Google Git
Sign in
fuchsia / third_party / cmake / refs/tags/v3.17.2 / . / Source / CTest / cmCTestTestHandler.cxx
blob: 4f324ea6d2c1aac32ec5580500fb659c19be31d9 [file] [log] [blame]
/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
file Copyright.txt or https://cmake.org/licensing for details. */
#include "cmCTestTestHandler.h"
#include <algorithm>
#include <chrono>
#include <cmath>
#include <cstddef>
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <ctime>
#include <functional>
#include <iomanip>
#include <iterator>
#include <set>
#include <sstream>
#include <utility>
#include <cm/memory>
#include "cmsys/FStream.hxx"
#include <cmsys/Base64.h>
#include <cmsys/Directory.hxx>
#include <cmsys/RegularExpression.hxx>
#include "cm_utf8.h"
#include "cmAlgorithms.h"
#include "cmCTest.h"
#include "cmCTestMultiProcessHandler.h"
#include "cmCTestResourceGroupsLexerHelper.h"
#include "cmDuration.h"
#include "cmExecutionStatus.h"
#include "cmGeneratedFileStream.h"
#include "cmGlobalGenerator.h"
#include "cmMakefile.h"
#include "cmState.h"
#include "cmStateSnapshot.h"
#include "cmStringAlgorithms.h"
#include "cmSystemTools.h"
#include "cmWorkingDirectory.h"
#include "cmXMLWriter.h"
#include "cmake.h"
namespace {
class cmCTestCommand
{
public:
cmCTestCommand(cmCTestTestHandler* testHandler)
: TestHandler(testHandler)
{
}
virtual ~cmCTestCommand() = default;
bool operator()(std::vector<cmListFileArgument> const& args,
cmExecutionStatus& status)
{
cmMakefile& mf = status.GetMakefile();
std::vector<std::string> expandedArguments;
if (!mf.ExpandArguments(args, expandedArguments)) {
// There was an error expanding arguments. It was already
// reported, so we can skip this command without error.
return true;
}
return this->InitialPass(expandedArguments, status);
}
virtual bool InitialPass(std::vector<std::string> const& args,
cmExecutionStatus& status) = 0;
cmCTestTestHandler* TestHandler;
};
bool cmCTestSubdirCommand(std::vector<std::string> const& args,
cmExecutionStatus& status)
{
if (args.empty()) {
status.SetError("called with incorrect number of arguments");
return false;
}
std::string cwd = cmSystemTools::GetCurrentWorkingDirectory();
for (std::string const& arg : args) {
std::string fname;
if (cmSystemTools::FileIsFullPath(arg)) {
fname = arg;
} else {
fname = cmStrCat(cwd, '/', arg);
}
if (!cmSystemTools::FileIsDirectory(fname)) {
// No subdirectory? So what...
continue;
}
bool readit = false;
{
cmWorkingDirectory workdir(fname);
if (workdir.Failed()) {
status.SetError("Failed to change directory to " + fname + " : " +
std::strerror(workdir.GetLastResult()));
return false;
}
const char* testFilename;
if (cmSystemTools::FileExists("CTestTestfile.cmake")) {
// does the CTestTestfile.cmake exist ?
testFilename = "CTestTestfile.cmake";
} else if (cmSystemTools::FileExists("DartTestfile.txt")) {
// does the DartTestfile.txt exist ?
testFilename = "DartTestfile.txt";
} else {
// No CTestTestfile? Who cares...
continue;
}
fname += "/";
fname += testFilename;
readit = status.GetMakefile().ReadDependentFile(fname);
}
if (!readit) {
status.SetError(cmStrCat("Could not find include file: ", fname));
return false;
}
}
return true;
}
bool cmCTestAddSubdirectoryCommand(std::vector<std::string> const& args,
cmExecutionStatus& status)
{
if (args.empty()) {
status.SetError("called with incorrect number of arguments");
return false;
}
std::string fname =
cmStrCat(cmSystemTools::GetCurrentWorkingDirectory(), '/', args[0]);
if (!cmSystemTools::FileExists(fname)) {
// No subdirectory? So what...
return true;
}
bool readit = false;
{
const char* testFilename;
if (cmSystemTools::FileExists("CTestTestfile.cmake")) {
// does the CTestTestfile.cmake exist ?
testFilename = "CTestTestfile.cmake";
} else if (cmSystemTools::FileExists("DartTestfile.txt")) {
// does the DartTestfile.txt exist ?
testFilename = "DartTestfile.txt";
} else {
// No CTestTestfile? Who cares...
return true;
}
fname += "/";
fname += testFilename;
readit = status.GetMakefile().ReadDependentFile(fname);
}
if (!readit) {
status.SetError(cmStrCat("Could not find include file: ", fname));
return false;
}
return true;
}
class cmCTestAddTestCommand : public cmCTestCommand
{
public:
using cmCTestCommand::cmCTestCommand;
/**
* This is called when the command is first encountered in
* the CMakeLists.txt file.
*/
bool InitialPass(std::vector<std::string> const& /*args*/,
cmExecutionStatus& /*unused*/) override;
};
bool cmCTestAddTestCommand::InitialPass(std::vector<std::string> const& args,
cmExecutionStatus& status)
{
if (args.size() < 2) {
status.SetError("called with incorrect number of arguments");
return false;
}
return this->TestHandler->AddTest(args);
}
class cmCTestSetTestsPropertiesCommand : public cmCTestCommand
{
public:
using cmCTestCommand::cmCTestCommand;
/**
* This is called when the command is first encountered in
* the CMakeLists.txt file.
*/
bool InitialPass(std::vector<std::string> const& /*args*/,
cmExecutionStatus& /*unused*/) override;
};
bool cmCTestSetTestsPropertiesCommand::InitialPass(
std::vector<std::string> const& args, cmExecutionStatus& /*unused*/)
{
return this->TestHandler->SetTestsProperties(args);
}
class cmCTestSetDirectoryPropertiesCommand : public cmCTestCommand
{
public:
using cmCTestCommand::cmCTestCommand;
/**
* This is called when the command is first encountered in
* the CMakeLists.txt file.
*/
bool InitialPass(std::vector<std::string> const& /*unused*/,
cmExecutionStatus& /*unused*/) override;
};
bool cmCTestSetDirectoryPropertiesCommand::InitialPass(
std::vector<std::string> const& args, cmExecutionStatus&)
{
return this->TestHandler->SetDirectoryProperties(args);
}
// get the next number in a string with numbers separated by ,
// pos is the start of the search and pos2 is the end of the search
// pos becomes pos2 after a call to GetNextNumber.
// -1 is returned at the end of the list.
inline int GetNextNumber(std::string const& in, int& val,
std::string::size_type& pos,
std::string::size_type& pos2)
{
pos2 = in.find(',', pos);
if (pos2 != std::string::npos) {
if (pos2 - pos == 0) {
val = -1;
} else {
val = atoi(in.substr(pos, pos2 - pos).c_str());
}
pos = pos2 + 1;
return 1;
}
if (in.size() - pos == 0) {
val = -1;
} else {
val = atoi(in.substr(pos, in.size() - pos).c_str());
}
return 0;
}
// get the next number in a string with numbers separated by ,
// pos is the start of the search and pos2 is the end of the search
// pos becomes pos2 after a call to GetNextNumber.
// -1 is returned at the end of the list.
inline int GetNextRealNumber(std::string const& in, double& val,
std::string::size_type& pos,
std::string::size_type& pos2)
{
pos2 = in.find(',', pos);
if (pos2 != std::string::npos) {
if (pos2 - pos == 0) {
val = -1;
} else {
val = atof(in.substr(pos, pos2 - pos).c_str());
}
pos = pos2 + 1;
return 1;
}
if (in.size() - pos == 0) {
val = -1;
} else {
val = atof(in.substr(pos, in.size() - pos).c_str());
}
return 0;
}
} // namespace
cmCTestTestHandler::cmCTestTestHandler()
{
this->UseUnion = false;
this->UseIncludeLabelRegExpFlag = false;
this->UseExcludeLabelRegExpFlag = false;
this->UseIncludeRegExpFlag = false;
this->UseExcludeRegExpFlag = false;
this->UseExcludeRegExpFirst = false;
this->UseResourceSpec = false;
this->CustomMaximumPassedTestOutputSize = 1 * 1024;
this->CustomMaximumFailedTestOutputSize = 300 * 1024;
this->MemCheck = false;
this->LogFile = nullptr;
// regex to detect <DartMeasurement>...</DartMeasurement>
this->DartStuff.compile("(<DartMeasurement.*/DartMeasurement[a-zA-Z]*>)");
// regex to detect each individual <DartMeasurement>...</DartMeasurement>
this->DartStuff1.compile(
"(<DartMeasurement[^<]*</DartMeasurement[a-zA-Z]*>)");
}
void cmCTestTestHandler::Initialize()
{
this->Superclass::Initialize();
this->ElapsedTestingTime = cmDuration();
this->TestResults.clear();
this->CustomTestsIgnore.clear();
this->StartTest.clear();
this->EndTest.clear();
this->CustomPreTest.clear();
this->CustomPostTest.clear();
this->CustomMaximumPassedTestOutputSize = 1 * 1024;
this->CustomMaximumFailedTestOutputSize = 300 * 1024;
this->TestsToRun.clear();
this->UseIncludeLabelRegExpFlag = false;
this->UseExcludeLabelRegExpFlag = false;
this->UseIncludeRegExpFlag = false;
this->UseExcludeRegExpFlag = false;
this->UseExcludeRegExpFirst = false;
this->IncludeLabelRegularExpression = "";
this->ExcludeLabelRegularExpression = "";
this->IncludeRegExp.clear();
this->ExcludeRegExp.clear();
this->ExcludeFixtureRegExp.clear();
this->ExcludeFixtureSetupRegExp.clear();
this->ExcludeFixtureCleanupRegExp.clear();
TestsToRunString.clear();
this->UseUnion = false;
this->TestList.clear();
}
void cmCTestTestHandler::PopulateCustomVectors(cmMakefile* mf)
{
this->CTest->PopulateCustomVector(mf, "CTEST_CUSTOM_PRE_TEST",
this->CustomPreTest);
this->CTest->PopulateCustomVector(mf, "CTEST_CUSTOM_POST_TEST",
this->CustomPostTest);
this->CTest->PopulateCustomVector(mf, "CTEST_CUSTOM_TESTS_IGNORE",
this->CustomTestsIgnore);
this->CTest->PopulateCustomInteger(
mf, "CTEST_CUSTOM_MAXIMUM_PASSED_TEST_OUTPUT_SIZE",
this->CustomMaximumPassedTestOutputSize);
this->CTest->PopulateCustomInteger(
mf, "CTEST_CUSTOM_MAXIMUM_FAILED_TEST_OUTPUT_SIZE",
this->CustomMaximumFailedTestOutputSize);
}
int cmCTestTestHandler::PreProcessHandler()
{
if (!this->ExecuteCommands(this->CustomPreTest)) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Problem executing pre-test command(s)." << std::endl);
return 0;
}
return 1;
}
int cmCTestTestHandler::PostProcessHandler()
{
if (!this->ExecuteCommands(this->CustomPostTest)) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Problem executing post-test command(s)." << std::endl);
return 0;
}
return 1;
}
int cmCTestTestHandler::ProcessHandler()
{
if (!this->ProcessOptions()) {
return -1;
}
this->TestResults.clear();
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
(this->MemCheck ? "Memory check" : "Test")
<< " project "
<< cmSystemTools::GetCurrentWorkingDirectory()
<< std::endl,
this->Quiet);
if (!this->PreProcessHandler()) {
return -1;
}
cmGeneratedFileStream mLogFile;
this->StartLogFile((this->MemCheck ? "DynamicAnalysis" : "Test"), mLogFile);
this->LogFile = &mLogFile;
std::vector<std::string> passed;
std::vector<std::string> failed;
// start the real time clock
auto clock_start = std::chrono::steady_clock::now();
this->ProcessDirectory(passed, failed);
auto clock_finish = std::chrono::steady_clock::now();
bool noTestsFoundError = false;
if (passed.size() + failed.size() == 0) {
if (!this->CTest->GetShowOnly() && !this->CTest->ShouldPrintLabels() &&
this->CTest->GetNoTestsMode() != cmCTest::NoTests::Ignore) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"No tests were found!!!" << std::endl);
if (this->CTest->GetNoTestsMode() == cmCTest::NoTests::Error) {
noTestsFoundError = true;
}
}
} else {
if (this->HandlerVerbose && !passed.empty() &&
(this->UseIncludeRegExpFlag || this->UseExcludeRegExpFlag)) {
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
std::endl
<< "The following tests passed:" << std::endl,
this->Quiet);
for (std::string const& j : passed) {
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"\t" << j << std::endl, this->Quiet);
}
}
SetOfTests resultsSet(this->TestResults.begin(), this->TestResults.end());
std::vector<cmCTestTestHandler::cmCTestTestResult> disabledTests;
for (cmCTestTestResult const& ft : resultsSet) {
if (cmHasLiteralPrefix(ft.CompletionStatus, "SKIP_") ||
ft.CompletionStatus == "Disabled") {
disabledTests.push_back(ft);
}
}
cmDuration durationInSecs = clock_finish - clock_start;
this->LogTestSummary(passed, failed, durationInSecs);
this->LogDisabledTests(disabledTests);
this->LogFailedTests(failed, resultsSet);
}
if (!this->GenerateXML()) {
return 1;
}
if (!this->PostProcessHandler()) {
this->LogFile = nullptr;
return -1;
}
if (!failed.empty()) {
this->LogFile = nullptr;
return -1;
}
if (noTestsFoundError) {
this->LogFile = nullptr;
return -1;
}
this->LogFile = nullptr;
return 0;
}
bool cmCTestTestHandler::ProcessOptions()
{
// Update internal data structure from generic one
this->SetTestsToRunInformation(this->GetOption("TestsToRunInformation"));
this->SetUseUnion(cmIsOn(this->GetOption("UseUnion")));
if (cmIsOn(this->GetOption("ScheduleRandom"))) {
this->CTest->SetScheduleType("Random");
}
if (const char* repeat = this->GetOption("Repeat")) {
cmsys::RegularExpression repeatRegex(
"^(UNTIL_FAIL|UNTIL_PASS|AFTER_TIMEOUT):([0-9]+)$");
if (repeatRegex.find(repeat)) {
std::string const& count = repeatRegex.match(2);
unsigned long n = 1;
cmStrToULong(count, &n); // regex guarantees success
this->RepeatCount = static_cast<int>(n);
if (this->RepeatCount > 1) {
std::string const& mode = repeatRegex.match(1);
if (mode == "UNTIL_FAIL") {
this->RepeatMode = cmCTest::Repeat::UntilFail;
} else if (mode == "UNTIL_PASS") {
this->RepeatMode = cmCTest::Repeat::UntilPass;
} else if (mode == "AFTER_TIMEOUT") {
this->RepeatMode = cmCTest::Repeat::AfterTimeout;
}
}
} else {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Repeat option invalid value: " << repeat << std::endl);
return false;
}
}
if (this->GetOption("ParallelLevel")) {
this->CTest->SetParallelLevel(atoi(this->GetOption("ParallelLevel")));
}
const char* val;
val = this->GetOption("LabelRegularExpression");
if (val) {
this->UseIncludeLabelRegExpFlag = true;
this->IncludeLabelRegExp = val;
}
val = this->GetOption("ExcludeLabelRegularExpression");
if (val) {
this->UseExcludeLabelRegExpFlag = true;
this->ExcludeLabelRegExp = val;
}
val = this->GetOption("IncludeRegularExpression");
if (val) {
this->UseIncludeRegExp();
this->SetIncludeRegExp(val);
}
val = this->GetOption("ExcludeRegularExpression");
if (val) {
this->UseExcludeRegExp();
this->SetExcludeRegExp(val);
}
val = this->GetOption("ExcludeFixtureRegularExpression");
if (val) {
this->ExcludeFixtureRegExp = val;
}
val = this->GetOption("ExcludeFixtureSetupRegularExpression");
if (val) {
this->ExcludeFixtureSetupRegExp = val;
}
val = this->GetOption("ExcludeFixtureCleanupRegularExpression");
if (val) {
this->ExcludeFixtureCleanupRegExp = val;
}
this->SetRerunFailed(cmIsOn(this->GetOption("RerunFailed")));
val = this->GetOption("ResourceSpecFile");
if (val) {
this->UseResourceSpec = true;
this->ResourceSpecFile = val;
auto result = this->ResourceSpec.ReadFromJSONFile(val);
if (result != cmCTestResourceSpec::ReadFileResult::READ_OK) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Could not read/parse resource spec file "
<< val << ": "
<< cmCTestResourceSpec::ResultToString(result)
<< std::endl);
return false;
}
}
return true;
}
void cmCTestTestHandler::LogTestSummary(const std::vector<std::string>& passed,
const std::vector<std::string>& failed,
const cmDuration& durationInSecs)
{
std::size_t total = passed.size() + failed.size();
float percent = float(passed.size()) * 100.0f / float(total);
if (!failed.empty() && percent > 99) {
percent = 99;
}
std::string passColorCode;
std::string failedColorCode;
if (failed.empty()) {
passColorCode = this->CTest->GetColorCode(cmCTest::Color::GREEN);
} else {
failedColorCode = this->CTest->GetColorCode(cmCTest::Color::RED);
}
cmCTestLog(this->CTest, HANDLER_OUTPUT,
std::endl
<< passColorCode << std::lround(percent) << "% tests passed"
<< this->CTest->GetColorCode(cmCTest::Color::CLEAR_COLOR)
<< ", " << failedColorCode << failed.size() << " tests failed"
<< this->CTest->GetColorCode(cmCTest::Color::CLEAR_COLOR)
<< " out of " << total << std::endl);
if ((!this->CTest->GetLabelsForSubprojects().empty() &&
this->CTest->GetSubprojectSummary())) {
this->PrintLabelOrSubprojectSummary(true);
}
if (this->CTest->GetLabelSummary()) {
this->PrintLabelOrSubprojectSummary(false);
}
char realBuf[1024];
sprintf(realBuf, "%6.2f sec", durationInSecs.count());
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
"\nTotal Test time (real) = " << realBuf << "\n",
this->Quiet);
}
void cmCTestTestHandler::LogDisabledTests(
const std::vector<cmCTestTestResult>& disabledTests)
{
if (!disabledTests.empty()) {
cmGeneratedFileStream ofs;
cmCTestLog(this->CTest, HANDLER_OUTPUT,
std::endl
<< "The following tests did not run:" << std::endl);
this->StartLogFile("TestsDisabled", ofs);
const char* disabled_reason;
cmCTestLog(this->CTest, HANDLER_OUTPUT,
this->CTest->GetColorCode(cmCTest::Color::BLUE));
for (cmCTestTestResult const& dt : disabledTests) {
ofs << dt.TestCount << ":" << dt.Name << std::endl;
if (dt.CompletionStatus == "Disabled") {
disabled_reason = "Disabled";
} else {
disabled_reason = "Skipped";
}
cmCTestLog(this->CTest, HANDLER_OUTPUT,
"\t" << std::setw(3) << dt.TestCount << " - " << dt.Name
<< " (" << disabled_reason << ")" << std::endl);
}
cmCTestLog(this->CTest, HANDLER_OUTPUT,
this->CTest->GetColorCode(cmCTest::Color::CLEAR_COLOR));
}
}
void cmCTestTestHandler::LogFailedTests(const std::vector<std::string>& failed,
const SetOfTests& resultsSet)
{
if (!failed.empty()) {
cmGeneratedFileStream ofs;
cmCTestLog(this->CTest, HANDLER_OUTPUT,
std::endl
<< "The following tests FAILED:" << std::endl);
this->StartLogFile("TestsFailed", ofs);
for (cmCTestTestResult const& ft : resultsSet) {
if (ft.Status != cmCTestTestHandler::COMPLETED &&
!cmHasLiteralPrefix(ft.CompletionStatus, "SKIP_") &&
ft.CompletionStatus != "Disabled") {
ofs << ft.TestCount << ":" << ft.Name << std::endl;
auto testColor = cmCTest::Color::RED;
if (this->GetTestStatus(ft) == "Not Run") {
testColor = cmCTest::Color::YELLOW;
}
cmCTestLog(
this->CTest, HANDLER_OUTPUT,
"\t" << this->CTest->GetColorCode(testColor) << std::setw(3)
<< ft.TestCount << " - " << ft.Name << " ("
<< this->GetTestStatus(ft) << ")"
<< this->CTest->GetColorCode(cmCTest::Color::CLEAR_COLOR)
<< std::endl);
}
}
}
}
bool cmCTestTestHandler::GenerateXML()
{
if (this->CTest->GetProduceXML()) {
cmGeneratedFileStream xmlfile;
if (!this->StartResultingXML(
(this->MemCheck ? cmCTest::PartMemCheck : cmCTest::PartTest),
(this->MemCheck ? "DynamicAnalysis" : "Test"), xmlfile)) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Cannot create "
<< (this->MemCheck ? "memory check" : "testing")
<< " XML file" << std::endl);
this->LogFile = nullptr;
return false;
}
cmXMLWriter xml(xmlfile);
this->GenerateDartOutput(xml);
}
return true;
}
void cmCTestTestHandler::PrintLabelOrSubprojectSummary(bool doSubProject)
{
// collect subproject labels
std::vector<std::string> subprojects =
this->CTest->GetLabelsForSubprojects();
std::map<std::string, double> labelTimes;
std::map<std::string, int> labelCounts;
std::set<std::string> labels;
std::string::size_type maxlen = 0;
// initialize maps
for (cmCTestTestProperties& p : this->TestList) {
for (std::string const& l : p.Labels) {
// first check to see if the current label is a subproject label
bool isSubprojectLabel = false;
auto subproject = std::find(subprojects.begin(), subprojects.end(), l);
if (subproject != subprojects.end()) {
isSubprojectLabel = true;
}
// if we are doing sub projects and this label is one, then use it
// if we are not doing sub projects and the label is not one use it
if (doSubProject == isSubprojectLabel) {
if (l.size() > maxlen) {
maxlen = l.size();
}
labels.insert(l);
labelTimes[l] = 0;
labelCounts[l] = 0;
}
}
}
// fill maps
for (cmCTestTestResult& result : this->TestResults) {
cmCTestTestProperties& p = *result.Properties;
for (std::string const& l : p.Labels) {
// only use labels found in labels
if (cmContains(labels, l)) {
labelTimes[l] +=
result.ExecutionTime.count() * result.Properties->Processors;
++labelCounts[l];
}
}
}
// if no labels are found return and print nothing
if (labels.empty()) {
return;
}
// now print times
if (doSubProject) {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
"\nSubproject Time Summary:", this->Quiet);
} else {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
"\nLabel Time Summary:", this->Quiet);
}
for (std::string const& i : labels) {
std::string label = i;
label.resize(maxlen + 3, ' ');
char buf[1024];
sprintf(buf, "%6.2f sec*proc", labelTimes[i]);
std::ostringstream labelCountStr;
labelCountStr << "(" << labelCounts[i] << " test";
if (labelCounts[i] > 1) {
labelCountStr << "s";
}
labelCountStr << ")";
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
"\n"
<< label << " = " << buf << " "
<< labelCountStr.str(),
this->Quiet);
if (this->LogFile) {
*this->LogFile << "\n" << i << " = " << buf << "\n";
}
}
if (this->LogFile) {
*this->LogFile << "\n";
}
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, "\n", this->Quiet);
}
void cmCTestTestHandler::CheckLabelFilterInclude(cmCTestTestProperties& it)
{
// if not using Labels to filter then return
if (!this->UseIncludeLabelRegExpFlag) {
return;
}
// if there are no labels and we are filtering by labels
// then exclude the test as it does not have the label
if (it.Labels.empty()) {
it.IsInBasedOnREOptions = false;
return;
}
// check to see if the label regular expression matches
bool found = false; // assume it does not match
// loop over all labels and look for match
for (std::string const& l : it.Labels) {
if (this->IncludeLabelRegularExpression.find(l)) {
found = true;
}
}
// if no match was found, exclude the test
if (!found) {
it.IsInBasedOnREOptions = false;
}
}
void cmCTestTestHandler::CheckLabelFilterExclude(cmCTestTestProperties& it)
{
// if not using Labels to filter then return
if (!this->UseExcludeLabelRegExpFlag) {
return;
}
// if there are no labels and we are excluding by labels
// then do nothing as a no label can not be a match
if (it.Labels.empty()) {
return;
}
// check to see if the label regular expression matches
bool found = false; // assume it does not match
// loop over all labels and look for match
for (std::string const& l : it.Labels) {
if (this->ExcludeLabelRegularExpression.find(l)) {
found = true;
}
}
// if match was found, exclude the test
if (found) {
it.IsInBasedOnREOptions = false;
}
}
void cmCTestTestHandler::CheckLabelFilter(cmCTestTestProperties& it)
{
this->CheckLabelFilterInclude(it);
this->CheckLabelFilterExclude(it);
}
void cmCTestTestHandler::ComputeTestList()
{
this->TestList.clear(); // clear list of test
this->GetListOfTests();
if (this->RerunFailed) {
this->ComputeTestListForRerunFailed();
return;
}
cmCTestTestHandler::ListOfTests::size_type tmsize = this->TestList.size();
// how many tests are in based on RegExp?
int inREcnt = 0;
for (cmCTestTestProperties& tp : this->TestList) {
this->CheckLabelFilter(tp);
if (tp.IsInBasedOnREOptions) {
inREcnt++;
}
}
// expand the test list based on the union flag
if (this->UseUnion) {
this->ExpandTestsToRunInformation(static_cast<int>(tmsize));
} else {
this->ExpandTestsToRunInformation(inREcnt);
}
// Now create a final list of tests to run
int cnt = 0;
inREcnt = 0;
std::string last_directory;
ListOfTests finalList;
for (cmCTestTestProperties& tp : this->TestList) {
cnt++;
if (tp.IsInBasedOnREOptions) {
inREcnt++;
}
if (this->UseUnion) {
// if it is not in the list and not in the regexp then skip
if ((!this->TestsToRun.empty() && !cmContains(this->TestsToRun, cnt)) &&
!tp.IsInBasedOnREOptions) {
continue;
}
} else {
// is this test in the list of tests to run? If not then skip it
if ((!this->TestsToRun.empty() &&
!cmContains(this->TestsToRun, inREcnt)) ||
!tp.IsInBasedOnREOptions) {
continue;
}
}
tp.Index = cnt; // save the index into the test list for this test
finalList.push_back(tp);
}
UpdateForFixtures(finalList);
// Save the total number of tests before exclusions
this->TotalNumberOfTests = this->TestList.size();
// Set the TestList to the final list of all test
this->TestList = finalList;
this->UpdateMaxTestNameWidth();
}
void cmCTestTestHandler::ComputeTestListForRerunFailed()
{
this->ExpandTestsToRunInformationForRerunFailed();
ListOfTests finalList;
int cnt = 0;
for (cmCTestTestProperties& tp : this->TestList) {
cnt++;
// if this test is not in our list of tests to run, then skip it.
if (!this->TestsToRun.empty() && !cmContains(this->TestsToRun, cnt)) {
continue;
}
tp.Index = cnt;
finalList.push_back(tp);
}
UpdateForFixtures(finalList);
// Save the total number of tests before exclusions
this->TotalNumberOfTests = this->TestList.size();
// Set the TestList to the list of failed tests to rerun
this->TestList = finalList;
this->UpdateMaxTestNameWidth();
}
void cmCTestTestHandler::UpdateForFixtures(ListOfTests& tests) const
{
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Updating test list for fixtures" << std::endl,
this->Quiet);
// Prepare regular expression evaluators
std::string setupRegExp(this->ExcludeFixtureRegExp);
std::string cleanupRegExp(this->ExcludeFixtureRegExp);
if (!this->ExcludeFixtureSetupRegExp.empty()) {
if (setupRegExp.empty()) {
setupRegExp = this->ExcludeFixtureSetupRegExp;
} else {
setupRegExp.append("(" + setupRegExp + ")|(" +
this->ExcludeFixtureSetupRegExp + ")");
}
}
if (!this->ExcludeFixtureCleanupRegExp.empty()) {
if (cleanupRegExp.empty()) {
cleanupRegExp = this->ExcludeFixtureCleanupRegExp;
} else {
cleanupRegExp.append("(" + cleanupRegExp + ")|(" +
this->ExcludeFixtureCleanupRegExp + ")");
}
}
cmsys::RegularExpression excludeSetupRegex(setupRegExp);
cmsys::RegularExpression excludeCleanupRegex(cleanupRegExp);
// Prepare some maps to help us find setup and cleanup tests for
// any given fixture
using TestIterator = ListOfTests::const_iterator;
using FixtureDependencies = std::multimap<std::string, TestIterator>;
using FixtureDepsIterator = FixtureDependencies::const_iterator;
FixtureDependencies fixtureSetups;
FixtureDependencies fixtureCleanups;
for (auto it = this->TestList.begin(); it != this->TestList.end(); ++it) {
const cmCTestTestProperties& p = *it;
for (std::string const& deps : p.FixturesSetup) {
fixtureSetups.insert(std::make_pair(deps, it));
}
for (std::string const& deps : p.FixturesCleanup) {
fixtureCleanups.insert(std::make_pair(deps, it));
}
}
// Prepare fast lookup of tests already included in our list of tests
std::set<std::string> addedTests;
for (cmCTestTestProperties const& p : tests) {
addedTests.insert(p.Name);
}
// These are lookups of fixture name to a list of indices into the final
// tests array for tests which require that fixture and tests which are
// setups for that fixture. They are needed at the end to populate
// dependencies of the cleanup tests in our final list of tests.
std::map<std::string, std::vector<size_t>> fixtureRequirements;
std::map<std::string, std::vector<size_t>> setupFixturesAdded;
// Use integer index for iteration because we append to
// the tests vector as we go
size_t fixtureTestsAdded = 0;
std::set<std::string> addedFixtures;
for (size_t i = 0; i < tests.size(); ++i) {
// Skip disabled tests
if (tests[i].Disabled) {
continue;
}
// There are two things to do for each test:
// 1. For every fixture required by this test, record that fixture as
// being required and create dependencies on that fixture's setup
// tests.
// 2. Record all setup tests in the final test list so we can later make
// cleanup tests in the test list depend on their associated setup
// tests to enforce correct ordering.
// 1. Handle fixture requirements
//
// Must copy the set of fixtures required because we may invalidate
// the tests array by appending to it
std::set<std::string> fixtures = tests[i].FixturesRequired;
for (std::string const& requiredFixtureName : fixtures) {
if (requiredFixtureName.empty()) {
continue;
}
fixtureRequirements[requiredFixtureName].push_back(i);
// Add dependencies to this test for all of the setup tests
// associated with the required fixture. If any of those setup
// tests fail, this test should not run. We make the fixture's
// cleanup tests depend on this test case later.
std::pair<FixtureDepsIterator, FixtureDepsIterator> setupRange =
fixtureSetups.equal_range(requiredFixtureName);
for (auto sIt = setupRange.first; sIt != setupRange.second; ++sIt) {
const std::string& setupTestName = sIt->second->Name;
tests[i].RequireSuccessDepends.insert(setupTestName);
if (!cmContains(tests[i].Depends, setupTestName)) {
tests[i].Depends.push_back(setupTestName);
}
}
// Append any fixture setup/cleanup tests to our test list if they
// are not already in it (they could have been in the original
// set of tests passed to us at the outset or have already been
// added from a previously checked test). A fixture isn't required
// to have setup/cleanup tests.
if (!addedFixtures.insert(requiredFixtureName).second) {
// Already seen this fixture, no need to check it again
continue;
}
// Only add setup tests if this fixture has not been excluded
if (setupRegExp.empty() ||
!excludeSetupRegex.find(requiredFixtureName)) {
std::pair<FixtureDepsIterator, FixtureDepsIterator> fixtureRange =
fixtureSetups.equal_range(requiredFixtureName);
for (auto it = fixtureRange.first; it != fixtureRange.second; ++it) {
ListOfTests::const_iterator lotIt = it->second;
const cmCTestTestProperties& p = *lotIt;
if (!addedTests.insert(p.Name).second) {
// Already have p in our test list
continue;
}
// This is a test not yet in our list, so add it and
// update its index to reflect where it was in the original
// full list of all tests (needed to track individual tests
// across ctest runs for re-run failed, etc.)
tests.push_back(p);
tests.back().Index =
1 + static_cast<int>(std::distance(this->TestList.begin(), lotIt));
++fixtureTestsAdded;
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Added setup test "
<< p.Name << " required by fixture "
<< requiredFixtureName << std::endl,
this->Quiet);
}
}
// Only add cleanup tests if this fixture has not been excluded
if (cleanupRegExp.empty() ||
!excludeCleanupRegex.find(requiredFixtureName)) {
std::pair<FixtureDepsIterator, FixtureDepsIterator> fixtureRange =
fixtureCleanups.equal_range(requiredFixtureName);
for (auto it = fixtureRange.first; it != fixtureRange.second; ++it) {
ListOfTests::const_iterator lotIt = it->second;
const cmCTestTestProperties& p = *lotIt;
if (!addedTests.insert(p.Name).second) {
// Already have p in our test list
continue;
}
// This is a test not yet in our list, so add it and
// update its index to reflect where it was in the original
// full list of all tests (needed to track individual tests
// across ctest runs for re-run failed, etc.)
tests.push_back(p);
tests.back().Index =
1 + static_cast<int>(std::distance(this->TestList.begin(), lotIt));
++fixtureTestsAdded;
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Added cleanup test "
<< p.Name << " required by fixture "
<< requiredFixtureName << std::endl,
this->Quiet);
}
}
}
// 2. Record all setup fixtures included in the final list of tests
for (std::string const& setupFixtureName : tests[i].FixturesSetup) {
if (setupFixtureName.empty()) {
continue;
}
setupFixturesAdded[setupFixtureName].push_back(i);
}
}
// Now that we have the final list of tests, we can update all cleanup
// tests to depend on those tests which require that fixture and on any
// setup tests for that fixture. The latter is required to handle the
// pathological case where setup and cleanup tests are in the test set
// but no other test has that fixture as a requirement.
for (cmCTestTestProperties& p : tests) {
const std::set<std::string>& cleanups = p.FixturesCleanup;
for (std::string const& fixture : cleanups) {
// This cleanup test could be part of the original test list that was
// passed in. It is then possible that no other test requires the
// fIt fixture, so we have to check for this.
auto cIt = fixtureRequirements.find(fixture);
if (cIt != fixtureRequirements.end()) {
const std::vector<size_t>& indices = cIt->second;
for (size_t index : indices) {
const std::string& reqTestName = tests[index].Name;
if (!cmContains(p.Depends, reqTestName)) {
p.Depends.push_back(reqTestName);
}
}
}
// Ensure fixture cleanup tests always run after their setup tests, even
// if no other test cases require the fixture
cIt = setupFixturesAdded.find(fixture);
if (cIt != setupFixturesAdded.end()) {
const std::vector<size_t>& indices = cIt->second;
for (size_t index : indices) {
const std::string& setupTestName = tests[index].Name;
if (!cmContains(p.Depends, setupTestName)) {
p.Depends.push_back(setupTestName);
}
}
}
}
}
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Added " << fixtureTestsAdded
<< " tests to meet fixture requirements"
<< std::endl,
this->Quiet);
}
void cmCTestTestHandler::UpdateMaxTestNameWidth()
{
std::string::size_type max = this->CTest->GetMaxTestNameWidth();
for (cmCTestTestProperties& p : this->TestList) {
if (max < p.Name.size()) {
max = p.Name.size();
}
}
if (static_cast<std::string::size_type>(
this->CTest->GetMaxTestNameWidth()) != max) {
this->CTest->SetMaxTestNameWidth(static_cast<int>(max));
}
}
bool cmCTestTestHandler::GetValue(const char* tag, int& value,
std::istream& fin)
{
std::string line;
bool ret = true;
cmSystemTools::GetLineFromStream(fin, line);
if (line == tag) {
fin >> value;
ret = cmSystemTools::GetLineFromStream(fin, line); // read blank line
} else {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"parse error: missing tag: " << tag << " found [" << line << "]"
<< std::endl);
ret = false;
}
return ret;
}
bool cmCTestTestHandler::GetValue(const char* tag, double& value,
std::istream& fin)
{
std::string line;
cmSystemTools::GetLineFromStream(fin, line);
bool ret = true;
if (line == tag) {
fin >> value;
ret = cmSystemTools::GetLineFromStream(fin, line); // read blank line
} else {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"parse error: missing tag: " << tag << " found [" << line << "]"
<< std::endl);
ret = false;
}
return ret;
}
bool cmCTestTestHandler::GetValue(const char* tag, bool& value,
std::istream& fin)
{
std::string line;
cmSystemTools::GetLineFromStream(fin, line);
bool ret = true;
if (line == tag) {
#ifdef __HAIKU__
int tmp = 0;
fin >> tmp;
value = false;
if (tmp) {
value = true;
}
#else
fin >> value;
#endif
ret = cmSystemTools::GetLineFromStream(fin, line); // read blank line
} else {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"parse error: missing tag: " << tag << " found [" << line << "]"
<< std::endl);
ret = false;
}
return ret;
}
bool cmCTestTestHandler::GetValue(const char* tag, size_t& value,
std::istream& fin)
{
std::string line;
cmSystemTools::GetLineFromStream(fin, line);
bool ret = true;
if (line == tag) {
fin >> value;
ret = cmSystemTools::GetLineFromStream(fin, line); // read blank line
} else {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"parse error: missing tag: " << tag << " found [" << line << "]"
<< std::endl);
ret = false;
}
return ret;
}
bool cmCTestTestHandler::GetValue(const char* tag, std::string& value,
std::istream& fin)
{
std::string line;
cmSystemTools::GetLineFromStream(fin, line);
bool ret = true;
if (line == tag) {
ret = cmSystemTools::GetLineFromStream(fin, value);
} else {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"parse error: missing tag: " << tag << " found [" << line << "]"
<< std::endl);
ret = false;
}
return ret;
}
void cmCTestTestHandler::ProcessDirectory(std::vector<std::string>& passed,
std::vector<std::string>& failed)
{
this->ComputeTestList();
this->StartTest = this->CTest->CurrentTime();
this->StartTestTime = std::chrono::system_clock::now();
auto elapsed_time_start = std::chrono::steady_clock::now();
cmCTestMultiProcessHandler* parallel = new cmCTestMultiProcessHandler;
parallel->SetCTest(this->CTest);
parallel->SetParallelLevel(this->CTest->GetParallelLevel());
parallel->SetTestHandler(this);
if (this->RepeatMode != cmCTest::Repeat::Never) {
parallel->SetRepeatMode(this->RepeatMode, this->RepeatCount);
} else {
parallel->SetRepeatMode(this->CTest->GetRepeatMode(),
this->CTest->GetRepeatCount());
}
parallel->SetQuiet(this->Quiet);
if (this->TestLoad > 0) {
parallel->SetTestLoad(this->TestLoad);
} else {
parallel->SetTestLoad(this->CTest->GetTestLoad());
}
if (this->UseResourceSpec) {
parallel->InitResourceAllocator(this->ResourceSpec);
}
*this->LogFile
<< "Start testing: " << this->CTest->CurrentTime() << std::endl
<< "----------------------------------------------------------"
<< std::endl;
cmCTestMultiProcessHandler::TestMap tests;
cmCTestMultiProcessHandler::PropertiesMap properties;
bool randomSchedule = this->CTest->GetScheduleType() == "Random";
if (randomSchedule) {
srand(static_cast<unsigned>(time(nullptr)));
}
for (cmCTestTestProperties& p : this->TestList) {
cmCTestMultiProcessHandler::TestSet depends;
if (randomSchedule) {
p.Cost = static_cast<float>(rand());
}
if (p.Timeout == cmDuration::zero() &&
this->CTest->GetGlobalTimeout() != cmDuration::zero()) {
p.Timeout = this->CTest->GetGlobalTimeout();
}
if (!p.Depends.empty()) {
for (std::string const& i : p.Depends) {
for (cmCTestTestProperties const& it2 : this->TestList) {
if (it2.Name == i) {
depends.insert(it2.Index);
break; // break out of test loop as name can only match 1
}
}
}
}
tests[p.Index] = depends;
properties[p.Index] = &p;
}
parallel->SetTests(tests, properties);
parallel->SetPassFailVectors(&passed, &failed);
this->TestResults.clear();
parallel->SetTestResults(&this->TestResults);
parallel->CheckResourcesAvailable();
if (this->CTest->ShouldPrintLabels()) {
parallel->PrintLabels();
} else if (this->CTest->GetShowOnly()) {
parallel->PrintTestList();
} else {
parallel->RunTests();
}
delete parallel;
this->EndTest = this->CTest->CurrentTime();
this->EndTestTime = std::chrono::system_clock::now();
this->ElapsedTestingTime =
std::chrono::steady_clock::now() - elapsed_time_start;
*this->LogFile << "End testing: " << this->CTest->CurrentTime() << std::endl;
}
void cmCTestTestHandler::GenerateTestCommand(
std::vector<std::string>& /*unused*/, int /*unused*/)
{
}
void cmCTestTestHandler::GenerateDartOutput(cmXMLWriter& xml)
{
if (!this->CTest->GetProduceXML()) {
return;
}
this->CTest->StartXML(xml, this->AppendXML);
this->CTest->GenerateSubprojectsOutput(xml);
xml.StartElement("Testing");
xml.Element("StartDateTime", this->StartTest);
xml.Element("StartTestTime", this->StartTestTime);
xml.StartElement("TestList");
for (cmCTestTestResult const& result : this->TestResults) {
std::string testPath = result.Path + "/" + result.Name;
xml.Element("Test", this->CTest->GetShortPathToFile(testPath.c_str()));
}
xml.EndElement(); // TestList
for (cmCTestTestResult& result : this->TestResults) {
this->WriteTestResultHeader(xml, result);
xml.StartElement("Results");
if (result.Status != cmCTestTestHandler::NOT_RUN) {
if (result.Status != cmCTestTestHandler::COMPLETED ||
result.ReturnValue) {
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "text/string");
xml.Attribute("name", "Exit Code");
xml.Element("Value", this->GetTestStatus(result));
xml.EndElement(); // NamedMeasurement
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "text/string");
xml.Attribute("name", "Exit Value");
xml.Element("Value", result.ReturnValue);
xml.EndElement(); // NamedMeasurement
}
this->GenerateRegressionImages(xml, result.DartString);
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "numeric/double");
xml.Attribute("name", "Execution Time");
xml.Element("Value", result.ExecutionTime.count());
xml.EndElement(); // NamedMeasurement
if (!result.Reason.empty()) {
const char* reasonType = "Pass Reason";
if (result.Status != cmCTestTestHandler::COMPLETED) {
reasonType = "Fail Reason";
}
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "text/string");
xml.Attribute("name", reasonType);
xml.Element("Value", result.Reason);
xml.EndElement(); // NamedMeasurement
}
}
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "numeric/double");
xml.Attribute("name", "Processors");
xml.Element("Value", result.Properties->Processors);
xml.EndElement(); // NamedMeasurement
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "text/string");
xml.Attribute("name", "Completion Status");
xml.Element("Value", result.CompletionStatus);
xml.EndElement(); // NamedMeasurement
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "text/string");
xml.Attribute("name", "Command Line");
xml.Element("Value", result.FullCommandLine);
xml.EndElement(); // NamedMeasurement
for (auto const& measure : result.Properties->Measurements) {
xml.StartElement("NamedMeasurement");
xml.Attribute("type", "text/string");
xml.Attribute("name", measure.first);
xml.Element("Value", measure.second);
xml.EndElement(); // NamedMeasurement
}
xml.StartElement("Measurement");
xml.StartElement("Value");
if (result.CompressOutput) {
xml.Attribute("encoding", "base64");
xml.Attribute("compression", "gzip");
}
xml.Content(result.Output);
xml.EndElement(); // Value
xml.EndElement(); // Measurement
xml.EndElement(); // Results
this->AttachFiles(xml, result);
this->WriteTestResultFooter(xml, result);
}
xml.Element("EndDateTime", this->EndTest);
xml.Element("EndTestTime", this->EndTestTime);
xml.Element(
"ElapsedMinutes",
std::chrono::duration_cast<std::chrono::minutes>(this->ElapsedTestingTime)
.count());
xml.EndElement(); // Testing
this->CTest->EndXML(xml);
}
void cmCTestTestHandler::WriteTestResultHeader(cmXMLWriter& xml,
cmCTestTestResult const& result)
{
xml.StartElement("Test");
if (result.Status == cmCTestTestHandler::COMPLETED) {
xml.Attribute("Status", "passed");
} else if (result.Status == cmCTestTestHandler::NOT_RUN) {
xml.Attribute("Status", "notrun");
} else {
xml.Attribute("Status", "failed");
}
std::string testPath = result.Path + "/" + result.Name;
xml.Element("Name", result.Name);
xml.Element("Path", this->CTest->GetShortPathToFile(result.Path.c_str()));
xml.Element("FullName", this->CTest->GetShortPathToFile(testPath.c_str()));
xml.Element("FullCommandLine", result.FullCommandLine);
}
void cmCTestTestHandler::WriteTestResultFooter(cmXMLWriter& xml,
cmCTestTestResult const& result)
{
if (!result.Properties->Labels.empty()) {
xml.StartElement("Labels");
std::vector<std::string> const& labels = result.Properties->Labels;
for (std::string const& label : labels) {
xml.Element("Label", label);
}
xml.EndElement(); // Labels
}
xml.EndElement(); // Test
}
void cmCTestTestHandler::AttachFiles(cmXMLWriter& xml,
cmCTestTestResult& result)
{
if (result.Status != cmCTestTestHandler::COMPLETED &&
!result.Properties->AttachOnFail.empty()) {
result.Properties->AttachedFiles.insert(
result.Properties->AttachedFiles.end(),
result.Properties->AttachOnFail.begin(),
result.Properties->AttachOnFail.end());
}
for (std::string const& file : result.Properties->AttachedFiles) {
const std::string& base64 = this->CTest->Base64GzipEncodeFile(file);
std::string const fname = cmSystemTools::GetFilenameName(file);
xml.StartElement("NamedMeasurement");
xml.Attribute("name", "Attached File");
xml.Attribute("encoding", "base64");
xml.Attribute("compression", "tar/gzip");
xml.Attribute("filename", fname);
xml.Attribute("type", "file");
xml.Element("Value", base64);
xml.EndElement(); // NamedMeasurement
}
}
int cmCTestTestHandler::ExecuteCommands(std::vector<std::string>& vec)
{
for (std::string const& it : vec) {
int retVal = 0;
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Run command: " << it << std::endl, this->Quiet);
if (!cmSystemTools::RunSingleCommand(it, nullptr, nullptr, &retVal,
nullptr, cmSystemTools::OUTPUT_MERGE
/*this->Verbose*/) ||
retVal != 0) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Problem running command: " << it << std::endl);
return 0;
}
}
return 1;
}
// Find the appropriate executable to run for a test
std::string cmCTestTestHandler::FindTheExecutable(const char* exe)
{
std::string resConfig;
std::vector<std::string> extraPaths;
std::vector<std::string> failedPaths;
if (strcmp(exe, "NOT_AVAILABLE") == 0) {
return exe;
}
return cmCTestTestHandler::FindExecutable(this->CTest, exe, resConfig,
extraPaths, failedPaths);
}
// add additional configurations to the search path
void cmCTestTestHandler::AddConfigurations(
cmCTest* ctest, std::vector<std::string>& attempted,
std::vector<std::string>& attemptedConfigs, std::string filepath,
std::string& filename)
{
std::string tempPath;
if (!filepath.empty() && filepath[filepath.size() - 1] != '/') {
filepath += "/";
}
tempPath = filepath + filename;
attempted.push_back(tempPath);
attemptedConfigs.emplace_back();
if (!ctest->GetConfigType().empty()) {
tempPath = cmStrCat(filepath, ctest->GetConfigType(), '/', filename);
attempted.push_back(tempPath);
attemptedConfigs.push_back(ctest->GetConfigType());
// If the file is an OSX bundle then the configtype
// will be at the start of the path
tempPath = cmStrCat(ctest->GetConfigType(), '/', filepath, filename);
attempted.push_back(tempPath);
attemptedConfigs.push_back(ctest->GetConfigType());
} else {
// no config specified - try some options...
tempPath = cmStrCat(filepath, "Release/", filename);
attempted.push_back(tempPath);
attemptedConfigs.emplace_back("Release");
tempPath = cmStrCat(filepath, "Debug/", filename);
attempted.push_back(tempPath);
attemptedConfigs.emplace_back("Debug");
tempPath = cmStrCat(filepath, "MinSizeRel/", filename);
attempted.push_back(tempPath);
attemptedConfigs.emplace_back("MinSizeRel");
tempPath = cmStrCat(filepath, "RelWithDebInfo/", filename);
attempted.push_back(tempPath);
attemptedConfigs.emplace_back("RelWithDebInfo");
tempPath = cmStrCat(filepath, "Deployment/", filename);
attempted.push_back(tempPath);
attemptedConfigs.emplace_back("Deployment");
tempPath = cmStrCat(filepath, "Development/", filename);
attempted.push_back(tempPath);
attemptedConfigs.emplace_back("Deployment");
}
}
// Find the appropriate executable to run for a test
std::string cmCTestTestHandler::FindExecutable(
cmCTest* ctest, const char* testCommand, std::string& resultingConfig,
std::vector<std::string>& extraPaths, std::vector<std::string>& failed)
{
// now run the compiled test if we can find it
std::vector<std::string> attempted;
std::vector<std::string> attemptedConfigs;
std::string tempPath;
std::string filepath = cmSystemTools::GetFilenamePath(testCommand);
std::string filename = cmSystemTools::GetFilenameName(testCommand);
cmCTestTestHandler::AddConfigurations(ctest, attempted, attemptedConfigs,
filepath, filename);
// even if a fullpath was specified also try it relative to the current
// directory
if (!filepath.empty() && filepath[0] == '/') {
std::string localfilepath = filepath.substr(1, filepath.size() - 1);
cmCTestTestHandler::AddConfigurations(ctest, attempted, attemptedConfigs,
localfilepath, filename);
}
// if extraPaths are provided and we were not passed a full path, try them,
// try any extra paths
if (filepath.empty()) {
for (std::string const& extraPath : extraPaths) {
std::string filepathExtra = cmSystemTools::GetFilenamePath(extraPath);
std::string filenameExtra = cmSystemTools::GetFilenameName(extraPath);
cmCTestTestHandler::AddConfigurations(ctest, attempted, attemptedConfigs,
filepathExtra, filenameExtra);
}
}
// store the final location in fullPath
std::string fullPath;
// now look in the paths we specified above
for (unsigned int ai = 0; ai < attempted.size() && fullPath.empty(); ++ai) {
// first check without exe extension
if (cmSystemTools::FileExists(attempted[ai]) &&
!cmSystemTools::FileIsDirectory(attempted[ai])) {
fullPath = cmSystemTools::CollapseFullPath(attempted[ai]);
resultingConfig = attemptedConfigs[ai];
}
// then try with the exe extension
else {
failed.push_back(attempted[ai]);
tempPath =
cmStrCat(attempted[ai], cmSystemTools::GetExecutableExtension());
if (cmSystemTools::FileExists(tempPath) &&
!cmSystemTools::FileIsDirectory(tempPath)) {
fullPath = cmSystemTools::CollapseFullPath(tempPath);
resultingConfig = attemptedConfigs[ai];
} else {
failed.push_back(tempPath);
}
}
}
// if everything else failed, check the users path, but only if a full path
// wasn't specified
if (fullPath.empty() && filepath.empty()) {
std::string const path = cmSystemTools::FindProgram(filename.c_str());
if (!path.empty()) {
resultingConfig.clear();
return path;
}
}
if (fullPath.empty()) {
cmCTestLog(ctest, HANDLER_OUTPUT,
"Could not find executable "
<< testCommand << "\n"
<< "Looked in the following places:\n");
for (std::string const& f : failed) {
cmCTestLog(ctest, HANDLER_OUTPUT, f << "\n");
}
}
return fullPath;
}
bool cmCTestTestHandler::ParseResourceGroupsProperty(
const std::string& val,
std::vector<std::vector<cmCTestTestResourceRequirement>>& resourceGroups)
{
cmCTestResourceGroupsLexerHelper lexer(resourceGroups);
return lexer.ParseString(val);
}
void cmCTestTestHandler::GetListOfTests()
{
if (!this->IncludeLabelRegExp.empty()) {
this->IncludeLabelRegularExpression.compile(
this->IncludeLabelRegExp.c_str());
}
if (!this->ExcludeLabelRegExp.empty()) {
this->ExcludeLabelRegularExpression.compile(
this->ExcludeLabelRegExp.c_str());
}
if (!this->IncludeRegExp.empty()) {
this->IncludeTestsRegularExpression.compile(this->IncludeRegExp.c_str());
}
if (!this->ExcludeRegExp.empty()) {
this->ExcludeTestsRegularExpression.compile(this->ExcludeRegExp.c_str());
}
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Constructing a list of tests" << std::endl, this->Quiet);
cmake cm(cmake::RoleScript, cmState::CTest);
cm.SetHomeDirectory("");
cm.SetHomeOutputDirectory("");
cm.GetCurrentSnapshot().SetDefaultDefinitions();
cmGlobalGenerator gg(&cm);
cmMakefile mf(&gg, cm.GetCurrentSnapshot());
mf.AddDefinition("CTEST_CONFIGURATION_TYPE", this->CTest->GetConfigType());
// Add handler for ADD_TEST
cm.GetState()->AddBuiltinCommand("add_test", cmCTestAddTestCommand(this));
// Add handler for SUBDIRS
cm.GetState()->AddBuiltinCommand("subdirs", cmCTestSubdirCommand);
// Add handler for ADD_SUBDIRECTORY
cm.GetState()->AddBuiltinCommand("add_subdirectory",
cmCTestAddSubdirectoryCommand);
// Add handler for SET_TESTS_PROPERTIES
cm.GetState()->AddBuiltinCommand("set_tests_properties",
cmCTestSetTestsPropertiesCommand(this));
// Add handler for SET_DIRECTORY_PROPERTIES
cm.GetState()->RemoveBuiltinCommand("set_directory_properties");
cm.GetState()->AddBuiltinCommand("set_directory_properties",
cmCTestSetDirectoryPropertiesCommand(this));
const char* testFilename;
if (cmSystemTools::FileExists("CTestTestfile.cmake")) {
// does the CTestTestfile.cmake exist ?
testFilename = "CTestTestfile.cmake";
} else if (cmSystemTools::FileExists("DartTestfile.txt")) {
// does the DartTestfile.txt exist ?
testFilename = "DartTestfile.txt";
} else {
return;
}
if (!mf.ReadListFile(testFilename)) {
return;
}
if (cmSystemTools::GetErrorOccuredFlag()) {
return;
}
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Done constructing a list of tests" << std::endl,
this->Quiet);
}
void cmCTestTestHandler::UseIncludeRegExp()
{
this->UseIncludeRegExpFlag = true;
}
void cmCTestTestHandler::UseExcludeRegExp()
{
this->UseExcludeRegExpFlag = true;
this->UseExcludeRegExpFirst = !this->UseIncludeRegExpFlag;
}
std::string cmCTestTestHandler::GetTestStatus(cmCTestTestResult const& result)
{
static const char* statuses[] = { "Not Run", "Timeout", "SEGFAULT",
"ILLEGAL", "INTERRUPT", "NUMERICAL",
"OTHER_FAULT", "Failed", "BAD_COMMAND",
"Completed" };
int status = result.Status;
if (status < cmCTestTestHandler::NOT_RUN ||
status > cmCTestTestHandler::COMPLETED) {
return "No Status";
}
if (status == cmCTestTestHandler::OTHER_FAULT) {
return result.ExceptionStatus;
}
return statuses[status];
}
void cmCTestTestHandler::ExpandTestsToRunInformation(size_t numTests)
{
if (this->TestsToRunString.empty()) {
return;
}
int start;
int end = -1;
double stride = -1;
std::string::size_type pos = 0;
std::string::size_type pos2;
// read start
if (GetNextNumber(this->TestsToRunString, start, pos, pos2)) {
// read end
if (GetNextNumber(this->TestsToRunString, end, pos, pos2)) {
// read stride
if (GetNextRealNumber(this->TestsToRunString, stride, pos, pos2)) {
int val = 0;
// now read specific numbers
while (GetNextNumber(this->TestsToRunString, val, pos, pos2)) {
this->TestsToRun.push_back(val);
}
this->TestsToRun.push_back(val);
}
}
}
// if start is not specified then we assume we start at 1
if (start == -1) {
start = 1;
}
// if end isnot specified then we assume we end with the last test
if (end == -1) {
end = static_cast<int>(numTests);
}
// if the stride wasn't specified then it defaults to 1
if (stride == -1) {
stride = 1;
}
// if we have a range then add it
if (end != -1 && start != -1 && stride > 0) {
int i = 0;
while (i * stride + start <= end) {
this->TestsToRun.push_back(static_cast<int>(i * stride + start));
++i;
}
}
// sort the array
std::sort(this->TestsToRun.begin(), this->TestsToRun.end(),
std::less<int>());
// remove duplicates
auto new_end = std::unique(this->TestsToRun.begin(), this->TestsToRun.end());
this->TestsToRun.erase(new_end, this->TestsToRun.end());
}
void cmCTestTestHandler::ExpandTestsToRunInformationForRerunFailed()
{
std::string dirName = this->CTest->GetBinaryDir() + "/Testing/Temporary";
cmsys::Directory directory;
if (directory.Load(dirName) == 0) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Unable to read the contents of " << dirName << std::endl);
return;
}
int numFiles =
static_cast<int>(cmsys::Directory::GetNumberOfFilesInDirectory(dirName));
std::string pattern = "LastTestsFailed";
std::string logName;
for (int i = 0; i < numFiles; ++i) {
std::string fileName = directory.GetFile(i);
// bcc crashes if we attempt a normal substring comparison,
// hence the following workaround
std::string fileNameSubstring = fileName.substr(0, pattern.length());
if (fileNameSubstring != pattern) {
continue;
}
if (logName.empty()) {
logName = fileName;
} else {
// if multiple matching logs were found we use the most recently
// modified one.
int res;
cmSystemTools::FileTimeCompare(logName, fileName, &res);
if (res == -1) {
logName = fileName;
}
}
}
std::string lastTestsFailedLog =
this->CTest->GetBinaryDir() + "/Testing/Temporary/" + logName;
if (!cmSystemTools::FileExists(lastTestsFailedLog)) {
if (!this->CTest->GetShowOnly() && !this->CTest->ShouldPrintLabels()) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
lastTestsFailedLog << " does not exist!" << std::endl);
}
return;
}
// parse the list of tests to rerun from LastTestsFailed.log
cmsys::ifstream ifs(lastTestsFailedLog.c_str());
if (ifs) {
std::string line;
std::string::size_type pos;
while (cmSystemTools::GetLineFromStream(ifs, line)) {
pos = line.find(':', 0);
if (pos == std::string::npos) {
continue;
}
int val = atoi(line.substr(0, pos).c_str());
this->TestsToRun.push_back(val);
}
ifs.close();
} else if (!this->CTest->GetShowOnly() &&
!this->CTest->ShouldPrintLabels()) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Problem reading file: "
<< lastTestsFailedLog
<< " while generating list of previously failed tests."
<< std::endl);
}
}
// Just for convenience
#define SPACE_REGEX "[ \t\r\n]"
void cmCTestTestHandler::GenerateRegressionImages(cmXMLWriter& xml,
const std::string& dart)
{
cmsys::RegularExpression twoattributes(
"<DartMeasurement" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*>([^<]*)</DartMeasurement>");
cmsys::RegularExpression threeattributes(
"<DartMeasurement" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*>([^<]*)</DartMeasurement>");
cmsys::RegularExpression fourattributes(
"<DartMeasurement" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*>([^<]*)</DartMeasurement>");
cmsys::RegularExpression cdatastart(
"<DartMeasurement" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*>" SPACE_REGEX "*<!\\[CDATA\\[");
cmsys::RegularExpression cdataend("]]>" SPACE_REGEX "*</DartMeasurement>");
cmsys::RegularExpression measurementfile(
"<DartMeasurementFile" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*(name|type|encoding|compression)=\"([^\"]*)\"" SPACE_REGEX
"*>([^<]*)</DartMeasurementFile>");
bool done = false;
std::string cxml = dart;
while (!done) {
if (twoattributes.find(cxml)) {
xml.StartElement("NamedMeasurement");
xml.Attribute(twoattributes.match(1).c_str(), twoattributes.match(2));
xml.Attribute(twoattributes.match(3).c_str(), twoattributes.match(4));
xml.Element("Value", twoattributes.match(5));
xml.EndElement();
cxml.erase(twoattributes.start(),
twoattributes.end() - twoattributes.start());
} else if (threeattributes.find(cxml)) {
xml.StartElement("NamedMeasurement");
xml.Attribute(threeattributes.match(1).c_str(),
threeattributes.match(2));
xml.Attribute(threeattributes.match(3).c_str(),
threeattributes.match(4));
xml.Attribute(threeattributes.match(5).c_str(),
threeattributes.match(6));
xml.Element("Value", twoattributes.match(7));
xml.EndElement();
cxml.erase(threeattributes.start(),
threeattributes.end() - threeattributes.start());
} else if (fourattributes.find(cxml)) {
xml.StartElement("NamedMeasurement");
xml.Attribute(fourattributes.match(1).c_str(), fourattributes.match(2));
xml.Attribute(fourattributes.match(3).c_str(), fourattributes.match(4));
xml.Attribute(fourattributes.match(5).c_str(), fourattributes.match(6));
xml.Attribute(fourattributes.match(7).c_str(), fourattributes.match(8));
xml.Element("Value", twoattributes.match(9));
xml.EndElement();
cxml.erase(fourattributes.start(),
fourattributes.end() - fourattributes.start());
} else if (cdatastart.find(cxml) && cdataend.find(cxml)) {
xml.StartElement("NamedMeasurement");
xml.Attribute(cdatastart.match(1).c_str(), cdatastart.match(2));
xml.Attribute(cdatastart.match(3).c_str(), cdatastart.match(4));
xml.StartElement("Value");
xml.CData(
cxml.substr(cdatastart.end(), cdataend.start() - cdatastart.end()));
xml.EndElement(); // Value
xml.EndElement(); // NamedMeasurement
cxml.erase(cdatastart.start(), cdataend.end() - cdatastart.start());
} else if (measurementfile.find(cxml)) {
const std::string& filename =
cmCTest::CleanString(measurementfile.match(5));
if (cmSystemTools::FileExists(filename)) {
long len = cmSystemTools::FileLength(filename);
if (len == 0) {
std::string k1 = measurementfile.match(1);
std::string v1 = measurementfile.match(2);
std::string k2 = measurementfile.match(3);
std::string v2 = measurementfile.match(4);
if (cmSystemTools::LowerCase(k1) == "type") {
v1 = "text/string";
}
if (cmSystemTools::LowerCase(k2) == "type") {
v2 = "text/string";
}
xml.StartElement("NamedMeasurement");
xml.Attribute(k1.c_str(), v1);
xml.Attribute(k2.c_str(), v2);
xml.Attribute("encoding", "none");
xml.Element("Value", "Image " + filename + " is empty");
xml.EndElement();
} else {
cmsys::ifstream ifs(filename.c_str(),
std::ios::in
#ifdef _WIN32
| std::ios::binary
#endif
);
unsigned char* file_buffer = new unsigned char[len + 1];
ifs.read(reinterpret_cast<char*>(file_buffer), len);
unsigned char* encoded_buffer = new unsigned char[static_cast<int>(
static_cast<double>(len) * 1.5 + 5.0)];
size_t rlen =
cmsysBase64_Encode(file_buffer, len, encoded_buffer, 1);
xml.StartElement("NamedMeasurement");
xml.Attribute(measurementfile.match(1).c_str(),
measurementfile.match(2));
xml.Attribute(measurementfile.match(3).c_str(),
measurementfile.match(4));
xml.Attribute("encoding", "base64");
std::ostringstream ostr;
for (size_t cc = 0; cc < rlen; cc++) {
ostr << encoded_buffer[cc];
if (cc % 60 == 0 && cc) {
ostr << std::endl;
}
}
xml.Element("Value", ostr.str());
xml.EndElement(); // NamedMeasurement
delete[] file_buffer;
delete[] encoded_buffer;
}
} else {
int idx = 4;
if (measurementfile.match(1) == "name") {
idx = 2;
}
xml.StartElement("NamedMeasurement");
xml.Attribute("name", measurementfile.match(idx));
xml.Attribute("text", "text/string");
xml.Element("Value", "File " + filename + " not found");
xml.EndElement();
cmCTestOptionalLog(
this->CTest, HANDLER_OUTPUT,
"File \"" << filename << "\" not found." << std::endl, this->Quiet);
}
cxml.erase(measurementfile.start(),
measurementfile.end() - measurementfile.start());
} else {
done = true;
}
}
}
void cmCTestTestHandler::SetIncludeRegExp(const char* arg)
{
this->IncludeRegExp = arg;
}
void cmCTestTestHandler::SetExcludeRegExp(const char* arg)
{
this->ExcludeRegExp = arg;
}
void cmCTestTestHandler::SetTestsToRunInformation(const char* in)
{
if (!in) {
return;
}
this->TestsToRunString = in;
// if the argument is a file, then read it and use the contents as the
// string
if (cmSystemTools::FileExists(in)) {
cmsys::ifstream fin(in);
unsigned long filelen = cmSystemTools::FileLength(in);
char* buff = new char[filelen + 1];
fin.getline(buff, filelen);
buff[fin.gcount()] = 0;
this->TestsToRunString = buff;
delete[] buff;
}
}
bool cmCTestTestHandler::CleanTestOutput(std::string& output, size_t length)
{
if (!length || length >= output.size() ||
output.find("CTEST_FULL_OUTPUT") != std::string::npos) {
return true;
}
// Truncate at given length but do not break in the middle of a multi-byte
// UTF-8 encoding.
char const* const begin = output.c_str();
char const* const end = begin + output.size();
char const* const truncate = begin + length;
char const* current = begin;
while (current < truncate) {
unsigned int ch;
if (const char* next = cm_utf8_decode_character(current, end, &ch)) {
if (next > truncate) {
break;
}
current = next;
} else // Bad byte will be handled by cmXMLWriter.
{
++current;
}
}
output = output.substr(0, current - begin);
// Append truncation message.
std::ostringstream msg;
msg << "...\n"
"The rest of the test output was removed since it exceeds the "
"threshold "
"of "
<< length << " bytes.\n";
output += msg.str();
return true;
}
bool cmCTestTestHandler::SetTestsProperties(
const std::vector<std::string>& args)
{
std::vector<std::string>::const_iterator it;
std::vector<std::string> tests;
bool found = false;
for (it = args.begin(); it != args.end(); ++it) {
if (*it == "PROPERTIES") {
found = true;
break;
}
tests.push_back(*it);
}
if (!found) {
return false;
}
++it; // skip PROPERTIES
for (; it != args.end(); ++it) {
std::string key = *it;
++it;
if (it == args.end()) {
break;
}
std::string val = *it;
for (std::string const& t : tests) {
for (cmCTestTestProperties& rt : this->TestList) {
if (t == rt.Name) {
if (key == "_BACKTRACE_TRIPLES") {
std::vector<std::string> triples;
// allow empty args in the triples
cmExpandList(val, triples, true);
// Ensure we have complete triples otherwise the data is corrupt.
if (triples.size() % 3 == 0) {
cmState state;
rt.Backtrace = cmListFileBacktrace(state.CreateBaseSnapshot());
// the first entry represents the top of the trace so we need to
// reconstruct the backtrace in reverse
for (size_t i = triples.size(); i >= 3; i -= 3) {
cmListFileContext fc;
fc.FilePath = triples[i - 3];
long line = 0;
if (!cmStrToLong(triples[i - 2], &line)) {
line = 0;
}
fc.Line = line;
fc.Name = triples[i - 1];
rt.Backtrace = rt.Backtrace.Push(fc);
}
}
}
if (key == "WILL_FAIL") {
rt.WillFail = cmIsOn(val);
}
if (key == "DISABLED") {
rt.Disabled = cmIsOn(val);
}
if (key == "ATTACHED_FILES") {
cmExpandList(val, rt.AttachedFiles);
}
if (key == "ATTACHED_FILES_ON_FAIL") {
cmExpandList(val, rt.AttachOnFail);
}
if (key == "RESOURCE_LOCK") {
std::vector<std::string> lval = cmExpandedList(val);
rt.LockedResources.insert(lval.begin(), lval.end());
}
if (key == "FIXTURES_SETUP") {
std::vector<std::string> lval = cmExpandedList(val);
rt.FixturesSetup.insert(lval.begin(), lval.end());
}
if (key == "FIXTURES_CLEANUP") {
std::vector<std::string> lval = cmExpandedList(val);
rt.FixturesCleanup.insert(lval.begin(), lval.end());
}
if (key == "FIXTURES_REQUIRED") {
std::vector<std::string> lval = cmExpandedList(val);
rt.FixturesRequired.insert(lval.begin(), lval.end());
}
if (key == "TIMEOUT") {
rt.Timeout = cmDuration(atof(val.c_str()));
rt.ExplicitTimeout = true;
}
if (key == "COST") {
rt.Cost = static_cast<float>(atof(val.c_str()));
}
if (key == "REQUIRED_FILES") {
cmExpandList(val, rt.RequiredFiles);
}
if (key == "RUN_SERIAL") {
rt.RunSerial = cmIsOn(val);
}
if (key == "FAIL_REGULAR_EXPRESSION") {
std::vector<std::string> lval = cmExpandedList(val);
for (std::string const& cr : lval) {
rt.ErrorRegularExpressions.emplace_back(cr, cr);
}
}
if (key == "SKIP_REGULAR_EXPRESSION") {
std::vector<std::string> lval = cmExpandedList(val);
for (std::string const& cr : lval) {
rt.SkipRegularExpressions.emplace_back(cr, cr);
}
}
if (key == "PROCESSORS") {
rt.Processors = atoi(val.c_str());
if (rt.Processors < 1) {
rt.Processors = 1;
}
}
if (key == "PROCESSOR_AFFINITY") {
rt.WantAffinity = cmIsOn(val);
}
if (key == "RESOURCE_GROUPS") {
if (!ParseResourceGroupsProperty(val, rt.ResourceGroups)) {
return false;
}
}
if (key == "SKIP_RETURN_CODE") {
rt.SkipReturnCode = atoi(val.c_str());
if (rt.SkipReturnCode < 0 || rt.SkipReturnCode > 255) {
rt.SkipReturnCode = -1;
}
}
if (key == "DEPENDS") {
cmExpandList(val, rt.Depends);
}
if (key == "ENVIRONMENT") {
cmExpandList(val, rt.Environment);
}
if (key == "LABELS") {
std::vector<std::string> Labels = cmExpandedList(val);
rt.Labels.insert(rt.Labels.end(), Labels.begin(), Labels.end());
// sort the array
std::sort(rt.Labels.begin(), rt.Labels.end());
// remove duplicates
auto new_end = std::unique(rt.Labels.begin(), rt.Labels.end());
rt.Labels.erase(new_end, rt.Labels.end());
}
if (key == "MEASUREMENT") {
size_t pos = val.find_first_of('=');
if (pos != std::string::npos) {
std::string mKey = val.substr(0, pos);
std::string mVal = val.substr(pos + 1);
rt.Measurements[mKey] = std::move(mVal);
} else {
rt.Measurements[val] = "1";
}
}
if (key == "PASS_REGULAR_EXPRESSION") {
std::vector<std::string> lval = cmExpandedList(val);
for (std::string const& cr : lval) {
rt.RequiredRegularExpressions.emplace_back(cr, cr);
}
}
if (key == "WORKING_DIRECTORY") {
rt.Directory = val;
}
if (key == "TIMEOUT_AFTER_MATCH") {
std::vector<std::string> propArgs = cmExpandedList(val);
if (propArgs.size() != 2) {
cmCTestLog(this->CTest, WARNING,
"TIMEOUT_AFTER_MATCH expects two arguments, found "
<< propArgs.size() << std::endl);
} else {
rt.AlternateTimeout = cmDuration(atof(propArgs[0].c_str()));
std::vector<std::string> lval = cmExpandedList(propArgs[1]);
for (std::string const& cr : lval) {
rt.TimeoutRegularExpressions.emplace_back(cr, cr);
}
}
}
}
}
}
}
return true;
}
bool cmCTestTestHandler::SetDirectoryProperties(
const std::vector<std::string>& args)
{
std::vector<std::string>::const_iterator it;
std::vector<std::string> tests;
bool found = false;
for (it = args.begin(); it != args.end(); ++it) {
if (*it == "PROPERTIES") {
found = true;
break;
}
tests.push_back(*it);
}
if (!found) {
return false;
}
++it; // skip PROPERTIES
for (; it != args.end(); ++it) {
std::string key = *it;
++it;
if (it == args.end()) {
break;
}
std::string val = *it;
for (cmCTestTestProperties& rt : this->TestList) {
std::string cwd = cmSystemTools::GetCurrentWorkingDirectory();
if (cwd == rt.Directory) {
if (key == "LABELS") {
std::vector<std::string> DirectoryLabels = cmExpandedList(val);
rt.Labels.insert(rt.Labels.end(), DirectoryLabels.begin(),
DirectoryLabels.end());
// sort the array
std::sort(rt.Labels.begin(), rt.Labels.end());
// remove duplicates
auto new_end = std::unique(rt.Labels.begin(), rt.Labels.end());
rt.Labels.erase(new_end, rt.Labels.end());
}
}
}
}
return true;
}
bool cmCTestTestHandler::AddTest(const std::vector<std::string>& args)
{
const std::string& testname = args[0];
cmCTestOptionalLog(this->CTest, DEBUG, "Add test: " << args[0] << std::endl,
this->Quiet);
if (this->UseExcludeRegExpFlag && this->UseExcludeRegExpFirst &&
this->ExcludeTestsRegularExpression.find(testname)) {
return true;
}
if (this->MemCheck) {
std::vector<std::string>::iterator it;
bool found = false;
for (it = this->CustomTestsIgnore.begin();
it != this->CustomTestsIgnore.end(); ++it) {
if (*it == testname) {
found = true;
break;
}
}
if (found) {
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Ignore memcheck: " << *it << std::endl, this->Quiet);
return true;
}
} else {
std::vector<std::string>::iterator it;
bool found = false;
for (it = this->CustomTestsIgnore.begin();
it != this->CustomTestsIgnore.end(); ++it) {
if (*it == testname) {
found = true;
break;
}
}
if (found) {
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Ignore test: " << *it << std::endl, this->Quiet);
return true;
}
}
cmCTestTestProperties test;
test.Name = testname;
test.Args = args;
test.Directory = cmSystemTools::GetCurrentWorkingDirectory();
cmCTestOptionalLog(this->CTest, DEBUG,
"Set test directory: " << test.Directory << std::endl,
this->Quiet);
test.IsInBasedOnREOptions = true;
test.WillFail = false;
test.Disabled = false;
test.RunSerial = false;
test.Timeout = cmDuration::zero();
test.ExplicitTimeout = false;
test.Cost = 0;
test.Processors = 1;
test.WantAffinity = false;
test.SkipReturnCode = -1;
test.PreviousRuns = 0;
if (this->UseIncludeRegExpFlag &&
!this->IncludeTestsRegularExpression.find(testname)) {
test.IsInBasedOnREOptions = false;
} else if (this->UseExcludeRegExpFlag && !this->UseExcludeRegExpFirst &&
this->ExcludeTestsRegularExpression.find(testname)) {
test.IsInBasedOnREOptions = false;
}
this->TestList.push_back(test);
return true;
}
bool cmCTestTestHandler::cmCTestTestResourceRequirement::operator==(
const cmCTestTestResourceRequirement& other) const
{
return this->ResourceType == other.ResourceType &&
this->SlotsNeeded == other.SlotsNeeded &&
this->UnitsNeeded == other.UnitsNeeded;
}
bool cmCTestTestHandler::cmCTestTestResourceRequirement::operator!=(
const cmCTestTestResourceRequirement& other) const
{
return !(*this == other);
}