Libraries.begin(); li != iface.Libraries.end(); ++li)
{
emitted.insert(*li);
}
if (thisTarget->GetType() != cmTarget::INTERFACE_LIBRARY)
{
cmTarget::LinkImplementation const* impl =
thisTarget->GetLinkImplementation(config, headTarget);
for(std::vector<std::string>::const_iterator
li = impl->Libraries.begin(); li != impl->Libraries.end(); ++li)
{
if(emitted.insert(*li).second)
{
if(cmTarget* tgt = thisTarget->Makefile->FindTargetToUse(*li))
{
// This is a runtime dependency on another shared library.
if(tgt->GetType() == cmTarget::SHARED_LIBRARY)
{
iface.SharedDeps.push_back(*li);
}
}
else
{
// TODO: Recognize shared library file names. Perhaps this
// should be moved to cmComputeLinkInformation, but that creates
// a chicken-and-egg problem since this list is needed for its
// construction.
}
}
}
if(thisTarget->LinkLanguagePropagatesToDependents())
{
// Targets using this archive need its language runtime libraries.
iface.Languages = impl->Languages;
}
}
}
}
else if (thisTarget->PolicyStatusCMP0022 == cmPolicies::WARN
|| thisTarget->PolicyStatusCMP0022 == cmPolicies::OLD)
{
// The link implementation is the default link interface.
cmTarget::LinkImplementation const*
impl = thisTarget->GetLinkImplementation(config, headTarget);
iface.ImplementationIsInterface = true;
iface.WrongConfigLibraries = impl->WrongConfigLibraries;
if(thisTarget->LinkLanguagePropagatesToDependents())
{
// Targets using this archive need its language runtime libraries.
iface.Languages = impl->Languages;
}
}
if(thisTarget->GetType() == cmTarget::STATIC_LIBRARY)
{
// Construct the property name suffix for this configuration.
std::string suffix = "_";
if(!config.empty())
{
suffix += cmSystemTools::UpperCase(config);
}
else
{
suffix += "NOCONFIG";
}
// How many repetitions are needed if this library has cyclic
// dependencies?
std::string propName = "LINK_INTERFACE_MULTIPLICITY";
propName += suffix;
if(const char* config_reps = thisTarget->GetProperty(propName.c_str()))
{
sscanf(config_reps, "%u", &iface.Multiplicity);
}
else if(const char* reps =
thisTarget->GetProperty("LINK_INTERFACE_MULTIPLICITY"))
{
sscanf(reps, "%u", &iface.Multiplicity);
}
}
iface.Complete = true;
}
//----------------------------------------------------------------------------
cmTarget::LinkImplementation const*
cmTarget::GetLinkImplementation(const std::string& config,
cmTarget const* head) const
{
// There is no link implementation for imported targets.
if(this->IsImported())
{
return 0;
}
// Lookup any existing link implementation for this configuration.
TargetConfigPair key(head, cmSystemTools::UpperCase(config));
cmTargetInternals::LinkImplMapType::iterator
i = this->Internal->LinkImplMap.find(key);
if(i == this->Internal->LinkImplMap.end())
{
// Compute the link implementation for this configuration.
LinkImplementation impl;
this->ComputeLinkImplementation(config, impl, head);
this->ComputeLinkImplementationLanguages(impl);
// Store the information for this configuration.
cmTargetInternals::LinkImplMapType::value_type entry(key, impl);
i = this->Internal->LinkImplMap.insert(entry).first;
}
else if (i->second.Languages.empty())
{
this->ComputeLinkImplementationLanguages(i->second);
}
return &i->second;
}
//----------------------------------------------------------------------------
cmTarget::LinkImplementation const*
cmTarget::GetLinkImplementationLibraries(const std::string& config,
cmTarget const* head) const
{
// There is no link implementation for imported targets.
if(this->IsImported())
{
return 0;
}
// Lookup any existing link implementation for this configuration.
TargetConfigPair key(head, cmSystemTools::UpperCase(config));
cmTargetInternals::LinkImplMapType::iterator
i = this->Internal->LinkImplMap.find(key);
if(i == this->Internal->LinkImplMap.end())
{
// Compute the link implementation for this configuration.
LinkImplementation impl;
this->ComputeLinkImplementation(config, impl, head);
// Store the information for this configuration.
cmTargetInternals::LinkImplMapType::value_type entry(key, impl);
i = this->Internal->LinkImplMap.insert(entry).first;
}
return &i->second;
}
//----------------------------------------------------------------------------
void cmTarget::ComputeLinkImplementation(const std::string& config,
LinkImplementation& impl,
cmTarget const* head) const
{
// Collect libraries directly linked in this configuration.
std::vector<std::string> llibs;
this->GetDirectLinkLibraries(config, llibs, head);
for(std::vector<std::string>::const_iterator li = llibs.begin();
li != llibs.end(); ++li)
{
// Skip entries that resolve to the target itself or are empty.
std::string item = this->CheckCMP0004(*li);
if(item == this->GetName() || item.empty())
{
2013-11-05 21:01:09 +04:00
if(item == this->GetName())
{
bool noMessage = false;
cmake::MessageType messageType = cmake::FATAL_ERROR;
cmOStringStream e;
switch(this->Makefile->GetPolicyStatus(cmPolicies::CMP0038))
{
case cmPolicies::WARN:
{
e << (this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0038)) << "\n";
messageType = cmake::AUTHOR_WARNING;
}
break;
case cmPolicies::OLD:
noMessage = true;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::NEW:
// Issue the fatal message.
break;
}
if(!noMessage)
{
e << "Target \"" << this->GetName() << "\" links to itself.";
this->Makefile->GetCMakeInstance()->IssueMessage(messageType,
e.str(),
this->GetBacktrace());
if (messageType == cmake::FATAL_ERROR)
{
return;
}
}
}
continue;
}
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// The entry is meant for this configuration.
impl.Libraries.push_back(item);
}
cmTarget::LinkLibraryType linkType = this->ComputeLinkType(config);
LinkLibraryVectorType const& oldllibs = this->GetOriginalLinkLibraries();
for(cmTarget::LinkLibraryVectorType::const_iterator li = oldllibs.begin();
li != oldllibs.end(); ++li)
{
if(li->second != cmTarget::GENERAL && li->second != linkType)
{
std::string item = this->CheckCMP0004(li->first);
if(item == this->GetName() || item.empty())
{
continue;
}
// Support OLD behavior for CMP0003.
impl.WrongConfigLibraries.push_back(item);
}
}
}
//----------------------------------------------------------------------------
void
cmTarget::ComputeLinkImplementationLanguages(LinkImplementation& impl) const
{
// This target needs runtime libraries for its source languages.
std::set<std::string> languages;
// Get languages used in our source files.
this->GetLanguages(languages);
// Get languages used in object library sources.
for(std::vector<std::string>::const_iterator
i = this->ObjectLibraries.begin();
i != this->ObjectLibraries.end(); ++i)
{
if(cmTarget* objLib = this->Makefile->FindTargetToUse(*i))
{
if(objLib->GetType() == cmTarget::OBJECT_LIBRARY)
{
objLib->GetLanguages(languages);
}
}
}
// Copy the set of langauges to the link implementation.
for(std::set<std::string>::iterator li = languages.begin();
li != languages.end(); ++li)
{
impl.Languages.push_back(*li);
}
}
//----------------------------------------------------------------------------
std::string cmTarget::CheckCMP0004(std::string const& item) const
{
// Strip whitespace off the library names because we used to do this
// in case variables were expanded at generate time. We no longer
// do the expansion but users link to libraries like " ${VAR} ".
std::string lib = item;
std::string::size_type pos = lib.find_first_not_of(" \t\r\n");
if(pos != lib.npos)
{
lib = lib.substr(pos, lib.npos);
}
pos = lib.find_last_not_of(" \t\r\n");
if(pos != lib.npos)
{
lib = lib.substr(0, pos+1);
}
if(lib != item)
{
cmake* cm = this->Makefile->GetCMakeInstance();
switch(this->PolicyStatusCMP0004)
{
case cmPolicies::WARN:
{
cmOStringStream w;
w << (this->Makefile->GetPolicies()
->GetPolicyWarning(cmPolicies::CMP0004)) << "\n"
<< "Target \"" << this->GetName() << "\" links to item \""
<< item << "\" which has leading or trailing whitespace.";
cm->IssueMessage(cmake::AUTHOR_WARNING, w.str(),
this->GetBacktrace());
}
case cmPolicies::OLD:
break;
case cmPolicies::NEW:
{
cmOStringStream e;
e << "Target \"" << this->GetName() << "\" links to item \""
<< item << "\" which has leading or trailing whitespace. "
<< "This is now an error according to policy CMP0004.";
cm->IssueMessage(cmake::FATAL_ERROR, e.str(), this->GetBacktrace());
}
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
{
cmOStringStream e;
e << (this->Makefile->GetPolicies()
->GetRequiredPolicyError(cmPolicies::CMP0004)) << "\n"
<< "Target \"" << this->GetName() << "\" links to item \""
<< item << "\" which has leading or trailing whitespace.";
cm->IssueMessage(cmake::FATAL_ERROR, e.str(), this->GetBacktrace());
}
break;
}
}
return lib;
}
template<typename PropertyType>
PropertyType getLinkInterfaceDependentProperty(cmTarget const* tgt,
const std::string& prop,
const std::string& config,
CompatibleType,
PropertyType *);
template<>
bool getLinkInterfaceDependentProperty(cmTarget const* tgt,
const std::string& prop,
const std::string& config,
CompatibleType, bool *)
{
return tgt->GetLinkInterfaceDependentBoolProperty(prop, config);
}
template<>
const char * getLinkInterfaceDependentProperty(cmTarget const* tgt,
const std::string& prop,
const std::string& config,
CompatibleType t,
const char **)
{
switch(t)
{
case BoolType:
assert(!"String compatibility check function called for boolean");
return 0;
case StringType:
return tgt->GetLinkInterfaceDependentStringProperty(prop, config);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
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case NumberMinType:
return tgt->GetLinkInterfaceDependentNumberMinProperty(prop, config);
case NumberMaxType:
return tgt->GetLinkInterfaceDependentNumberMaxProperty(prop, config);
}
assert(!"Unreachable!");
return 0;
}
//----------------------------------------------------------------------------
template<typename PropertyType>
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void checkPropertyConsistency(cmTarget const* depender,
cmTarget const* dependee,
const std::string& propName,
std::set<std::string> &emitted,
const std::string& config,
CompatibleType t,
PropertyType *)
{
const char *prop = dependee->GetProperty(propName);
if (!prop)
{
return;
}
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(prop, props);
std::string pdir =
dependee->GetMakefile()->GetRequiredDefinition("CMAKE_ROOT");
pdir += "/Help/prop_tgt/";
for(std::vector<std::string>::iterator pi = props.begin();
pi != props.end(); ++pi)
{
std::string pname = cmSystemTools::HelpFileName(*pi);
std::string pfile = pdir + pname + ".rst";
if(cmSystemTools::FileExists(pfile.c_str(), true))
{
cmOStringStream e;
e << "Target \"" << dependee->GetName() << "\" has property \""
<< *pi << "\" listed in its " << propName << " property. "
"This is not allowed. Only user-defined properties may appear "
"listed in the " << propName << " property.";
depender->GetMakefile()->IssueMessage(cmake::FATAL_ERROR, e.str());
return;
}
if(emitted.insert(*pi).second)
{
getLinkInterfaceDependentProperty<PropertyType>(depender, *pi, config,
t, 0);
if (cmSystemTools::GetErrorOccuredFlag())
{
return;
}
}
}
}
static std::string intersect(const std::set<std::string> &s1,
const std::set<std::string> &s2)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
std::set<std::string> intersect;
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
std::set_intersection(s1.begin(),s1.end(),
s2.begin(),s2.end(),
std::inserter(intersect,intersect.begin()));
if (!intersect.empty())
{
return *intersect.begin();
}
return "";
}
static std::string intersect(const std::set<std::string> &s1,
const std::set<std::string> &s2,
const std::set<std::string> &s3)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
std::string result;
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
result = intersect(s1, s2);
if (!result.empty())
return result;
result = intersect(s1, s3);
if (!result.empty())
return result;
return intersect(s2, s3);
}
static std::string intersect(const std::set<std::string> &s1,
const std::set<std::string> &s2,
const std::set<std::string> &s3,
const std::set<std::string> &s4)
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
{
std::string result;
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
result = intersect(s1, s2);
if (!result.empty())
return result;
result = intersect(s1, s3);
if (!result.empty())
return result;
result = intersect(s1, s4);
if (!result.empty())
return result;
return intersect(s2, s3, s4);
}
//----------------------------------------------------------------------------
void cmTarget::CheckPropertyCompatibility(cmComputeLinkInformation *info,
const std::string& config) const
{
const cmComputeLinkInformation::ItemVector &deps = info->GetItems();
std::set<std::string> emittedBools;
std::set<std::string> emittedStrings;
std::set<std::string> emittedMinNumbers;
std::set<std::string> emittedMaxNumbers;
for(cmComputeLinkInformation::ItemVector::const_iterator li =
deps.begin();
li != deps.end(); ++li)
{
if (!li->Target)
{
continue;
}
checkPropertyConsistency<bool>(this, li->Target,
std::string("COMPATIBLE_INTERFACE_BOOL"),
emittedBools, config, BoolType, 0);
if (cmSystemTools::GetErrorOccuredFlag())
{
return;
}
checkPropertyConsistency<const char *>(this, li->Target,
std::string("COMPATIBLE_INTERFACE_STRING"),
emittedStrings, config,
StringType, 0);
if (cmSystemTools::GetErrorOccuredFlag())
{
return;
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
checkPropertyConsistency<const char *>(this, li->Target,
std::string("COMPATIBLE_INTERFACE_NUMBER_MIN"),
emittedMinNumbers, config,
NumberMinType, 0);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
if (cmSystemTools::GetErrorOccuredFlag())
{
return;
}
checkPropertyConsistency<const char *>(this, li->Target,
std::string("COMPATIBLE_INTERFACE_NUMBER_MAX"),
emittedMaxNumbers, config,
NumberMaxType, 0);
if (cmSystemTools::GetErrorOccuredFlag())
{
return;
}
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
std::string prop = intersect(emittedBools,
emittedStrings,
emittedMinNumbers,
emittedMaxNumbers);
if (!prop.empty())
{
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
std::set<std::string> props;
std::set<std::string>::const_iterator i = emittedBools.find(prop);
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
if (i != emittedBools.end())
{
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
props.insert("COMPATIBLE_INTERFACE_BOOL");
}
i = emittedStrings.find(prop);
if (i != emittedStrings.end())
{
props.insert("COMPATIBLE_INTERFACE_STRING");
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
i = emittedMinNumbers.find(prop);
if (i != emittedMinNumbers.end())
{
props.insert("COMPATIBLE_INTERFACE_NUMBER_MIN");
}
i = emittedMaxNumbers.find(prop);
if (i != emittedMaxNumbers.end())
{
props.insert("COMPATIBLE_INTERFACE_NUMBER_MAX");
}
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
std::string propsString = *props.begin();
props.erase(props.begin());
while (props.size() > 1)
{
propsString += ", " + *props.begin();
props.erase(props.begin());
}
if (props.size() == 1)
{
propsString += " and the " + *props.begin();
}
cmOStringStream e;
e << "Property \"" << prop << "\" appears in both the "
<< propsString <<
" property in the dependencies of target \"" << this->GetName() <<
"\". This is not allowed. A property may only require compatibility "
"in a boolean interpretation, a numeric minimum, a numeric maximum or a "
"string interpretation, but not a mixture.";
cmTarget: Add interface for compatible numeric properties When using the boost MPL library, one can set a define to increase the limit of how many variadic elements should be supported. The default for BOOST_MPL_LIMIT_VECTOR_SIZE is 20: http://www.boost.org/doc/libs/1_36_0/libs/mpl/doc/refmanual/limit-vector-size.html If the foo library requires that to be set to 30, and the independent bar library requires it to be set to 40, consumers of both need to set it to 40. add_library(foo INTERFACE) set_property(TARGET foo PROPERTY INTERFACE_boost_mpl_vector_size 30) set_property(TARGET foo PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(foo INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_library(bar INTERFACE) set_property(TARGET bar PROPERTY INTERFACE_boost_mpl_vector_size 40) # Technically the next two lines are redundant, but as foo and bar are # independent, they both set these interfaces. set_property(TARGET bar PROPERTY COMPATIBLE_INTERFACE_NUMBER_MAX boost_mpl_vector_size) target_compile_definitions(bar INTERFACE BOOST_MPL_LIMIT_VECTOR_SIZE=$<TARGET_PROPERTY:boost_mpl_vector_size>) add_executable(user) target_link_libraries(user foo bar) Because the TARGET_PROPERTY reads the boost_mpl_vector_size property from the HEAD of the dependency graph (the user target), and because that property appears in the COMPATIBLE_INTERFACE_NUMBER_MAX of the dependencies of the user target, the maximum value for it is chosen for the compile definition, ie, 40. There are also use-cases for choosing the minimum value of a number. In Qt, deprecated API can be disabled by version. Setting the definition QT_DISABLE_DEPRECATED_BEFORE=0 disables no deprecated API. Setting it to 0x501000 disables API which was deprecated before Qt 5.1 etc. If two dependencies require the use of API which was deprecated in different Qt versions, then COMPATIBLE_INTERFACE_NUMBER_MIN can be used to ensure that both can compile.
2013-10-22 21:51:36 +04:00
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str());
}
}
//----------------------------------------------------------------------------
cmComputeLinkInformation*
cmTarget::GetLinkInformation(const std::string& config,
cmTarget const* head) const
{
cmTarget const* headTarget = head ? head : this;
// Lookup any existing information for this configuration.
TargetConfigPair key(headTarget, cmSystemTools::UpperCase(config));
cmTargetLinkInformationMap::iterator
i = this->LinkInformation.find(key);
if(i == this->LinkInformation.end())
{
// Compute information for this configuration.
cmComputeLinkInformation* info =
new cmComputeLinkInformation(this, config, headTarget);
if(!info || !info->Compute())
{
delete info;
info = 0;
}
// Store the information for this configuration.
cmTargetLinkInformationMap::value_type entry(key, info);
i = this->LinkInformation.insert(entry).first;
if (info)
{
this->CheckPropertyCompatibility(info, config);
}
}
return i->second;
}
//----------------------------------------------------------------------------
std::string cmTarget::GetFrameworkDirectory(const std::string& config,
bool rootDir) const
{
std::string fpath;
fpath += this->GetOutputName(config, false);
fpath += ".framework";
if(!rootDir)
{
fpath += "/Versions/";
fpath += this->GetFrameworkVersion();
}
return fpath;
}
//----------------------------------------------------------------------------
std::string cmTarget::GetCFBundleDirectory(const std::string& config,
bool contentOnly) const
{
std::string fpath;
fpath += this->GetOutputName(config, false);
fpath += ".";
const char *ext = this->GetProperty("BUNDLE_EXTENSION");
if (!ext)
{
ext = "bundle";
}
fpath += ext;
fpath += "/Contents";
if(!contentOnly)
fpath += "/MacOS";
return fpath;
}
//----------------------------------------------------------------------------
std::string cmTarget::GetAppBundleDirectory(const std::string& config,
bool contentOnly) const
{
std::string fpath = this->GetFullName(config, false);
fpath += ".app/Contents";
if(!contentOnly)
fpath += "/MacOS";
return fpath;
}
//----------------------------------------------------------------------------
std::string cmTarget::BuildMacContentDirectory(const std::string& base,
const std::string& config,
bool contentOnly) const
{
std::string fpath = base;
if(this->IsAppBundleOnApple())
{
fpath += this->GetAppBundleDirectory(config, contentOnly);
}
if(this->IsFrameworkOnApple())
{
fpath += this->GetFrameworkDirectory(config, contentOnly);
}
if(this->IsCFBundleOnApple())
{
fpath += this->GetCFBundleDirectory(config, contentOnly);
}
return fpath;
}
//----------------------------------------------------------------------------
std::string cmTarget::GetMacContentDirectory(const std::string& config,
2013-11-04 01:26:26 +04:00
bool implib) const
{
// Start with the output directory for the target.
std::string fpath = this->GetDirectory(config, implib);
fpath += "/";
bool contentOnly = true;
if(this->IsFrameworkOnApple())
{
// additional files with a framework go into the version specific
// directory
contentOnly = false;
}
fpath = this->BuildMacContentDirectory(fpath, config, contentOnly);
return fpath;
}
//----------------------------------------------------------------------------
cmTargetLinkInformationMap
::cmTargetLinkInformationMap(cmTargetLinkInformationMap const& r): derived()
{
// Ideally cmTarget instances should never be copied. However until
// we can make a sweep to remove that, this copy constructor avoids
// allowing the resources (LinkInformation) from getting copied. In
// the worst case this will lead to extra cmComputeLinkInformation
// instances. We also enforce in debug mode that the map be emptied
// when copied.
static_cast<void>(r);
assert(r.empty());
}
//----------------------------------------------------------------------------
cmTargetLinkInformationMap::~cmTargetLinkInformationMap()
{
for(derived::iterator i = this->begin(); i != this->end(); ++i)
{
delete i->second;
}
}
//----------------------------------------------------------------------------
cmTargetInternalPointer::cmTargetInternalPointer()
{
this->Pointer = new cmTargetInternals;
}
//----------------------------------------------------------------------------
cmTargetInternalPointer
::cmTargetInternalPointer(cmTargetInternalPointer const& r)
{
// Ideally cmTarget instances should never be copied. However until
// we can make a sweep to remove that, this copy constructor avoids
// allowing the resources (Internals) to be copied.
this->Pointer = new cmTargetInternals(*r.Pointer);
}
//----------------------------------------------------------------------------
cmTargetInternalPointer::~cmTargetInternalPointer()
{
deleteAndClear(this->Pointer->IncludeDirectoriesEntries);
deleteAndClear(this->Pointer->CompileOptionsEntries);
deleteAndClear(this->Pointer->CompileDefinitionsEntries);
delete this->Pointer;
}
//----------------------------------------------------------------------------
cmTargetInternalPointer&
cmTargetInternalPointer::operator=(cmTargetInternalPointer const& r)
{
if(this == &r) { return *this; } // avoid warning on HP about self check
// Ideally cmTarget instances should never be copied. However until
// we can make a sweep to remove that, this copy constructor avoids
// allowing the resources (Internals) to be copied.
cmTargetInternals* oldPointer = this->Pointer;
this->Pointer = new cmTargetInternals(*r.Pointer);
delete oldPointer;
return *this;
}