in Source/cmCoreTryCompile.cxx [334:1325]
cm::optional<cmTryCompileResult> cmCoreTryCompile::TryCompileCode(
Arguments& arguments, cmStateEnums::TargetType targetType)
{
this->OutputFile.clear();
// which signature were we called with ?
this->SrcFileSignature = true;
bool useUniqueBinaryDirectory = false;
std::string sourceDirectory;
std::string projectName;
std::string targetName;
if (arguments.ProjectName) {
this->SrcFileSignature = false;
if (!arguments.SourceDirectoryOrFile ||
arguments.SourceDirectoryOrFile->empty()) {
this->Makefile->IssueMessage(MessageType::FATAL_ERROR,
"No <srcdir> specified.");
return cm::nullopt;
}
sourceDirectory = *arguments.SourceDirectoryOrFile;
projectName = *arguments.ProjectName;
if (arguments.TargetName) {
targetName = *arguments.TargetName;
}
} else {
projectName = "CMAKE_TRY_COMPILE";
/* Use a random file name to avoid rapid creation and deletion
of the same executable name (some filesystems fail on that). */
char targetNameBuf[64];
snprintf(targetNameBuf, sizeof(targetNameBuf), "cmTC_%05x",
cmSystemTools::RandomNumber() & 0xFFFFF);
targetName = targetNameBuf;
}
if (!arguments.BinaryDirectory || arguments.BinaryDirectory->empty()) {
this->Makefile->IssueMessage(MessageType::FATAL_ERROR,
"No <bindir> specified.");
return cm::nullopt;
}
if (*arguments.BinaryDirectory == unique_binary_directory) {
// leave empty until we're ready to create it, so we don't try to remove
// a non-existing directory if we abort due to e.g. bad arguments
this->BinaryDirectory.clear();
useUniqueBinaryDirectory = true;
} else {
if (!cmSystemTools::FileIsFullPath(*arguments.BinaryDirectory)) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
cmStrCat("<bindir> is not an absolute path:\n '",
*arguments.BinaryDirectory, '\''));
return cm::nullopt;
}
this->BinaryDirectory = *arguments.BinaryDirectory;
// compute the binary dir when TRY_COMPILE is called with a src file
// signature
if (this->SrcFileSignature) {
this->BinaryDirectory += "/CMakeFiles/CMakeTmp";
}
}
std::vector<std::string> targets;
if (arguments.LinkLibraries) {
for (std::string const& i : *arguments.LinkLibraries) {
if (cmTarget* tgt = this->Makefile->FindTargetToUse(i)) {
switch (tgt->GetType()) {
case cmStateEnums::SHARED_LIBRARY:
case cmStateEnums::STATIC_LIBRARY:
case cmStateEnums::INTERFACE_LIBRARY:
case cmStateEnums::UNKNOWN_LIBRARY:
break;
case cmStateEnums::EXECUTABLE:
if (tgt->IsExecutableWithExports()) {
break;
}
CM_FALLTHROUGH;
default:
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
cmStrCat("Only libraries may be used as try_compile or try_run "
"IMPORTED LINK_LIBRARIES. Got ",
tgt->GetName(), " of type ",
cmState::GetTargetTypeName(tgt->GetType()), '.'));
return cm::nullopt;
}
if (tgt->IsImported()) {
targets.emplace_back(i);
}
}
}
}
if (arguments.CopyFileTo && arguments.CopyFileTo->empty()) {
this->Makefile->IssueMessage(MessageType::FATAL_ERROR,
"COPY_FILE must be followed by a file path");
return cm::nullopt;
}
if (arguments.CopyFileError && arguments.CopyFileError->empty()) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"COPY_FILE_ERROR must be followed by a variable name");
return cm::nullopt;
}
if (arguments.CopyFileError && !arguments.CopyFileTo) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"COPY_FILE_ERROR may be used only with COPY_FILE");
return cm::nullopt;
}
if (arguments.Sources && arguments.Sources->empty()) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"SOURCES must be followed by at least one source file");
return cm::nullopt;
}
if (this->SrcFileSignature) {
if (arguments.SourceFromContent &&
arguments.SourceFromContent->size() % 2) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"SOURCE_FROM_CONTENT requires exactly two arguments");
return cm::nullopt;
}
if (arguments.SourceFromVar && arguments.SourceFromVar->size() % 2) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"SOURCE_FROM_VAR requires exactly two arguments");
return cm::nullopt;
}
if (arguments.SourceFromFile && arguments.SourceFromFile->size() % 2) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"SOURCE_FROM_FILE requires exactly two arguments");
return cm::nullopt;
}
if (!arguments.SourceTypeError.empty()) {
this->Makefile->IssueMessage(MessageType::FATAL_ERROR,
arguments.SourceTypeError);
return cm::nullopt;
}
} else {
// only valid for srcfile signatures
if (!arguments.LangProps.empty()) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
cmStrCat(arguments.LangProps.begin()->first,
" allowed only in source file signature"));
return cm::nullopt;
}
if (!arguments.CompileDefs.empty()) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"COMPILE_DEFINITIONS allowed only in source file signature");
return cm::nullopt;
}
if (arguments.CopyFileTo) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"COPY_FILE allowed only in source file signature");
return cm::nullopt;
}
}
// make sure the binary directory exists
if (useUniqueBinaryDirectory) {
this->BinaryDirectory =
cmStrCat(this->Makefile->GetHomeOutputDirectory(),
"/CMakeFiles/CMakeScratch/TryCompile-XXXXXX");
cmSystemTools::MakeTempDirectory(this->BinaryDirectory);
} else {
cmSystemTools::MakeDirectory(this->BinaryDirectory);
}
// do not allow recursive try Compiles
if (this->BinaryDirectory == this->Makefile->GetHomeOutputDirectory()) {
std::ostringstream e;
e << "Attempt at a recursive or nested TRY_COMPILE in directory\n"
<< " " << this->BinaryDirectory << "\n";
this->Makefile->IssueMessage(MessageType::FATAL_ERROR, e.str());
return cm::nullopt;
}
std::map<std::string, std::string> cmakeVariables;
std::string outFileName = cmStrCat(this->BinaryDirectory, "/CMakeLists.txt");
// which signature are we using? If we are using var srcfile bindir
if (this->SrcFileSignature) {
// remove any CMakeCache.txt files so we will have a clean test
std::string ccFile = cmStrCat(this->BinaryDirectory, "/CMakeCache.txt");
cmSystemTools::RemoveFile(ccFile);
// Choose sources.
std::vector<std::pair<std::string, Arguments::SourceType>> sources;
if (arguments.Sources) {
sources = std::move(*arguments.Sources);
} else if (arguments.SourceDirectoryOrFile) {
sources.emplace_back(*arguments.SourceDirectoryOrFile,
Arguments::SourceType::Directory);
}
if (arguments.SourceFromContent) {
auto const k = arguments.SourceFromContent->size();
for (auto i = decltype(k){ 0 }; i < k; i += 2) {
auto const& name = (*arguments.SourceFromContent)[i + 0].first;
auto const& content = (*arguments.SourceFromContent)[i + 1].first;
auto out = this->WriteSource(name, content, "SOURCE_FROM_CONTENT");
if (out.empty()) {
return cm::nullopt;
}
sources.emplace_back(std::move(out),
(*arguments.SourceFromContent)[i + 0].second);
}
}
if (arguments.SourceFromVar) {
auto const k = arguments.SourceFromVar->size();
for (auto i = decltype(k){ 0 }; i < k; i += 2) {
auto const& name = (*arguments.SourceFromVar)[i + 0].first;
auto const& var = (*arguments.SourceFromVar)[i + 1].first;
auto const& content = this->Makefile->GetDefinition(var);
auto out = this->WriteSource(name, content, "SOURCE_FROM_VAR");
if (out.empty()) {
return cm::nullopt;
}
sources.emplace_back(std::move(out),
(*arguments.SourceFromVar)[i + 0].second);
}
}
if (arguments.SourceFromFile) {
auto const k = arguments.SourceFromFile->size();
for (auto i = decltype(k){ 0 }; i < k; i += 2) {
auto const& dst = (*arguments.SourceFromFile)[i + 0].first;
auto const& src = (*arguments.SourceFromFile)[i + 1].first;
if (!cmSystemTools::GetFilenamePath(dst).empty()) {
auto const& msg =
cmStrCat("SOURCE_FROM_FILE given invalid filename \"", dst, '"');
this->Makefile->IssueMessage(MessageType::FATAL_ERROR, msg);
return cm::nullopt;
}
auto dstPath = cmStrCat(this->BinaryDirectory, '/', dst);
auto const result = cmSystemTools::CopyFileAlways(src, dstPath);
if (!result.IsSuccess()) {
auto const& msg = cmStrCat("SOURCE_FROM_FILE failed to copy \"", src,
"\": ", result.GetString());
this->Makefile->IssueMessage(MessageType::FATAL_ERROR, msg);
return cm::nullopt;
}
sources.emplace_back(std::move(dstPath),
(*arguments.SourceFromFile)[i + 0].second);
}
}
// TODO: ensure sources is not empty
// Detect languages to enable.
cmGlobalGenerator* gg = this->Makefile->GetGlobalGenerator();
std::set<std::string> testLangs;
for (auto const& source : sources) {
auto const& si = source.first;
std::string ext = cmSystemTools::GetFilenameLastExtension(si);
std::string lang = gg->GetLanguageFromExtension(ext.c_str());
if (!lang.empty()) {
testLangs.insert(lang);
} else {
std::ostringstream err;
err << "Unknown extension \"" << ext
<< "\" for file\n"
" "
<< si
<< "\n"
"try_compile() works only for enabled languages. "
"Currently these are:\n ";
std::vector<std::string> langs;
gg->GetEnabledLanguages(langs);
err << cmJoin(langs, " ");
err << "\nSee project() command to enable other languages.";
this->Makefile->IssueMessage(MessageType::FATAL_ERROR, err.str());
return cm::nullopt;
}
}
// when the only language is ISPC we know that the output
// type must by a static library
if (testLangs.size() == 1 && testLangs.count("ISPC") == 1) {
targetType = cmStateEnums::STATIC_LIBRARY;
}
std::string const tcConfig =
this->Makefile->GetSafeDefinition("CMAKE_TRY_COMPILE_CONFIGURATION");
// we need to create a directory and CMakeLists file etc...
// first create the directories
sourceDirectory = this->BinaryDirectory;
// now create a CMakeLists.txt file in that directory
FILE* fout = cmsys::SystemTools::Fopen(outFileName, "w");
if (!fout) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
cmStrCat("Failed to open\n"
" ",
outFileName, '\n', cmSystemTools::GetLastSystemError()));
return cm::nullopt;
}
cmValue def = this->Makefile->GetDefinition("CMAKE_MODULE_PATH");
fprintf(fout, "cmake_minimum_required(VERSION %u.%u.%u.%u)\n",
cmVersion::GetMajorVersion(), cmVersion::GetMinorVersion(),
cmVersion::GetPatchVersion(), cmVersion::GetTweakVersion());
if (def) {
fprintf(fout, "set(CMAKE_MODULE_PATH \"%s\")\n", def->c_str());
cmakeVariables.emplace("CMAKE_MODULE_PATH", *def);
}
/* Set MSVC runtime library policy to match our selection. */
if (cmValue msvcRuntimeLibraryDefault =
this->Makefile->GetDefinition(kCMAKE_MSVC_RUNTIME_LIBRARY_DEFAULT)) {
fprintf(fout, "cmake_policy(SET CMP0091 %s)\n",
!msvcRuntimeLibraryDefault->empty() ? "NEW" : "OLD");
}
/* Set Watcom runtime library policy to match our selection. */
if (cmValue watcomRuntimeLibraryDefault = this->Makefile->GetDefinition(
kCMAKE_WATCOM_RUNTIME_LIBRARY_DEFAULT)) {
fprintf(fout, "cmake_policy(SET CMP0136 %s)\n",
!watcomRuntimeLibraryDefault->empty() ? "NEW" : "OLD");
}
/* Set CUDA architectures policy to match outer project. */
if (this->Makefile->GetPolicyStatus(cmPolicies::CMP0104) !=
cmPolicies::NEW &&
testLangs.find("CUDA") != testLangs.end() &&
this->Makefile->GetSafeDefinition(kCMAKE_CUDA_ARCHITECTURES).empty()) {
fprintf(fout, "cmake_policy(SET CMP0104 OLD)\n");
}
/* Set ARMClang cpu/arch policy to match outer project. */
if (cmValue cmp0123 =
this->Makefile->GetDefinition(kCMAKE_ARMClang_CMP0123)) {
fprintf(fout, "cmake_policy(SET CMP0123 %s)\n",
*cmp0123 == "NEW"_s ? "NEW" : "OLD");
}
/* Set MSVC debug information format policy to match our selection. */
if (cmValue msvcDebugInformationFormatDefault =
this->Makefile->GetDefinition(
kCMAKE_MSVC_DEBUG_INFORMATION_FORMAT_DEFAULT)) {
fprintf(fout, "cmake_policy(SET CMP0141 %s)\n",
!msvcDebugInformationFormatDefault->empty() ? "NEW" : "OLD");
}
/* Set MSVC runtime checks policy to match our selection. */
if (cmValue msvcRuntimeChecksDefault =
this->Makefile->GetDefinition(kCMAKE_MSVC_RUNTIME_CHECKS_DEFAULT)) {
fprintf(fout, "cmake_policy(SET CMP0184 %s)\n",
!msvcRuntimeChecksDefault->empty() ? "NEW" : "OLD");
}
/* Set cache/normal variable policy to match outer project.
It may affect toolchain files. */
if (this->Makefile->GetPolicyStatus(cmPolicies::CMP0126) !=
cmPolicies::NEW) {
fprintf(fout, "cmake_policy(SET CMP0126 OLD)\n");
}
/* Set language extensions policy to match outer project. */
if (this->Makefile->GetPolicyStatus(cmPolicies::CMP0128) !=
cmPolicies::NEW) {
fprintf(fout, "cmake_policy(SET CMP0128 OLD)\n");
}
std::string projectLangs;
for (std::string const& li : testLangs) {
projectLangs += cmStrCat(' ', li);
std::string rulesOverrideBase = "CMAKE_USER_MAKE_RULES_OVERRIDE";
std::string rulesOverrideLang = cmStrCat(rulesOverrideBase, '_', li);
if (cmValue rulesOverridePath =
this->Makefile->GetDefinition(rulesOverrideLang)) {
fprintf(fout, "set(%s \"%s\")\n", rulesOverrideLang.c_str(),
rulesOverridePath->c_str());
cmakeVariables.emplace(rulesOverrideLang, *rulesOverridePath);
} else if (cmValue rulesOverridePath2 =
this->Makefile->GetDefinition(rulesOverrideBase)) {
fprintf(fout, "set(%s \"%s\")\n", rulesOverrideBase.c_str(),
rulesOverridePath2->c_str());
cmakeVariables.emplace(rulesOverrideBase, *rulesOverridePath2);
}
}
fprintf(fout, "project(CMAKE_TRY_COMPILE%s)\n", projectLangs.c_str());
if (arguments.CMakeInternal == "ABI") {
// This is the ABI detection step, also used for implicit includes.
// Erase any include_directories() calls from the toolchain file so
// that we do not see them as implicit. Our ABI detection source
// does not include any system headers anyway.
fprintf(fout,
"set_property(DIRECTORY PROPERTY INCLUDE_DIRECTORIES \"\")\n");
// The link and compile lines for ABI detection step need to not use
// response files so we can extract implicit includes given to
// the underlying host compiler
static std::array<std::string, 2> const noRSP{ { "CUDA", "HIP" } };
for (std::string const& lang : noRSP) {
if (testLangs.find(lang) != testLangs.end()) {
fprintf(fout, "set(CMAKE_%s_USE_RESPONSE_FILE_FOR_INCLUDES OFF)\n",
lang.c_str());
fprintf(fout, "set(CMAKE_%s_USE_RESPONSE_FILE_FOR_LIBRARIES OFF)\n",
lang.c_str());
fprintf(fout, "set(CMAKE_%s_USE_RESPONSE_FILE_FOR_OBJECTS OFF)\n",
lang.c_str());
}
}
}
fprintf(fout, "set(CMAKE_VERBOSE_MAKEFILE 1)\n");
for (std::string const& li : testLangs) {
std::string langFlags = cmStrCat("CMAKE_", li, "_FLAGS");
cmValue flags = this->Makefile->GetDefinition(langFlags);
fprintf(fout, "set(CMAKE_%s_FLAGS %s)\n", li.c_str(),
cmOutputConverter::EscapeForCMake(*flags).c_str());
fprintf(fout,
"set(CMAKE_%s_FLAGS \"${CMAKE_%s_FLAGS}"
" ${COMPILE_DEFINITIONS}\")\n",
li.c_str(), li.c_str());
if (flags) {
cmakeVariables.emplace(langFlags, *flags);
}
}
switch (this->Makefile->GetPolicyStatus(cmPolicies::CMP0066)) {
case cmPolicies::WARN:
if (this->Makefile->PolicyOptionalWarningEnabled(
"CMAKE_POLICY_WARNING_CMP0066")) {
std::ostringstream w;
/* clang-format off */
w << cmPolicies::GetPolicyWarning(cmPolicies::CMP0066) << "\n"
"For compatibility with older versions of CMake, try_compile "
"is not honoring caller config-specific compiler flags "
"(e.g. CMAKE_C_FLAGS_DEBUG) in the test project."
;
/* clang-format on */
this->Makefile->IssueMessage(MessageType::AUTHOR_WARNING, w.str());
}
CM_FALLTHROUGH;
case cmPolicies::OLD:
// OLD behavior is to do nothing.
break;
case cmPolicies::NEW: {
// NEW behavior is to pass config-specific compiler flags.
std::string const cfg = !tcConfig.empty()
? cmSystemTools::UpperCase(tcConfig)
: TryCompileDefaultConfig;
for (std::string const& li : testLangs) {
std::string const langFlagsCfg =
cmStrCat("CMAKE_", li, "_FLAGS_", cfg);
cmValue flagsCfg = this->Makefile->GetDefinition(langFlagsCfg);
fprintf(fout, "set(%s %s)\n", langFlagsCfg.c_str(),
cmOutputConverter::EscapeForCMake(*flagsCfg).c_str());
if (flagsCfg) {
cmakeVariables.emplace(langFlagsCfg, *flagsCfg);
}
}
} break;
}
{
cmValue exeLinkFlags =
this->Makefile->GetDefinition("CMAKE_EXE_LINKER_FLAGS");
fprintf(fout, "set(CMAKE_EXE_LINKER_FLAGS %s)\n",
cmOutputConverter::EscapeForCMake(*exeLinkFlags).c_str());
if (exeLinkFlags) {
cmakeVariables.emplace("CMAKE_EXE_LINKER_FLAGS", *exeLinkFlags);
}
}
fprintf(fout,
"set(CMAKE_EXE_LINKER_FLAGS \"${CMAKE_EXE_LINKER_FLAGS}"
" ${EXE_LINKER_FLAGS}\")\n");
fprintf(fout, "include_directories(${INCLUDE_DIRECTORIES})\n");
fprintf(fout, "set(CMAKE_SUPPRESS_REGENERATION 1)\n");
fprintf(fout, "link_directories(${LINK_DIRECTORIES})\n");
// handle any compile flags we need to pass on
if (!arguments.CompileDefs.empty()) {
// Pass using bracket arguments to preserve content.
fprintf(fout, "add_definitions([==[%s]==])\n",
arguments.CompileDefs.join("]==] [==[").c_str());
}
if (!targets.empty()) {
std::string fname = cmStrCat('/', targetName, "Targets.cmake");
cmExportTryCompileFileGenerator tcfg(gg, targets, this->Makefile,
testLangs);
tcfg.SetExportFile(cmStrCat(this->BinaryDirectory, fname).c_str());
tcfg.SetConfig(tcConfig);
if (!tcfg.GenerateImportFile()) {
this->Makefile->IssueMessage(MessageType::FATAL_ERROR,
"could not write export file.");
fclose(fout);
return cm::nullopt;
}
fprintf(fout, "\ninclude(\"${CMAKE_CURRENT_LIST_DIR}/%s\")\n",
fname.c_str());
// Create all relevant alias targets
if (arguments.LinkLibraries) {
auto const& aliasTargets = this->Makefile->GetAliasTargets();
for (std::string const& i : *arguments.LinkLibraries) {
auto alias = aliasTargets.find(i);
if (alias != aliasTargets.end()) {
auto const& aliasTarget =
this->Makefile->FindTargetToUse(alias->second);
// Create equivalent library/executable alias
if (aliasTarget->GetType() == cmStateEnums::EXECUTABLE) {
fprintf(fout, "add_executable(\"%s\" ALIAS \"%s\")\n", i.c_str(),
alias->second.c_str());
} else {
// Other cases like UTILITY and GLOBAL_TARGET are excluded when
// arguments.LinkLibraries is initially parsed in this function.
fprintf(fout, "add_library(\"%s\" ALIAS \"%s\")\n", i.c_str(),
alias->second.c_str());
}
}
}
}
fprintf(fout, "\n");
}
/* Set the appropriate policy information for PIE link flags */
fprintf(fout, "cmake_policy(SET CMP0083 %s)\n",
this->Makefile->GetPolicyStatus(cmPolicies::CMP0083) ==
cmPolicies::NEW
? "NEW"
: "OLD");
/* Set the appropriate policy information for C++ module support */
fprintf(fout, "cmake_policy(SET CMP0155 %s)\n",
this->Makefile->GetPolicyStatus(cmPolicies::CMP0155) ==
cmPolicies::NEW
? "NEW"
: "OLD");
/* Set the appropriate policy information for Swift compilation mode */
fprintf(
fout, "cmake_policy(SET CMP0157 %s)\n",
this->Makefile->GetDefinition("CMAKE_Swift_COMPILATION_MODE_DEFAULT")
.IsEmpty()
? "OLD"
: "NEW");
/* Set the appropriate policy information for the LINKER: prefix expansion
*/
fprintf(fout, "cmake_policy(SET CMP0181 %s)\n",
this->Makefile->GetPolicyStatus(cmPolicies::CMP0181) ==
cmPolicies::NEW
? "NEW"
: "OLD");
// Workaround for -Wl,-headerpad_max_install_names issue until we can avoid
// adding that flag in the platform and compiler language files
fprintf(fout,
"include(\"${CMAKE_ROOT}/Modules/Internal/"
"HeaderpadWorkaround.cmake\")\n");
if (targetType == cmStateEnums::EXECUTABLE) {
/* Put the executable at a known location (for COPY_FILE). */
fprintf(fout, "set(CMAKE_RUNTIME_OUTPUT_DIRECTORY \"%s\")\n",
this->BinaryDirectory.c_str());
/* Create the actual executable. */
fprintf(fout, "add_executable(%s)\n", targetName.c_str());
} else // if (targetType == cmStateEnums::STATIC_LIBRARY)
{
/* Put the static library at a known location (for COPY_FILE). */
fprintf(fout, "set(CMAKE_ARCHIVE_OUTPUT_DIRECTORY \"%s\")\n",
this->BinaryDirectory.c_str());
/* Create the actual static library. */
fprintf(fout, "add_library(%s STATIC)\n", targetName.c_str());
}
fprintf(fout, "target_sources(%s PRIVATE\n", targetName.c_str());
std::string file_set_name;
bool in_file_set = false;
for (auto const& source : sources) {
auto const& si = source.first;
switch (source.second) {
case Arguments::SourceType::Normal: {
if (in_file_set) {
fprintf(fout, " PRIVATE\n");
in_file_set = false;
}
} break;
case Arguments::SourceType::CxxModule: {
if (!in_file_set) {
file_set_name += 'a';
fprintf(fout,
" PRIVATE FILE_SET %s TYPE CXX_MODULES BASE_DIRS \"%s\" "
"FILES\n",
file_set_name.c_str(),
this->Makefile->GetCurrentSourceDirectory().c_str());
in_file_set = true;
}
} break;
case Arguments::SourceType::Directory:
/* Handled elsewhere. */
break;
}
fprintf(fout, " \"%s\"\n", si.c_str());
// Add dependencies on any non-temporary sources.
if (!IsTemporary(si)) {
this->Makefile->AddCMakeDependFile(si);
}
}
fprintf(fout, ")\n");
/* Write out the output location of the target we are building */
std::string perConfigGenex;
if (this->Makefile->GetGlobalGenerator()->IsMultiConfig()) {
perConfigGenex = "_$<UPPER_CASE:$<CONFIG>>";
}
fprintf(fout,
"file(GENERATE OUTPUT "
"\"${CMAKE_BINARY_DIR}/%s%s_loc\"\n",
targetName.c_str(), perConfigGenex.c_str());
fprintf(fout, " CONTENT $<TARGET_FILE:%s>)\n", targetName.c_str());
bool warnCMP0067 = false;
bool honorStandard = true;
if (arguments.LangProps.empty()) {
switch (this->Makefile->GetPolicyStatus(cmPolicies::CMP0067)) {
case cmPolicies::WARN:
warnCMP0067 = this->Makefile->PolicyOptionalWarningEnabled(
"CMAKE_POLICY_WARNING_CMP0067");
CM_FALLTHROUGH;
case cmPolicies::OLD:
// OLD behavior is to not honor the language standard variables.
honorStandard = false;
break;
case cmPolicies::NEW:
// NEW behavior is to honor the language standard variables.
// We already initialized honorStandard to true.
break;
}
}
std::vector<std::string> warnCMP0067Variables;
if (honorStandard || warnCMP0067) {
static std::array<std::string, 6> const possibleLangs{
{ "C", "CXX", "CUDA", "HIP", "OBJC", "OBJCXX" }
};
static std::array<cm::string_view, 3> const langPropSuffixes{
{ "_STANDARD"_s, "_STANDARD_REQUIRED"_s, "_EXTENSIONS"_s }
};
for (std::string const& lang : possibleLangs) {
if (testLangs.find(lang) == testLangs.end()) {
continue;
}
for (cm::string_view propSuffix : langPropSuffixes) {
std::string langProp = cmStrCat(lang, propSuffix);
if (!arguments.LangProps.count(langProp)) {
std::string langPropVar = cmStrCat("CMAKE_"_s, langProp);
std::string value = this->Makefile->GetSafeDefinition(langPropVar);
if (warnCMP0067 && !value.empty()) {
value.clear();
warnCMP0067Variables.emplace_back(langPropVar);
}
if (!value.empty()) {
arguments.LangProps[langProp] = value;
}
}
}
}
}
if (!warnCMP0067Variables.empty()) {
std::ostringstream w;
/* clang-format off */
w << cmPolicies::GetPolicyWarning(cmPolicies::CMP0067) << "\n"
"For compatibility with older versions of CMake, try_compile "
"is not honoring language standard variables in the test project:\n"
;
/* clang-format on */
for (std::string const& vi : warnCMP0067Variables) {
w << " " << vi << "\n";
}
this->Makefile->IssueMessage(MessageType::AUTHOR_WARNING, w.str());
}
for (auto const& p : arguments.LangProps) {
if (p.second.empty()) {
continue;
}
fprintf(fout, "set_property(TARGET %s PROPERTY %s %s)\n",
targetName.c_str(),
cmOutputConverter::EscapeForCMake(p.first).c_str(),
cmOutputConverter::EscapeForCMake(p.second).c_str());
}
if (!arguments.LinkOptions.empty()) {
std::vector<std::string> options;
options.reserve(arguments.LinkOptions.size());
for (auto const& option : arguments.LinkOptions) {
options.emplace_back(cmOutputConverter::EscapeForCMake(option));
}
if (targetType == cmStateEnums::STATIC_LIBRARY) {
fprintf(fout,
"set_property(TARGET %s PROPERTY STATIC_LIBRARY_OPTIONS %s)\n",
targetName.c_str(), cmJoin(options, " ").c_str());
} else {
fprintf(fout, "target_link_options(%s PRIVATE %s)\n",
targetName.c_str(), cmJoin(options, " ").c_str());
}
}
if (arguments.LinkerLanguage) {
std::string LinkerLanguage = *arguments.LinkerLanguage;
if (testLangs.find(LinkerLanguage) == testLangs.end()) {
this->Makefile->IssueMessage(
MessageType::FATAL_ERROR,
"Linker language '" + LinkerLanguage +
"' must be enabled in project(LANGUAGES).");
}
fprintf(fout, "set_property(TARGET %s PROPERTY LINKER_LANGUAGE %s)\n",
targetName.c_str(), LinkerLanguage.c_str());
}
if (arguments.LinkLibraries) {
std::string libsToLink = " ";
for (std::string const& i : *arguments.LinkLibraries) {
libsToLink += cmStrCat('"', cmTrimWhitespace(i), "\" ");
}
fprintf(fout, "target_link_libraries(%s %s)\n", targetName.c_str(),
libsToLink.c_str());
} else {
fprintf(fout, "target_link_libraries(%s ${LINK_LIBRARIES})\n",
targetName.c_str());
}
fclose(fout);
}
// Forward a set of variables to the inner project cache.
if ((this->SrcFileSignature ||
this->Makefile->GetPolicyStatus(cmPolicies::CMP0137) ==
cmPolicies::NEW) &&
!this->Makefile->IsOn("CMAKE_TRY_COMPILE_NO_PLATFORM_VARIABLES")) {
std::set<std::string> vars;
vars.insert(&c_properties[lang_property_start],
&c_properties[lang_property_start + lang_property_size]);
vars.insert(&cxx_properties[lang_property_start],
&cxx_properties[lang_property_start + lang_property_size]);
vars.insert(&cuda_properties[lang_property_start],
&cuda_properties[lang_property_start + lang_property_size]);
vars.insert(&fortran_properties[lang_property_start],
&fortran_properties[lang_property_start + lang_property_size]);
vars.insert(&hip_properties[lang_property_start],
&hip_properties[lang_property_start + lang_property_size]);
vars.insert(&objc_properties[lang_property_start],
&objc_properties[lang_property_start + lang_property_size]);
vars.insert(&objcxx_properties[lang_property_start],
&objcxx_properties[lang_property_start + lang_property_size]);
vars.insert(&ispc_properties[lang_property_start],
&ispc_properties[lang_property_start + lang_property_size]);
vars.insert(&swift_properties[lang_property_start],
&swift_properties[lang_property_start + lang_property_size]);
vars.insert(kCMAKE_CUDA_ARCHITECTURES);
vars.insert(kCMAKE_CUDA_RUNTIME_LIBRARY);
vars.insert(kCMAKE_CXX_SCAN_FOR_MODULES);
vars.insert(kCMAKE_ENABLE_EXPORTS);
vars.insert(kCMAKE_EXECUTABLE_ENABLE_EXPORTS);
vars.insert(kCMAKE_SHARED_LIBRARY_ENABLE_EXPORTS);
vars.insert(kCMAKE_HIP_ARCHITECTURES);
vars.insert(kCMAKE_HIP_PLATFORM);
vars.insert(kCMAKE_HIP_RUNTIME_LIBRARY);
vars.insert(kCMAKE_ISPC_INSTRUCTION_SETS);
vars.insert(kCMAKE_ISPC_HEADER_SUFFIX);
vars.insert(kCMAKE_LINK_SEARCH_END_STATIC);
vars.insert(kCMAKE_LINK_SEARCH_START_STATIC);
vars.insert(kCMAKE_OSX_ARCHITECTURES);
vars.insert(kCMAKE_OSX_DEPLOYMENT_TARGET);
vars.insert(kCMAKE_OSX_SYSROOT);
vars.insert(kCMAKE_APPLE_ARCH_SYSROOTS);
vars.insert(kCMAKE_POSITION_INDEPENDENT_CODE);
vars.insert(kCMAKE_SYSROOT);
vars.insert(kCMAKE_SYSROOT_COMPILE);
vars.insert(kCMAKE_SYSROOT_LINK);
vars.insert(kCMAKE_WARN_DEPRECATED);
vars.emplace("CMAKE_MSVC_RUNTIME_LIBRARY"_s);
vars.emplace("CMAKE_WATCOM_RUNTIME_LIBRARY"_s);
vars.emplace("CMAKE_MSVC_DEBUG_INFORMATION_FORMAT"_s);
vars.emplace("CMAKE_MSVC_RUNTIME_CHECKS"_s);
vars.emplace("CMAKE_CXX_COMPILER_CLANG_SCAN_DEPS"_s);
vars.emplace("CMAKE_VS_USE_DEBUG_LIBRARIES"_s);
if (cmValue varListStr = this->Makefile->GetDefinition(
kCMAKE_TRY_COMPILE_PLATFORM_VARIABLES)) {
cmList varList{ *varListStr };
vars.insert(varList.begin(), varList.end());
}
if (this->Makefile->GetDefinition(kCMAKE_LINKER_TYPE)) {
// propagate various variables to support linker selection
vars.insert(kCMAKE_LINKER_TYPE);
auto defs = this->Makefile->GetDefinitions();
cmsys::RegularExpression linkerTypeDef{
"^CMAKE_[A-Za-z_-]+_USING_LINKER_"
};
for (auto const& def : defs) {
if (linkerTypeDef.find(def)) {
vars.insert(def);
}
}
}
if (this->Makefile->GetPolicyStatus(cmPolicies::CMP0083) ==
cmPolicies::NEW) {
// To ensure full support of PIE, propagate cache variables
// driving the link options
vars.insert(&c_properties[pie_property_start],
&c_properties[pie_property_start + pie_property_size]);
vars.insert(&cxx_properties[pie_property_start],
&cxx_properties[pie_property_start + pie_property_size]);
vars.insert(&cuda_properties[pie_property_start],
&cuda_properties[pie_property_start + pie_property_size]);
vars.insert(&fortran_properties[pie_property_start],
&fortran_properties[pie_property_start + pie_property_size]);
vars.insert(&hip_properties[pie_property_start],
&hip_properties[pie_property_start + pie_property_size]);
vars.insert(&objc_properties[pie_property_start],
&objc_properties[pie_property_start + pie_property_size]);
vars.insert(&objcxx_properties[pie_property_start],
&objcxx_properties[pie_property_start + pie_property_size]);
vars.insert(&ispc_properties[pie_property_start],
&ispc_properties[pie_property_start + pie_property_size]);
vars.insert(&swift_properties[pie_property_start],
&swift_properties[pie_property_start + pie_property_size]);
}
/* for the TRY_COMPILEs we want to be able to specify the architecture.
So the user can set CMAKE_OSX_ARCHITECTURES to i386;ppc and then set
CMAKE_TRY_COMPILE_OSX_ARCHITECTURES first to i386 and then to ppc to
have the tests run for each specific architecture. Since
cmLocalGenerator doesn't allow building for "the other"
architecture only via CMAKE_OSX_ARCHITECTURES.
*/
if (cmValue tcArchs = this->Makefile->GetDefinition(
kCMAKE_TRY_COMPILE_OSX_ARCHITECTURES)) {
vars.erase(kCMAKE_OSX_ARCHITECTURES);
std::string flag = cmStrCat("-DCMAKE_OSX_ARCHITECTURES=", *tcArchs);
arguments.CMakeFlags.emplace_back(std::move(flag));
cmakeVariables.emplace("CMAKE_OSX_ARCHITECTURES", *tcArchs);
}
// Pass down CMAKE_EXPERIMENTAL_* feature flags
for (std::size_t i = 0;
i < static_cast<std::size_t>(cmExperimental::Feature::Sentinel);
i++) {
auto const& data = cmExperimental::DataForFeature(
static_cast<cmExperimental::Feature>(i));
if (data.ForwardThroughTryCompile ==
cmExperimental::TryCompileCondition::Always ||
(data.ForwardThroughTryCompile ==
cmExperimental::TryCompileCondition::SkipCompilerChecks &&
arguments.CMakeInternal != "ABI"_s &&
arguments.CMakeInternal != "FEATURE_TESTING"_s)) {
vars.insert(data.Variable);
for (auto const& var : data.TryCompileVariables) {
vars.insert(var);
}
}
}
for (std::string const& var : vars) {
if (cmValue val = this->Makefile->GetDefinition(var)) {
std::string flag = cmStrCat("-D", var, '=', *val);
arguments.CMakeFlags.emplace_back(std::move(flag));
cmakeVariables.emplace(var, *val);
}
}
}
if (!this->SrcFileSignature &&
this->Makefile->GetState()->GetGlobalPropertyAsBool(
"PROPAGATE_TOP_LEVEL_INCLUDES_TO_TRY_COMPILE")) {
std::string const var = "CMAKE_PROJECT_TOP_LEVEL_INCLUDES";
if (cmValue val = this->Makefile->GetDefinition(var)) {
std::string flag = cmStrCat("-D", var, "=\'", *val, '\'');
arguments.CMakeFlags.emplace_back(std::move(flag));
cmakeVariables.emplace(var, *val);
}
}
if (this->Makefile->GetState()->UseGhsMultiIDE()) {
// Forward the GHS variables to the inner project cache.
for (std::string const& var : ghs_platform_vars) {
if (cmValue val = this->Makefile->GetDefinition(var)) {
std::string flag = cmStrCat("-D", var, "=\'", *val, '\'');
arguments.CMakeFlags.emplace_back(std::move(flag));
cmakeVariables.emplace(var, *val);
}
}
}
if (this->Makefile->GetCMakeInstance()->GetDebugTryCompile()) {
auto msg =
cmStrCat("Executing try_compile (", *arguments.CompileResultVariable,
") in:\n ", this->BinaryDirectory);
this->Makefile->IssueMessage(MessageType::LOG, msg);
}
bool erroroc = cmSystemTools::GetErrorOccurredFlag();
cmSystemTools::ResetErrorOccurredFlag();
std::string output;
// actually do the try compile now that everything is setup
int res = this->Makefile->TryCompile(
sourceDirectory, this->BinaryDirectory, projectName, targetName,
this->SrcFileSignature, cmake::NO_BUILD_PARALLEL_LEVEL,
&arguments.CMakeFlags, output);
if (erroroc) {
cmSystemTools::SetErrorOccurred();
}
// set the result var to the return value to indicate success or failure
if (arguments.NoCache) {
this->Makefile->AddDefinition(*arguments.CompileResultVariable,
(res == 0 ? "TRUE" : "FALSE"));
} else {
this->Makefile->AddCacheDefinition(
*arguments.CompileResultVariable, (res == 0 ? "TRUE" : "FALSE"),
"Result of TRY_COMPILE", cmStateEnums::INTERNAL);
}
if (arguments.OutputVariable) {
this->Makefile->AddDefinition(*arguments.OutputVariable, output);
}
if (this->SrcFileSignature) {
std::string copyFileErrorMessage;
this->FindOutputFile(targetName);
if ((res == 0) && arguments.CopyFileTo) {
std::string const& copyFile = *arguments.CopyFileTo;
cmsys::SystemTools::CopyStatus status =
cmSystemTools::CopyFileAlways(this->OutputFile, copyFile);
if (!status) {
std::string err = status.GetString();
switch (status.Path) {
case cmsys::SystemTools::CopyStatus::SourcePath:
err = cmStrCat(err, " (input)");
break;
case cmsys::SystemTools::CopyStatus::DestPath:
err = cmStrCat(err, " (output)");
break;
default:
break;
}
/* clang-format off */
err = cmStrCat(
"Cannot copy output executable\n"
" '", this->OutputFile, "'\n"
"to destination specified by COPY_FILE:\n"
" '", copyFile, "'\n"
"because:\n"
" ", err, "\n",
this->FindErrorMessage);
/* clang-format on */
if (!arguments.CopyFileError) {
this->Makefile->IssueMessage(MessageType::FATAL_ERROR, err);
return cm::nullopt;
}
copyFileErrorMessage = std::move(err);
}
}
if (arguments.CopyFileError) {
std::string const& copyFileError = *arguments.CopyFileError;
this->Makefile->AddDefinition(copyFileError, copyFileErrorMessage);
}
}
cmTryCompileResult result;
if (arguments.LogDescription) {
result.LogDescription = *arguments.LogDescription;
}
result.CMakeVariables = std::move(cmakeVariables);
result.SourceDirectory = sourceDirectory;
result.BinaryDirectory = this->BinaryDirectory;
result.Variable = *arguments.CompileResultVariable;
result.VariableCached = !arguments.NoCache;
result.Output = std::move(output);
result.ExitCode = res;
return cm::optional<cmTryCompileResult>(std::move(result));
}