/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying file Copyright.txt or https://cmake.org/licensing for details. */ #include "cmGlobalVisualStudioGenerator.h" #include #include #include #include #include #include #include #include "cmsys/Encoding.hxx" #include "cmCallVisualStudioMacro.h" #include "cmCustomCommand.h" #include "cmCustomCommandLines.h" #include "cmGeneratedFileStream.h" #include "cmGeneratorTarget.h" #include "cmLocalVisualStudioGenerator.h" #include "cmMakefile.h" #include "cmSourceFile.h" #include "cmState.h" #include "cmTarget.h" #include "cmake.h" cmGlobalVisualStudioGenerator::cmGlobalVisualStudioGenerator( cmake* cm, std::string const& platformInGeneratorName) : cmGlobalGenerator(cm) { cm->GetState()->SetIsGeneratorMultiConfig(true); cm->GetState()->SetWindowsShell(true); cm->GetState()->SetWindowsVSIDE(true); if (platformInGeneratorName.empty()) { this->DefaultPlatformName = "Win32"; } else { this->DefaultPlatformName = platformInGeneratorName; this->PlatformInGeneratorName = true; } } cmGlobalVisualStudioGenerator::~cmGlobalVisualStudioGenerator() { } cmGlobalVisualStudioGenerator::VSVersion cmGlobalVisualStudioGenerator::GetVersion() const { return this->Version; } void cmGlobalVisualStudioGenerator::SetVersion(VSVersion v) { this->Version = v; } void cmGlobalVisualStudioGenerator::EnableLanguage( std::vector const& lang, cmMakefile* mf, bool optional) { mf->AddDefinition("CMAKE_VS_PLATFORM_NAME_DEFAULT", this->DefaultPlatformName); this->cmGlobalGenerator::EnableLanguage(lang, mf, optional); } bool cmGlobalVisualStudioGenerator::SetGeneratorPlatform(std::string const& p, cmMakefile* mf) { if (this->GetPlatformName() == "x64") { mf->AddDefinition("CMAKE_FORCE_WIN64", "TRUE"); } else if (this->GetPlatformName() == "Itanium") { mf->AddDefinition("CMAKE_FORCE_IA64", "TRUE"); } mf->AddDefinition("CMAKE_VS_PLATFORM_NAME", this->GetPlatformName()); return this->cmGlobalGenerator::SetGeneratorPlatform(p, mf); } std::string const& cmGlobalVisualStudioGenerator::GetPlatformName() const { if (!this->GeneratorPlatform.empty()) { return this->GeneratorPlatform; } return this->DefaultPlatformName; } const char* cmGlobalVisualStudioGenerator::GetIDEVersion() const { switch (this->Version) { case cmGlobalVisualStudioGenerator::VS9: return "9.0"; case cmGlobalVisualStudioGenerator::VS10: return "10.0"; case cmGlobalVisualStudioGenerator::VS11: return "11.0"; case cmGlobalVisualStudioGenerator::VS12: return "12.0"; case cmGlobalVisualStudioGenerator::VS14: return "14.0"; case cmGlobalVisualStudioGenerator::VS15: return "15.0"; case cmGlobalVisualStudioGenerator::VS16: return "16.0"; } return ""; } void cmGlobalVisualStudioGenerator::WriteSLNHeader(std::ostream& fout) { char utf8bom[] = { char(0xEF), char(0xBB), char(0xBF) }; fout.write(utf8bom, 3); fout << '\n'; switch (this->Version) { case cmGlobalVisualStudioGenerator::VS9: fout << "Microsoft Visual Studio Solution File, Format Version 10.00\n"; fout << "# Visual Studio 2008\n"; break; case cmGlobalVisualStudioGenerator::VS10: fout << "Microsoft Visual Studio Solution File, Format Version 11.00\n"; if (this->ExpressEdition) { fout << "# Visual C++ Express 2010\n"; } else { fout << "# Visual Studio 2010\n"; } break; case cmGlobalVisualStudioGenerator::VS11: fout << "Microsoft Visual Studio Solution File, Format Version 12.00\n"; if (this->ExpressEdition) { fout << "# Visual Studio Express 2012 for Windows Desktop\n"; } else { fout << "# Visual Studio 2012\n"; } break; case cmGlobalVisualStudioGenerator::VS12: fout << "Microsoft Visual Studio Solution File, Format Version 12.00\n"; if (this->ExpressEdition) { fout << "# Visual Studio Express 2013 for Windows Desktop\n"; } else { fout << "# Visual Studio 2013\n"; } break; case cmGlobalVisualStudioGenerator::VS14: // Visual Studio 14 writes .sln format 12.00 fout << "Microsoft Visual Studio Solution File, Format Version 12.00\n"; if (this->ExpressEdition) { fout << "# Visual Studio Express 14 for Windows Desktop\n"; } else { fout << "# Visual Studio 14\n"; } break; case cmGlobalVisualStudioGenerator::VS15: // Visual Studio 15 writes .sln format 12.00 fout << "Microsoft Visual Studio Solution File, Format Version 12.00\n"; if (this->ExpressEdition) { fout << "# Visual Studio Express 15 for Windows Desktop\n"; } else { fout << "# Visual Studio 15\n"; } break; case cmGlobalVisualStudioGenerator::VS16: // Visual Studio 16 writes .sln format 12.00 fout << "Microsoft Visual Studio Solution File, Format Version 12.00\n"; if (this->ExpressEdition) { fout << "# Visual Studio Express 16 for Windows Desktop\n"; } else { fout << "# Visual Studio Version 16\n"; } break; } } std::string cmGlobalVisualStudioGenerator::GetRegistryBase() { return cmGlobalVisualStudioGenerator::GetRegistryBase(this->GetIDEVersion()); } std::string cmGlobalVisualStudioGenerator::GetRegistryBase(const char* version) { std::string key = "HKEY_LOCAL_MACHINE\\SOFTWARE\\Microsoft\\VisualStudio\\"; return key + version; } void cmGlobalVisualStudioGenerator::AddExtraIDETargets() { // Add a special target that depends on ALL projects for easy build // of one configuration only. const char* no_working_dir = nullptr; std::vector no_byproducts; std::vector no_depends; cmCustomCommandLines no_commands; for (auto const& it : this->ProjectMap) { std::vector const& gen = it.second; // add the ALL_BUILD to the first local generator of each project if (!gen.empty()) { // Use no actual command lines so that the target itself is not // considered always out of date. cmTarget* allBuild = gen[0]->AddUtilityCommand( "ALL_BUILD", true, no_working_dir, no_byproducts, no_depends, no_commands, false, "Build all projects"); gen[0]->AddGeneratorTarget( cm::make_unique(allBuild, gen[0])); // // Organize in the "predefined targets" folder: // if (this->UseFolderProperty()) { allBuild->SetProperty("FOLDER", this->GetPredefinedTargetsFolder()); } // Now make all targets depend on the ALL_BUILD target for (cmLocalGenerator const* i : gen) { for (const auto& tgt : i->GetGeneratorTargets()) { if (tgt->GetType() == cmStateEnums::GLOBAL_TARGET || tgt->IsImported()) { continue; } if (!this->IsExcluded(gen[0], tgt.get())) { allBuild->AddUtility(tgt->GetName(), false); } } } } } // Configure CMake Visual Studio macros, for this user on this version // of Visual Studio. this->ConfigureCMakeVisualStudioMacros(); } void cmGlobalVisualStudioGenerator::ComputeTargetObjectDirectory( cmGeneratorTarget* gt) const { std::string dir = cmStrCat(gt->LocalGenerator->GetCurrentBinaryDirectory(), '/'); std::string tgtDir = gt->LocalGenerator->GetTargetDirectory(gt); if (!tgtDir.empty()) { dir += tgtDir; dir += "/"; } const char* cd = this->GetCMakeCFGIntDir(); if (cd && *cd) { dir += cd; dir += "/"; } gt->ObjectDirectory = dir; } bool IsVisualStudioMacrosFileRegistered(const std::string& macrosFile, const std::string& regKeyBase, std::string& nextAvailableSubKeyName); void RegisterVisualStudioMacros(const std::string& macrosFile, const std::string& regKeyBase); #define CMAKE_VSMACROS_FILENAME "CMakeVSMacros2.vsmacros" #define CMAKE_VSMACROS_RELOAD_MACRONAME \ "Macros.CMakeVSMacros2.Macros.ReloadProjects" #define CMAKE_VSMACROS_STOP_MACRONAME "Macros.CMakeVSMacros2.Macros.StopBuild" void cmGlobalVisualStudioGenerator::ConfigureCMakeVisualStudioMacros() { std::string dir = this->GetUserMacrosDirectory(); if (!dir.empty()) { std::string src = cmStrCat(cmSystemTools::GetCMakeRoot(), "/Templates/" CMAKE_VSMACROS_FILENAME); std::string dst = dir + "/CMakeMacros/" CMAKE_VSMACROS_FILENAME; // Copy the macros file to the user directory only if the // destination does not exist or the source location is newer. // This will allow the user to edit the macros for development // purposes but newer versions distributed with CMake will replace // older versions in user directories. int res; if (!cmSystemTools::FileTimeCompare(src, dst, &res) || res > 0) { if (!cmSystemTools::CopyFileAlways(src, dst)) { std::ostringstream oss; oss << "Could not copy from: " << src << std::endl; oss << " to: " << dst << std::endl; cmSystemTools::Message(oss.str(), "Warning"); } } RegisterVisualStudioMacros(dst, this->GetUserMacrosRegKeyBase()); } } void cmGlobalVisualStudioGenerator::CallVisualStudioMacro( MacroName m, const std::string& vsSolutionFile) { // If any solution or project files changed during the generation, // tell Visual Studio to reload them... std::string dir = this->GetUserMacrosDirectory(); // Only really try to call the macro if: // - there is a UserMacrosDirectory // - the CMake vsmacros file exists // - the CMake vsmacros file is registered // - there were .sln/.vcproj files changed during generation // if (!dir.empty()) { std::string macrosFile = dir + "/CMakeMacros/" CMAKE_VSMACROS_FILENAME; std::string nextSubkeyName; if (cmSystemTools::FileExists(macrosFile) && IsVisualStudioMacrosFileRegistered( macrosFile, this->GetUserMacrosRegKeyBase(), nextSubkeyName)) { if (m == MacroReload) { std::vector filenames; this->GetFilesReplacedDuringGenerate(filenames); if (!filenames.empty()) { std::string projects = cmJoin(filenames, ";"); cmCallVisualStudioMacro::CallMacro( vsSolutionFile, CMAKE_VSMACROS_RELOAD_MACRONAME, projects, this->GetCMakeInstance()->GetDebugOutput()); } } else if (m == MacroStop) { cmCallVisualStudioMacro::CallMacro( vsSolutionFile, CMAKE_VSMACROS_STOP_MACRONAME, "", this->GetCMakeInstance()->GetDebugOutput()); } } } } std::string cmGlobalVisualStudioGenerator::GetUserMacrosDirectory() { return ""; } std::string cmGlobalVisualStudioGenerator::GetUserMacrosRegKeyBase() { return ""; } void cmGlobalVisualStudioGenerator::FillLinkClosure( const cmGeneratorTarget* target, TargetSet& linked) { if (linked.insert(target).second) { TargetDependSet const& depends = this->GetTargetDirectDepends(target); for (cmTargetDepend const& di : depends) { if (di.IsLink()) { this->FillLinkClosure(di, linked); } } } } cmGlobalVisualStudioGenerator::TargetSet const& cmGlobalVisualStudioGenerator::GetTargetLinkClosure(cmGeneratorTarget* target) { auto i = this->TargetLinkClosure.find(target); if (i == this->TargetLinkClosure.end()) { TargetSetMap::value_type entry(target, TargetSet()); i = this->TargetLinkClosure.insert(entry).first; this->FillLinkClosure(target, i->second); } return i->second; } void cmGlobalVisualStudioGenerator::FollowLinkDepends( const cmGeneratorTarget* target, std::set& linked) { if (target->GetType() == cmStateEnums::INTERFACE_LIBRARY) { return; } if (linked.insert(target).second && target->GetType() == cmStateEnums::STATIC_LIBRARY) { // Static library targets do not list their link dependencies so // we must follow them transitively now. TargetDependSet const& depends = this->GetTargetDirectDepends(target); for (cmTargetDepend const& di : depends) { if (di.IsLink()) { this->FollowLinkDepends(di, linked); } } } } bool cmGlobalVisualStudioGenerator::ComputeTargetDepends() { if (!this->cmGlobalGenerator::ComputeTargetDepends()) { return false; } for (auto const& it : this->ProjectMap) { for (const cmLocalGenerator* i : it.second) { for (const auto& ti : i->GetGeneratorTargets()) { this->ComputeVSTargetDepends(ti.get()); } } } return true; } static bool VSLinkable(cmGeneratorTarget const* t) { return t->IsLinkable() || t->GetType() == cmStateEnums::OBJECT_LIBRARY; } void cmGlobalVisualStudioGenerator::ComputeVSTargetDepends( cmGeneratorTarget* target) { if (this->VSTargetDepends.find(target) != this->VSTargetDepends.end()) { return; } VSDependSet& vsTargetDepend = this->VSTargetDepends[target]; // VS <= 7.1 has two behaviors that affect solution dependencies. // // (1) Solution-level dependencies between a linkable target and a // library cause that library to be linked. We use an intermedite // empty utility target to express the dependency. (VS 8 and above // provide a project file "LinkLibraryDependencies" setting to // choose whether to activate this behavior. We disable it except // when linking external project files.) // // (2) We cannot let static libraries depend directly on targets to // which they "link" because the librarian tool will copy the // targets into the static library. While the work-around for // behavior (1) would also avoid this, it would create a large // number of extra utility targets for little gain. Instead, use // the above work-around only for dependencies explicitly added by // the add_dependencies() command. Approximate link dependencies by // leaving them out for the static library itself but following them // transitively for other targets. bool allowLinkable = (target->GetType() != cmStateEnums::STATIC_LIBRARY && target->GetType() != cmStateEnums::SHARED_LIBRARY && target->GetType() != cmStateEnums::MODULE_LIBRARY && target->GetType() != cmStateEnums::EXECUTABLE); TargetDependSet const& depends = this->GetTargetDirectDepends(target); // Collect implicit link dependencies (target_link_libraries). // Static libraries cannot depend on their link implementation // due to behavior (2), but they do not really need to. std::set linkDepends; if (target->GetType() != cmStateEnums::STATIC_LIBRARY) { for (cmTargetDepend const& di : depends) { if (di.IsLink()) { this->FollowLinkDepends(di, linkDepends); } } } // Collect explicit util dependencies (add_dependencies). std::set utilDepends; for (cmTargetDepend const& di : depends) { if (di.IsUtil()) { this->FollowLinkDepends(di, utilDepends); } } // Collect all targets linked by this target so we can avoid // intermediate targets below. TargetSet linked; if (target->GetType() != cmStateEnums::STATIC_LIBRARY) { linked = this->GetTargetLinkClosure(target); } // Emit link dependencies. for (cmGeneratorTarget const* dep : linkDepends) { vsTargetDepend.insert(dep->GetName()); } // Emit util dependencies. Possibly use intermediate targets. for (cmGeneratorTarget const* dgt : utilDepends) { if (allowLinkable || !VSLinkable(dgt) || linked.count(dgt)) { // Direct dependency allowed. vsTargetDepend.insert(dgt->GetName()); } else { // Direct dependency on linkable target not allowed. // Use an intermediate utility target. vsTargetDepend.insert(this->GetUtilityDepend(dgt)); } } } bool cmGlobalVisualStudioGenerator::FindMakeProgram(cmMakefile* mf) { // Visual Studio generators know how to lookup their build tool // directly instead of needing a helper module to do it, so we // do not actually need to put CMAKE_MAKE_PROGRAM into the cache. if (cmIsOff(mf->GetDefinition("CMAKE_MAKE_PROGRAM"))) { mf->AddDefinition("CMAKE_MAKE_PROGRAM", this->GetVSMakeProgram()); } return true; } std::string cmGlobalVisualStudioGenerator::GetUtilityDepend( cmGeneratorTarget const* target) { auto i = this->UtilityDepends.find(target); if (i == this->UtilityDepends.end()) { std::string name = this->WriteUtilityDepend(target); UtilityDependsMap::value_type entry(target, name); i = this->UtilityDepends.insert(entry).first; } return i->second; } std::string cmGlobalVisualStudioGenerator::GetStartupProjectName( cmLocalGenerator const* root) const { cmProp n = root->GetMakefile()->GetProperty("VS_STARTUP_PROJECT"); if (n && !n->empty()) { std::string startup = *n; if (this->FindTarget(startup)) { return startup; } else { root->GetMakefile()->IssueMessage( MessageType::AUTHOR_WARNING, "Directory property VS_STARTUP_PROJECT specifies target " "'" + startup + "' that does not exist. Ignoring."); } } // default, if not specified return this->GetAllTargetName(); } bool IsVisualStudioMacrosFileRegistered(const std::string& macrosFile, const std::string& regKeyBase, std::string& nextAvailableSubKeyName) { bool macrosRegistered = false; std::string s1; std::string s2; // Make lowercase local copies, convert to Unix slashes, and // see if the resulting strings are the same: s1 = cmSystemTools::LowerCase(macrosFile); cmSystemTools::ConvertToUnixSlashes(s1); std::string keyname; HKEY hkey = NULL; LONG result = ERROR_SUCCESS; DWORD index = 0; keyname = regKeyBase + "\\OtherProjects7"; hkey = NULL; result = RegOpenKeyExW(HKEY_CURRENT_USER, cmsys::Encoding::ToWide(keyname).c_str(), 0, KEY_READ, &hkey); if (ERROR_SUCCESS == result) { // Iterate the subkeys and look for the values of interest in each subkey: wchar_t subkeyname[256]; DWORD cch_subkeyname = cm::size(subkeyname); wchar_t keyclass[256]; DWORD cch_keyclass = cm::size(keyclass); FILETIME lastWriteTime; lastWriteTime.dwHighDateTime = 0; lastWriteTime.dwLowDateTime = 0; while (ERROR_SUCCESS == RegEnumKeyExW(hkey, index, subkeyname, &cch_subkeyname, 0, keyclass, &cch_keyclass, &lastWriteTime)) { // Open the subkey and query the values of interest: HKEY hsubkey = NULL; result = RegOpenKeyExW(hkey, subkeyname, 0, KEY_READ, &hsubkey); if (ERROR_SUCCESS == result) { DWORD valueType = REG_SZ; wchar_t data1[256]; DWORD cch_data1 = sizeof(data1); RegQueryValueExW(hsubkey, L"Path", 0, &valueType, (LPBYTE)data1, &cch_data1); DWORD data2 = 0; DWORD cch_data2 = sizeof(data2); RegQueryValueExW(hsubkey, L"Security", 0, &valueType, (LPBYTE)&data2, &cch_data2); DWORD data3 = 0; DWORD cch_data3 = sizeof(data3); RegQueryValueExW(hsubkey, L"StorageFormat", 0, &valueType, (LPBYTE)&data3, &cch_data3); s2 = cmSystemTools::LowerCase(cmsys::Encoding::ToNarrow(data1)); cmSystemTools::ConvertToUnixSlashes(s2); if (s2 == s1) { macrosRegistered = true; } std::string fullname = cmsys::Encoding::ToNarrow(data1); std::string filename; std::string filepath; std::string filepathname; std::string filepathpath; if (cmSystemTools::FileExists(fullname)) { filename = cmSystemTools::GetFilenameName(fullname); filepath = cmSystemTools::GetFilenamePath(fullname); filepathname = cmSystemTools::GetFilenameName(filepath); filepathpath = cmSystemTools::GetFilenamePath(filepath); } // std::cout << keyname << "\\" << subkeyname << ":" << std::endl; // std::cout << " Path: " << data1 << std::endl; // std::cout << " Security: " << data2 << std::endl; // std::cout << " StorageFormat: " << data3 << std::endl; // std::cout << " filename: " << filename << std::endl; // std::cout << " filepath: " << filepath << std::endl; // std::cout << " filepathname: " << filepathname << std::endl; // std::cout << " filepathpath: " << filepathpath << std::endl; // std::cout << std::endl; RegCloseKey(hsubkey); } else { std::cout << "error opening subkey: " << subkeyname << std::endl; std::cout << std::endl; } ++index; cch_subkeyname = cm::size(subkeyname); cch_keyclass = cm::size(keyclass); lastWriteTime.dwHighDateTime = 0; lastWriteTime.dwLowDateTime = 0; } RegCloseKey(hkey); } else { std::cout << "error opening key: " << keyname << std::endl; std::cout << std::endl; } // Pass back next available sub key name, assuming sub keys always // follow the expected naming scheme. Expected naming scheme is that // the subkeys of OtherProjects7 is 0 to n-1, so it's ok to use "n" // as the name of the next subkey. nextAvailableSubKeyName = std::to_string(index); keyname = regKeyBase + "\\RecordingProject7"; hkey = NULL; result = RegOpenKeyExW(HKEY_CURRENT_USER, cmsys::Encoding::ToWide(keyname).c_str(), 0, KEY_READ, &hkey); if (ERROR_SUCCESS == result) { DWORD valueType = REG_SZ; wchar_t data1[256]; DWORD cch_data1 = sizeof(data1); RegQueryValueExW(hkey, L"Path", 0, &valueType, (LPBYTE)data1, &cch_data1); DWORD data2 = 0; DWORD cch_data2 = sizeof(data2); RegQueryValueExW(hkey, L"Security", 0, &valueType, (LPBYTE)&data2, &cch_data2); DWORD data3 = 0; DWORD cch_data3 = sizeof(data3); RegQueryValueExW(hkey, L"StorageFormat", 0, &valueType, (LPBYTE)&data3, &cch_data3); s2 = cmSystemTools::LowerCase(cmsys::Encoding::ToNarrow(data1)); cmSystemTools::ConvertToUnixSlashes(s2); if (s2 == s1) { macrosRegistered = true; } // std::cout << keyname << ":" << std::endl; // std::cout << " Path: " << data1 << std::endl; // std::cout << " Security: " << data2 << std::endl; // std::cout << " StorageFormat: " << data3 << std::endl; // std::cout << std::endl; RegCloseKey(hkey); } else { std::cout << "error opening key: " << keyname << std::endl; std::cout << std::endl; } return macrosRegistered; } void WriteVSMacrosFileRegistryEntry(const std::string& nextAvailableSubKeyName, const std::string& macrosFile, const std::string& regKeyBase) { std::string keyname = regKeyBase + "\\OtherProjects7"; HKEY hkey = NULL; LONG result = RegOpenKeyExW(HKEY_CURRENT_USER, cmsys::Encoding::ToWide(keyname).c_str(), 0, KEY_READ | KEY_WRITE, &hkey); if (ERROR_SUCCESS == result) { // Create the subkey and set the values of interest: HKEY hsubkey = NULL; wchar_t lpClass[] = L""; result = RegCreateKeyExW( hkey, cmsys::Encoding::ToWide(nextAvailableSubKeyName).c_str(), 0, lpClass, 0, KEY_READ | KEY_WRITE, 0, &hsubkey, 0); if (ERROR_SUCCESS == result) { DWORD dw = 0; std::string s(macrosFile); std::replace(s.begin(), s.end(), '/', '\\'); std::wstring ws = cmsys::Encoding::ToWide(s); result = RegSetValueExW(hsubkey, L"Path", 0, REG_SZ, (LPBYTE)ws.c_str(), static_cast(ws.size() + 1) * sizeof(wchar_t)); if (ERROR_SUCCESS != result) { std::cout << "error result 1: " << result << std::endl; std::cout << std::endl; } // Security value is always "1" for sample macros files (seems to be "2" // if you put the file somewhere outside the standard VSMacros folder) dw = 1; result = RegSetValueExW(hsubkey, L"Security", 0, REG_DWORD, (LPBYTE)&dw, sizeof(DWORD)); if (ERROR_SUCCESS != result) { std::cout << "error result 2: " << result << std::endl; std::cout << std::endl; } // StorageFormat value is always "0" for sample macros files dw = 0; result = RegSetValueExW(hsubkey, L"StorageFormat", 0, REG_DWORD, (LPBYTE)&dw, sizeof(DWORD)); if (ERROR_SUCCESS != result) { std::cout << "error result 3: " << result << std::endl; std::cout << std::endl; } RegCloseKey(hsubkey); } else { std::cout << "error creating subkey: " << nextAvailableSubKeyName << std::endl; std::cout << std::endl; } RegCloseKey(hkey); } else { std::cout << "error opening key: " << keyname << std::endl; std::cout << std::endl; } } void RegisterVisualStudioMacros(const std::string& macrosFile, const std::string& regKeyBase) { bool macrosRegistered; std::string nextAvailableSubKeyName; macrosRegistered = IsVisualStudioMacrosFileRegistered( macrosFile, regKeyBase, nextAvailableSubKeyName); if (!macrosRegistered) { int count = cmCallVisualStudioMacro::GetNumberOfRunningVisualStudioInstances("ALL"); // Only register the macros file if there are *no* instances of Visual // Studio running. If we register it while one is running, first, it has // no effect on the running instance; second, and worse, Visual Studio // removes our newly added registration entry when it quits. Instead, // emit a warning asking the user to exit all running Visual Studio // instances... // if (0 != count) { std::ostringstream oss; oss << "Could not register CMake's Visual Studio macros file '" << CMAKE_VSMACROS_FILENAME "' while Visual Studio is running." << " Please exit all running instances of Visual Studio before" << " continuing." << std::endl << std::endl << "CMake needs to register Visual Studio macros when its macros" << " file is updated or when it detects that its current macros file" << " is no longer registered with Visual Studio." << std::endl; cmSystemTools::Message(oss.str(), "Warning"); // Count them again now that the warning is over. In the case of a GUI // warning, the user may have gone to close Visual Studio and then come // back to the CMake GUI and clicked ok on the above warning. If so, // then register the macros *now* if the count is *now* 0... // count = cmCallVisualStudioMacro::GetNumberOfRunningVisualStudioInstances( "ALL"); // Also re-get the nextAvailableSubKeyName in case Visual Studio // wrote out new registered macros information as it was exiting: // if (0 == count) { IsVisualStudioMacrosFileRegistered(macrosFile, regKeyBase, nextAvailableSubKeyName); } } // Do another if check - 'count' may have changed inside the above if: // if (0 == count) { WriteVSMacrosFileRegistryEntry(nextAvailableSubKeyName, macrosFile, regKeyBase); } } } bool cmGlobalVisualStudioGenerator::TargetIsFortranOnly( cmGeneratorTarget const* gt) { // If there's only one source language, Fortran has to be used // in order for the sources to compile. std::set languages = gt->GetAllConfigCompileLanguages(); // Consider an explicit linker language property, but *not* the // computed linker language that may depend on linked targets. // This allows the project to control the language choice in // a target with none of its own sources, e.g. when also using // object libraries. cmProp linkLang = gt->GetProperty("LINKER_LANGUAGE"); if (linkLang && !linkLang->empty()) { languages.insert(*linkLang); } // Intel Fortran .vfproj files do support the resource compiler. languages.erase("RC"); return languages.size() == 1 && *languages.begin() == "Fortran"; } bool cmGlobalVisualStudioGenerator::TargetCompare::operator()( cmGeneratorTarget const* l, cmGeneratorTarget const* r) const { // Make sure a given named target is ordered first, // e.g. to set ALL_BUILD as the default active project. // When the empty string is named this is a no-op. if (r->GetName() == this->First) { return false; } if (l->GetName() == this->First) { return true; } return l->GetName() < r->GetName(); } cmGlobalVisualStudioGenerator::OrderedTargetDependSet::OrderedTargetDependSet( TargetDependSet const& targets, std::string const& first) : derived(TargetCompare(first)) { this->insert(targets.begin(), targets.end()); } cmGlobalVisualStudioGenerator::OrderedTargetDependSet::OrderedTargetDependSet( TargetSet const& targets, std::string const& first) : derived(TargetCompare(first)) { for (cmGeneratorTarget const* it : targets) { this->insert(it); } } std::string cmGlobalVisualStudioGenerator::ExpandCFGIntDir( const std::string& str, const std::string& config) const { std::string replace = GetCMakeCFGIntDir(); std::string tmp = str; for (std::string::size_type i = tmp.find(replace); i != std::string::npos; i = tmp.find(replace, i)) { tmp.replace(i, replace.size(), config); i += config.size(); } return tmp; } void cmGlobalVisualStudioGenerator::AddSymbolExportCommand( cmGeneratorTarget* gt, std::vector& commands, std::string const& configName) { cmGeneratorTarget::ModuleDefinitionInfo const* mdi = gt->GetModuleDefinitionInfo(configName); if (!mdi || !mdi->DefFileGenerated) { return; } std::vector outputs; outputs.push_back(mdi->DefFile); std::vector empty; std::vector objectSources; gt->GetObjectSources(objectSources, configName); std::map mapping; for (cmSourceFile const* it : objectSources) { mapping[it]; } gt->LocalGenerator->ComputeObjectFilenames(mapping, gt); std::string obj_dir = gt->ObjectDirectory; std::string cmakeCommand = cmSystemTools::GetCMakeCommand(); std::string obj_dir_expanded = obj_dir; cmSystemTools::ReplaceString(obj_dir_expanded, this->GetCMakeCFGIntDir(), configName.c_str()); cmSystemTools::MakeDirectory(obj_dir_expanded); std::string const objs_file = obj_dir_expanded + "/objects.txt"; cmGeneratedFileStream fout(objs_file.c_str()); if (!fout) { cmSystemTools::Error("could not open " + objs_file); return; } if (mdi->WindowsExportAllSymbols) { std::vector objs; for (cmSourceFile const* it : objectSources) { // Find the object file name corresponding to this source file. // It must exist because we populated the mapping just above. const auto& v = mapping[it]; assert(!v.empty()); std::string objFile = obj_dir + v; objs.push_back(objFile); } std::vector externalObjectSources; gt->GetExternalObjects(externalObjectSources, configName); for (cmSourceFile const* it : externalObjectSources) { objs.push_back(it->GetFullPath()); } for (std::string const& it : objs) { std::string objFile = it; // replace $(ConfigurationName) in the object names cmSystemTools::ReplaceString(objFile, this->GetCMakeCFGIntDir(), configName); if (cmHasLiteralSuffix(objFile, ".obj")) { fout << objFile << "\n"; } } } for (cmSourceFile const* i : mdi->Sources) { fout << i->GetFullPath() << "\n"; } cmCustomCommandLines commandLines = cmMakeSingleCommandLine( { cmakeCommand, "-E", "__create_def", mdi->DefFile, objs_file }); cmCustomCommand command(outputs, empty, empty, commandLines, gt->Target->GetMakefile()->GetBacktrace(), "Auto build dll exports", ".", true); commands.push_back(std::move(command)); } static bool OpenSolution(std::string sln) { HRESULT comInitialized = CoInitializeEx(NULL, COINIT_APARTMENTTHREADED | COINIT_DISABLE_OLE1DDE); if (FAILED(comInitialized)) { return false; } HINSTANCE hi = ShellExecuteA(NULL, "open", sln.c_str(), NULL, NULL, SW_SHOWNORMAL); CoUninitialize(); return reinterpret_cast(hi) > 32; } bool cmGlobalVisualStudioGenerator::Open(const std::string& bindir, const std::string& projectName, bool dryRun) { std::string sln = bindir + "/" + projectName + ".sln"; if (dryRun) { return cmSystemTools::FileExists(sln, true); } sln = cmSystemTools::ConvertToOutputPath(sln); return std::async(std::launch::async, OpenSolution, sln).get(); }