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fuchsia / third_party / cmake / refs/heads/upstream/master / . / Source / CTest / cmCTestMultiProcessHandler.cxx
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/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
file Copyright.txt or https://cmake.org/licensing for details. */
#include "cmCTestMultiProcessHandler.h"
#include <algorithm>
#include <cassert>
#include <chrono>
#include <cmath>
#include <cstddef> // IWYU pragma: keep
#include <cstdlib>
#include <cstring>
#include <iomanip>
#include <iostream>
#include <list>
#include <sstream>
#include <stack>
#include <unordered_map>
#include <utility>
#include <vector>
#include <cm/memory>
#include <cm/optional>
#include <cmext/algorithm>
#include <cm3p/json/value.h>
#include <cm3p/json/writer.h>
#include <cm3p/uv.h>
#include "cmsys/FStream.hxx"
#include "cmsys/SystemInformation.hxx"
#include "cmAffinity.h"
#include "cmCTest.h"
#include "cmCTestBinPacker.h"
#include "cmCTestRunTest.h"
#include "cmCTestTestHandler.h"
#include "cmDuration.h"
#include "cmJSONState.h"
#include "cmListFileCache.h"
#include "cmRange.h"
#include "cmStringAlgorithms.h"
#include "cmSystemTools.h"
#include "cmUVJobServerClient.h"
#include "cmWorkingDirectory.h"
namespace {
// For unspecified parallelism, limit to the number of processors,
// but with a minimum greater than 1 so there is some parallelism.
constexpr unsigned long kParallelLevelMinimum = 2u;
// For "unbounded" parallelism, limit to a very high value.
// Under a job server, parallelism is effectively limited
// only by available job server tokens.
constexpr unsigned long kParallelLevelUnbounded = 0x10000u;
}
namespace cmsys {
class RegularExpression;
}
class TestComparator
{
public:
TestComparator(cmCTestMultiProcessHandler* handler)
: Handler(handler)
{
}
// Sorts tests in descending order of cost
bool operator()(int index1, int index2) const
{
return this->Handler->Properties[index1]->Cost >
this->Handler->Properties[index2]->Cost;
}
private:
cmCTestMultiProcessHandler* Handler;
};
cmCTestMultiProcessHandler::cmCTestMultiProcessHandler(
cmCTest* ctest, cmCTestTestHandler* handler)
: CTest(ctest)
, TestHandler(handler)
, ProcessorsAvailable(cmAffinity::GetProcessorsAvailable())
, HaveAffinity(this->ProcessorsAvailable.size())
, ParallelLevelDefault(kParallelLevelMinimum)
{
}
cmCTestMultiProcessHandler::~cmCTestMultiProcessHandler() = default;
// Set the tests
bool cmCTestMultiProcessHandler::SetTests(TestMap tests,
PropertiesMap properties)
{
this->PendingTests = std::move(tests);
this->Properties = std::move(properties);
this->Total = this->PendingTests.size();
if (!this->CTest->GetShowOnly()) {
this->ReadCostData();
this->HasCycles = !this->CheckCycles();
this->HasInvalidGeneratedResourceSpec =
!this->CheckGeneratedResourceSpec();
if (this->HasCycles || this->HasInvalidGeneratedResourceSpec) {
return false;
}
this->CreateTestCostList();
}
return true;
}
// Set the max number of tests that can be run at the same time.
void cmCTestMultiProcessHandler::SetParallelLevel(cm::optional<size_t> level)
{
this->ParallelLevel = level;
if (!this->ParallelLevel) {
// '-j' was given with no value. Limit by number of processors.
cmsys::SystemInformation info;
info.RunCPUCheck();
unsigned long processorCount = info.GetNumberOfLogicalCPU();
if (cm::optional<std::string> fakeProcessorCount =
cmSystemTools::GetEnvVar(
"__CTEST_FAKE_PROCESSOR_COUNT_FOR_TESTING")) {
unsigned long pc = 0;
if (cmStrToULong(*fakeProcessorCount, &pc)) {
processorCount = pc;
} else {
cmSystemTools::Error("Failed to parse fake processor count: " +
*fakeProcessorCount);
}
}
this->ParallelLevelDefault =
std::max(kParallelLevelMinimum, processorCount);
}
}
size_t cmCTestMultiProcessHandler::GetParallelLevel() const
{
if ((this->ParallelLevel && *this->ParallelLevel == 0) ||
(!this->ParallelLevel && this->JobServerClient)) {
return kParallelLevelUnbounded;
}
if (this->ParallelLevel) {
return *this->ParallelLevel;
}
return this->ParallelLevelDefault;
}
void cmCTestMultiProcessHandler::SetTestLoad(unsigned long load)
{
this->TestLoad = load;
std::string fake_load_value;
if (cmSystemTools::GetEnv("__CTEST_FAKE_LOAD_AVERAGE_FOR_TESTING",
fake_load_value)) {
if (!cmStrToULong(fake_load_value, &this->FakeLoadForTesting)) {
cmSystemTools::Error("Failed to parse fake load value: " +
fake_load_value);
}
}
}
bool cmCTestMultiProcessHandler::Complete()
{
return this->Completed == this->Total;
}
void cmCTestMultiProcessHandler::InitializeLoop()
{
this->Loop.init();
this->StartNextTestsOnIdle_.init(*this->Loop, this);
this->StartNextTestsOnTimer_.init(*this->Loop, this);
this->JobServerClient = cmUVJobServerClient::Connect(
*this->Loop, /*onToken=*/[this]() { this->JobServerReceivedToken(); },
/*onDisconnect=*/nullptr);
if (this->JobServerClient) {
cmCTestLog(this->CTest, OUTPUT,
"Connected to MAKE jobserver" << std::endl);
}
}
void cmCTestMultiProcessHandler::FinalizeLoop()
{
this->JobServerClient.reset();
this->StartNextTestsOnTimer_.reset();
this->StartNextTestsOnIdle_.reset();
this->Loop.reset();
}
void cmCTestMultiProcessHandler::RunTests()
{
this->CheckResume();
if (this->HasCycles || this->HasInvalidGeneratedResourceSpec) {
return;
}
this->TestHandler->SetMaxIndex(this->FindMaxIndex());
this->InitializeLoop();
this->StartNextTestsOnIdle();
uv_run(this->Loop, UV_RUN_DEFAULT);
this->FinalizeLoop();
if (!this->StopTimePassed && !this->CheckStopOnFailure()) {
assert(this->Complete());
assert(this->PendingTests.empty());
}
assert(this->AllResourcesAvailable());
this->MarkFinished();
this->UpdateCostData();
}
void cmCTestMultiProcessHandler::StartTestProcess(int test)
{
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"test " << test << "\n", this->Quiet);
auto testRun = cm::make_unique<cmCTestRunTest>(*this, test);
if (this->RepeatMode != cmCTest::Repeat::Never) {
testRun->SetRepeatMode(this->RepeatMode);
testRun->SetNumberOfRuns(this->RepeatCount);
}
if (this->UseResourceSpec) {
testRun->SetUseAllocatedResources(true);
testRun->SetAllocatedResources(this->AllocatedResources[test]);
}
// Find any failed dependencies for this test. We assume the more common
// scenario has no failed tests, so make it the outer loop.
for (std::string const& f : *this->Failed) {
if (cm::contains(this->Properties[test]->RequireSuccessDepends, f)) {
testRun->AddFailedDependency(f);
}
}
if (!this->ResourceAvailabilityErrors[test].empty()) {
std::ostringstream e;
e << "Insufficient resources for test " << this->Properties[test]->Name
<< ":\n\n";
for (auto const& it : this->ResourceAvailabilityErrors[test]) {
switch (it.second) {
case ResourceAvailabilityError::NoResourceType:
e << " Test requested resources of type '" << it.first
<< "' which does not exist\n";
break;
case ResourceAvailabilityError::InsufficientResources:
e << " Test requested resources of type '" << it.first
<< "' in the following amounts:\n";
for (auto const& group : this->Properties[test]->ResourceGroups) {
for (auto const& requirement : group) {
if (requirement.ResourceType == it.first) {
e << " " << requirement.SlotsNeeded
<< (requirement.SlotsNeeded == 1 ? " slot\n" : " slots\n");
}
}
}
e << " but only the following units were available:\n";
for (auto const& res :
this->ResourceAllocator.GetResources().at(it.first)) {
e << " '" << res.first << "': " << res.second.Total
<< (res.second.Total == 1 ? " slot\n" : " slots\n");
}
break;
}
e << "\n";
}
e << "Resource spec file:\n\n " << this->ResourceSpecFile;
cmCTestRunTest::StartFailure(std::move(testRun), this->Total, e.str(),
"Insufficient resources");
return;
}
cmWorkingDirectory workdir(this->Properties[test]->Directory);
if (workdir.Failed()) {
cmCTestRunTest::StartFailure(std::move(testRun), this->Total,
"Failed to change working directory to " +
this->Properties[test]->Directory + " : " +
std::strerror(workdir.GetLastResult()),
"Failed to change working directory");
return;
}
// Ownership of 'testRun' has moved to another structure.
// When the test finishes, FinishTestProcess will be called.
cmCTestRunTest::StartTest(std::move(testRun), this->Completed, this->Total);
}
bool cmCTestMultiProcessHandler::AllocateResources(int index)
{
if (!this->UseResourceSpec) {
return true;
}
// If the test needs unavailable resources then do not allocate anything
// because it will never run. We will issue the recorded errors instead.
if (!this->ResourceAvailabilityErrors[index].empty()) {
return true;
}
std::map<std::string, std::vector<cmCTestBinPackerAllocation>> allocations;
if (!this->TryAllocateResources(index, allocations)) {
return false;
}
auto& allocatedResources = this->AllocatedResources[index];
allocatedResources.resize(this->Properties[index]->ResourceGroups.size());
for (auto const& it : allocations) {
for (auto const& alloc : it.second) {
bool result = this->ResourceAllocator.AllocateResource(
it.first, alloc.Id, alloc.SlotsNeeded);
(void)result;
assert(result);
allocatedResources[alloc.ProcessIndex][it.first].push_back(
{ alloc.Id, static_cast<unsigned int>(alloc.SlotsNeeded) });
}
}
return true;
}
bool cmCTestMultiProcessHandler::TryAllocateResources(
int index,
std::map<std::string, std::vector<cmCTestBinPackerAllocation>>& allocations,
std::map<std::string, ResourceAvailabilityError>* errors)
{
allocations.clear();
std::size_t processIndex = 0;
for (auto const& process : this->Properties[index]->ResourceGroups) {
for (auto const& requirement : process) {
for (int i = 0; i < requirement.UnitsNeeded; ++i) {
allocations[requirement.ResourceType].push_back(
{ processIndex, requirement.SlotsNeeded, "" });
}
}
++processIndex;
}
bool result = true;
auto const& availableResources = this->ResourceAllocator.GetResources();
for (auto& it : allocations) {
if (!availableResources.count(it.first)) {
if (errors) {
(*errors)[it.first] = ResourceAvailabilityError::NoResourceType;
result = false;
} else {
return false;
}
} else if (!cmAllocateCTestResourcesRoundRobin(
availableResources.at(it.first), it.second)) {
if (errors) {
(*errors)[it.first] = ResourceAvailabilityError::InsufficientResources;
result = false;
} else {
return false;
}
}
}
return result;
}
void cmCTestMultiProcessHandler::DeallocateResources(int index)
{
if (!this->UseResourceSpec) {
return;
}
{
auto& allocatedResources = this->AllocatedResources[index];
for (auto const& processAlloc : allocatedResources) {
for (auto const& it : processAlloc) {
auto resourceType = it.first;
for (auto const& it2 : it.second) {
bool success = this->ResourceAllocator.DeallocateResource(
resourceType, it2.Id, it2.Slots);
(void)success;
assert(success);
}
}
}
}
this->AllocatedResources.erase(index);
}
bool cmCTestMultiProcessHandler::AllResourcesAvailable()
{
for (auto const& it : this->ResourceAllocator.GetResources()) {
for (auto const& it2 : it.second) {
if (it2.second.Locked != 0) {
return false;
}
}
}
return true;
}
void cmCTestMultiProcessHandler::CheckResourceAvailability()
{
if (this->UseResourceSpec) {
for (auto const& t : this->PendingTests) {
std::map<std::string, std::vector<cmCTestBinPackerAllocation>>
allocations;
this->TryAllocateResources(t.first, allocations,
&this->ResourceAvailabilityErrors[t.first]);
}
}
}
bool cmCTestMultiProcessHandler::CheckStopOnFailure()
{
return this->CTest->GetStopOnFailure();
}
bool cmCTestMultiProcessHandler::CheckStopTimePassed()
{
if (!this->StopTimePassed) {
std::chrono::system_clock::time_point stop_time =
this->CTest->GetStopTime();
if (stop_time != std::chrono::system_clock::time_point() &&
stop_time <= std::chrono::system_clock::now()) {
this->SetStopTimePassed();
}
}
return this->StopTimePassed;
}
void cmCTestMultiProcessHandler::SetStopTimePassed()
{
if (!this->StopTimePassed) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"The stop time has been passed. "
"Stopping all tests."
<< std::endl);
this->StopTimePassed = true;
}
}
bool cmCTestMultiProcessHandler::ResourceLocksAvailable(int test)
{
return std::all_of(this->Properties[test]->ProjectResources.begin(),
this->Properties[test]->ProjectResources.end(),
[this](std::string const& r) -> bool {
return !cm::contains(this->ProjectResourcesLocked, r);
});
}
void cmCTestMultiProcessHandler::LockResources(int index)
{
this->RunningCount += this->GetProcessorsUsed(index);
auto* properties = this->Properties[index];
this->ProjectResourcesLocked.insert(properties->ProjectResources.begin(),
properties->ProjectResources.end());
if (properties->RunSerial) {
this->SerialTestRunning = true;
}
if (this->HaveAffinity && properties->WantAffinity) {
size_t needProcessors = this->GetProcessorsUsed(index);
assert(needProcessors <= this->ProcessorsAvailable.size());
std::vector<size_t> affinity;
affinity.reserve(needProcessors);
for (size_t i = 0; i < needProcessors; ++i) {
auto p = this->ProcessorsAvailable.begin();
affinity.push_back(*p);
this->ProcessorsAvailable.erase(p);
}
properties->Affinity = std::move(affinity);
}
}
void cmCTestMultiProcessHandler::UnlockResources(int index)
{
auto* properties = this->Properties[index];
for (auto p : properties->Affinity) {
this->ProcessorsAvailable.insert(p);
}
properties->Affinity.clear();
for (std::string const& i : properties->ProjectResources) {
this->ProjectResourcesLocked.erase(i);
}
if (properties->RunSerial) {
this->SerialTestRunning = false;
}
this->RunningCount -= this->GetProcessorsUsed(index);
}
inline size_t cmCTestMultiProcessHandler::GetProcessorsUsed(int test)
{
size_t processors = static_cast<int>(this->Properties[test]->Processors);
size_t const parallelLevel = this->GetParallelLevel();
// If processors setting is set higher than the -j
// setting, we default to using all of the process slots.
if (processors > parallelLevel) {
processors = parallelLevel;
}
// Cap tests that want affinity to the maximum affinity available.
if (this->HaveAffinity && processors > this->HaveAffinity &&
this->Properties[test]->WantAffinity) {
processors = this->HaveAffinity;
}
return processors;
}
std::string cmCTestMultiProcessHandler::GetName(int test)
{
return this->Properties[test]->Name;
}
void cmCTestMultiProcessHandler::StartTest(int test)
{
if (this->JobServerClient) {
// There is a job server. Request a token and queue the test to run
// when a token is received. Note that if we do not get a token right
// away it's possible that the system load will be higher when the
// token is received and we may violate the test-load limit. However,
// this is unlikely because if we do not get a token right away, some
// other job that's currently running must finish before we get one.
this->JobServerClient->RequestToken();
this->JobServerQueuedTests.emplace_back(test);
} else {
// There is no job server. Start the test now.
this->StartTestProcess(test);
}
}
void cmCTestMultiProcessHandler::JobServerReceivedToken()
{
assert(!this->JobServerQueuedTests.empty());
int test = this->JobServerQueuedTests.front();
this->JobServerQueuedTests.pop_front();
this->StartTestProcess(test);
}
void cmCTestMultiProcessHandler::StartNextTests()
{
// One or more events may be scheduled to call this method again.
// Since this method has been called they are no longer needed.
this->StartNextTestsOnIdle_.stop();
this->StartNextTestsOnTimer_.stop();
if (this->PendingTests.empty() || this->CheckStopTimePassed() ||
(this->CheckStopOnFailure() && !this->Failed->empty())) {
return;
}
size_t numToStart = 0;
size_t const parallelLevel = this->GetParallelLevel();
if (this->RunningCount < parallelLevel) {
numToStart = parallelLevel - this->RunningCount;
}
if (numToStart == 0) {
return;
}
// Don't start any new tests if one with the RUN_SERIAL property
// is already running.
if (this->SerialTestRunning) {
return;
}
bool allTestsFailedTestLoadCheck = false;
size_t minProcessorsRequired = this->GetParallelLevel();
std::string testWithMinProcessors;
cmsys::SystemInformation info;
unsigned long systemLoad = 0;
size_t spareLoad = 0;
if (this->TestLoad > 0) {
// Activate possible wait.
allTestsFailedTestLoadCheck = true;
// Check for a fake load average value used in testing.
if (this->FakeLoadForTesting > 0) {
systemLoad = this->FakeLoadForTesting;
// Drop the fake load for the next iteration to a value low enough
// that the next iteration will start tests.
this->FakeLoadForTesting = 1;
}
// If it's not set, look up the true load average.
else {
systemLoad = static_cast<unsigned long>(ceil(info.GetLoadAverage()));
}
spareLoad =
(this->TestLoad > systemLoad ? this->TestLoad - systemLoad : 0);
// Don't start more tests than the spare load can support.
if (numToStart > spareLoad) {
numToStart = spareLoad;
}
}
// Start tests in the preferred order, each subject to readiness checks.
auto ti = this->OrderedTests.begin();
while (numToStart > 0 && !this->SerialTestRunning &&
ti != this->OrderedTests.end()) {
// Increment the test iterator now because the current list
// entry may be deleted below.
auto cti = ti++;
int test = *cti;
// We can only start a RUN_SERIAL test if no other tests are also
// running.
if (this->Properties[test]->RunSerial && this->RunningCount > 0) {
continue;
}
// Exclude tests that depend on unfinished tests.
if (!this->PendingTests[test].Depends.empty()) {
continue;
}
size_t processors = this->GetProcessorsUsed(test);
if (this->TestLoad > 0) {
// Exclude tests that are too big to fit in the spare load.
if (processors > spareLoad) {
// Keep track of the smallest excluded test to report in message below.
if (processors <= minProcessorsRequired) {
minProcessorsRequired = processors;
testWithMinProcessors = this->GetName(test);
}
continue;
}
// We found a test that fits in the spare load.
allTestsFailedTestLoadCheck = false;
cmCTestLog(this->CTest, DEBUG,
"OK to run "
<< this->GetName(test) << ", it requires " << processors
<< " procs & system load is: " << systemLoad << std::endl);
}
// Exclude tests that are too big to fit in the concurrency limit.
if (processors > numToStart) {
continue;
}
// Exclude tests that depend on currently-locked project resources.
if (!this->ResourceLocksAvailable(test)) {
continue;
}
// Allocate system resources needed by this test.
if (!this->AllocateResources(test)) {
continue;
}
// Lock resources needed by this test.
this->LockResources(test);
// The test is ready to run.
numToStart -= processors;
this->OrderedTests.erase(cti);
this->PendingTests.erase(test);
this->StartTest(test);
}
if (allTestsFailedTestLoadCheck) {
// Find out whether there are any non RUN_SERIAL tests left, so that the
// correct warning may be displayed.
bool onlyRunSerialTestsLeft = true;
for (auto const& t : this->PendingTests) {
if (!this->Properties[t.first]->RunSerial) {
onlyRunSerialTestsLeft = false;
}
}
cmCTestLog(this->CTest, HANDLER_VERBOSE_OUTPUT, "***** WAITING, ");
if (this->SerialTestRunning) {
cmCTestLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Waiting for RUN_SERIAL test to finish.");
} else if (onlyRunSerialTestsLeft) {
cmCTestLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Only RUN_SERIAL tests remain, awaiting available slot.");
} else if (!testWithMinProcessors.empty()) {
/* clang-format off */
cmCTestLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"System Load: " << systemLoad << ", "
"Max Allowed Load: " << this->TestLoad << ", "
"Smallest test " << testWithMinProcessors <<
" requires " << minProcessorsRequired);
/* clang-format on */
} else {
/* clang-format off */
cmCTestLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"System Load: " << systemLoad << ", "
"Max Allowed Load: " << this->TestLoad);
/* clang-format on */
}
cmCTestLog(this->CTest, HANDLER_VERBOSE_OUTPUT, "*****" << std::endl);
// Try again later when the load might be lower.
this->StartNextTestsOnTimer();
}
}
void cmCTestMultiProcessHandler::StartNextTestsOnIdle()
{
// Start more tests on the next loop iteration.
this->StartNextTestsOnIdle_.start([](uv_idle_t* idle) {
uv_idle_stop(idle);
auto* self = static_cast<cmCTestMultiProcessHandler*>(idle->data);
self->StartNextTests();
});
}
void cmCTestMultiProcessHandler::StartNextTestsOnTimer()
{
// Wait between 1 and 5 seconds before trying again.
unsigned int const milliseconds = this->FakeLoadForTesting
? 10
: (cmSystemTools::RandomSeed() % 5 + 1) * 1000;
this->StartNextTestsOnTimer_.start(
[](uv_timer_t* timer) {
uv_timer_stop(timer);
auto* self = static_cast<cmCTestMultiProcessHandler*>(timer->data);
self->StartNextTests();
},
milliseconds, 0);
}
void cmCTestMultiProcessHandler::FinishTestProcess(
std::unique_ptr<cmCTestRunTest> runner, bool started)
{
this->Completed++;
int test = runner->GetIndex();
auto* properties = runner->GetTestProperties();
cmCTestRunTest::EndTestResult testResult =
runner->EndTest(this->Completed, this->Total, started);
if (testResult.StopTimePassed) {
this->SetStopTimePassed();
}
if (started) {
if (!this->StopTimePassed &&
cmCTestRunTest::StartAgain(std::move(runner), this->Completed)) {
this->Completed--; // remove the completed test because run again
return;
}
}
if (testResult.Passed) {
this->Passed->push_back(properties->Name);
} else if (!properties->Disabled) {
this->Failed->push_back(properties->Name);
}
for (auto& t : this->PendingTests) {
t.second.Depends.erase(test);
}
this->WriteCheckpoint(test);
this->DeallocateResources(test);
this->UnlockResources(test);
runner.reset();
if (this->JobServerClient) {
this->JobServerClient->ReleaseToken();
}
this->StartNextTestsOnIdle();
}
void cmCTestMultiProcessHandler::UpdateCostData()
{
std::string fname = this->CTest->GetCostDataFile();
std::string tmpout = fname + ".tmp";
cmsys::ofstream fout;
fout.open(tmpout.c_str());
PropertiesMap temp = this->Properties;
if (cmSystemTools::FileExists(fname)) {
cmsys::ifstream fin;
fin.open(fname.c_str());
std::string line;
while (std::getline(fin, line)) {
if (line == "---") {
break;
}
std::vector<std::string> parts = cmSystemTools::SplitString(line, ' ');
// Format: <name> <previous_runs> <avg_cost>
if (parts.size() < 3) {
break;
}
std::string name = parts[0];
int prev = atoi(parts[1].c_str());
float cost = static_cast<float>(atof(parts[2].c_str()));
int index = this->SearchByName(name);
if (index == -1) {
// This test is not in memory. We just rewrite the entry
fout << name << " " << prev << " " << cost << "\n";
} else {
// Update with our new average cost
fout << name << " " << this->Properties[index]->PreviousRuns << " "
<< this->Properties[index]->Cost << "\n";
temp.erase(index);
}
}
fin.close();
cmSystemTools::RemoveFile(fname);
}
// Add all tests not previously listed in the file
for (auto const& i : temp) {
fout << i.second->Name << " " << i.second->PreviousRuns << " "
<< i.second->Cost << "\n";
}
// Write list of failed tests
fout << "---\n";
for (std::string const& f : *this->Failed) {
fout << f << "\n";
}
fout.close();
cmSystemTools::RenameFile(tmpout, fname);
}
void cmCTestMultiProcessHandler::ReadCostData()
{
std::string fname = this->CTest->GetCostDataFile();
if (cmSystemTools::FileExists(fname, true)) {
cmsys::ifstream fin;
fin.open(fname.c_str());
std::string line;
while (std::getline(fin, line)) {
if (line == "---") {
break;
}
std::vector<std::string> parts = cmSystemTools::SplitString(line, ' ');
// Probably an older version of the file, will be fixed next run
if (parts.size() < 3) {
fin.close();
return;
}
std::string name = parts[0];
int prev = atoi(parts[1].c_str());
float cost = static_cast<float>(atof(parts[2].c_str()));
int index = this->SearchByName(name);
if (index == -1) {
continue;
}
this->Properties[index]->PreviousRuns = prev;
// When not running in parallel mode, don't use cost data
if (this->GetParallelLevel() > 1 && this->Properties[index] &&
this->Properties[index]->Cost == 0) {
this->Properties[index]->Cost = cost;
}
}
// Next part of the file is the failed tests
while (std::getline(fin, line)) {
if (!line.empty()) {
this->LastTestsFailed.push_back(line);
}
}
fin.close();
}
}
int cmCTestMultiProcessHandler::SearchByName(std::string const& name)
{
int index = -1;
for (auto const& p : this->Properties) {
if (p.second->Name == name) {
index = p.first;
}
}
return index;
}
void cmCTestMultiProcessHandler::CreateTestCostList()
{
if (this->GetParallelLevel() > 1) {
this->CreateParallelTestCostList();
} else {
this->CreateSerialTestCostList();
}
}
void cmCTestMultiProcessHandler::CreateParallelTestCostList()
{
TestSet alreadyOrderedTests;
std::list<TestSet> priorityStack;
priorityStack.emplace_back();
TestSet& topLevel = priorityStack.back();
// In parallel test runs add previously failed tests to the front
// of the cost list and queue other tests for further sorting
for (auto const& t : this->PendingTests) {
if (cm::contains(this->LastTestsFailed, this->Properties[t.first]->Name)) {
// If the test failed last time, it should be run first.
this->OrderedTests.push_back(t.first);
alreadyOrderedTests.insert(t.first);
} else {
topLevel.insert(t.first);
}
}
// In parallel test runs repeatedly move dependencies of the tests on
// the current dependency level to the next level until no
// further dependencies exist.
while (!priorityStack.back().empty()) {
TestSet& previousSet = priorityStack.back();
priorityStack.emplace_back();
TestSet& currentSet = priorityStack.back();
for (auto const& i : previousSet) {
TestSet const& dependencies = this->PendingTests[i].Depends;
currentSet.insert(dependencies.begin(), dependencies.end());
}
for (auto const& i : currentSet) {
previousSet.erase(i);
}
}
// Remove the empty dependency level
priorityStack.pop_back();
// Reverse iterate over the different dependency levels (deepest first).
// Sort tests within each level by COST and append them to the cost list.
for (TestSet const& currentSet : cmReverseRange(priorityStack)) {
TestList sortedCopy;
cm::append(sortedCopy, currentSet);
std::stable_sort(sortedCopy.begin(), sortedCopy.end(),
TestComparator(this));
for (auto const& j : sortedCopy) {
if (!cm::contains(alreadyOrderedTests, j)) {
this->OrderedTests.push_back(j);
alreadyOrderedTests.insert(j);
}
}
}
}
void cmCTestMultiProcessHandler::GetAllTestDependencies(int test,
TestList& dependencies)
{
TestSet const& dependencySet = this->PendingTests[test].Depends;
for (int i : dependencySet) {
this->GetAllTestDependencies(i, dependencies);
dependencies.push_back(i);
}
}
void cmCTestMultiProcessHandler::CreateSerialTestCostList()
{
TestList presortedList;
for (auto const& i : this->PendingTests) {
presortedList.push_back(i.first);
}
std::stable_sort(presortedList.begin(), presortedList.end(),
TestComparator(this));
TestSet alreadyOrderedTests;
for (int test : presortedList) {
if (cm::contains(alreadyOrderedTests, test)) {
continue;
}
TestList dependencies;
this->GetAllTestDependencies(test, dependencies);
for (int testDependency : dependencies) {
if (!cm::contains(alreadyOrderedTests, testDependency)) {
alreadyOrderedTests.insert(testDependency);
this->OrderedTests.push_back(testDependency);
}
}
alreadyOrderedTests.insert(test);
this->OrderedTests.push_back(test);
}
}
void cmCTestMultiProcessHandler::WriteCheckpoint(int index)
{
std::string fname =
this->CTest->GetBinaryDir() + "/Testing/Temporary/CTestCheckpoint.txt";
cmsys::ofstream fout;
fout.open(fname.c_str(), std::ios::app);
fout << index << "\n";
fout.close();
}
void cmCTestMultiProcessHandler::MarkFinished()
{
std::string fname =
this->CTest->GetBinaryDir() + "/Testing/Temporary/CTestCheckpoint.txt";
cmSystemTools::RemoveFile(fname);
}
static Json::Value DumpToJsonArray(const std::set<std::string>& values)
{
Json::Value jsonArray = Json::arrayValue;
for (const auto& it : values) {
jsonArray.append(it);
}
return jsonArray;
}
static Json::Value DumpToJsonArray(const std::vector<std::string>& values)
{
Json::Value jsonArray = Json::arrayValue;
for (const auto& it : values) {
jsonArray.append(it);
}
return jsonArray;
}
static Json::Value DumpRegExToJsonArray(
const std::vector<std::pair<cmsys::RegularExpression, std::string>>& values)
{
Json::Value jsonArray = Json::arrayValue;
for (const auto& it : values) {
jsonArray.append(it.second);
}
return jsonArray;
}
static Json::Value DumpMeasurementToJsonArray(
const std::map<std::string, std::string>& values)
{
Json::Value jsonArray = Json::arrayValue;
for (const auto& it : values) {
Json::Value measurement = Json::objectValue;
measurement["measurement"] = it.first;
measurement["value"] = it.second;
jsonArray.append(measurement);
}
return jsonArray;
}
static Json::Value DumpTimeoutAfterMatch(
cmCTestTestHandler::cmCTestTestProperties& testProperties)
{
Json::Value timeoutAfterMatch = Json::objectValue;
timeoutAfterMatch["timeout"] = testProperties.AlternateTimeout.count();
timeoutAfterMatch["regex"] =
DumpRegExToJsonArray(testProperties.TimeoutRegularExpressions);
return timeoutAfterMatch;
}
static Json::Value DumpResourceGroupsToJsonArray(
const std::vector<
std::vector<cmCTestTestHandler::cmCTestTestResourceRequirement>>&
resourceGroups)
{
Json::Value jsonResourceGroups = Json::arrayValue;
for (auto const& it : resourceGroups) {
Json::Value jsonResourceGroup = Json::objectValue;
Json::Value requirements = Json::arrayValue;
for (auto const& it2 : it) {
Json::Value res = Json::objectValue;
res[".type"] = it2.ResourceType;
// res[".units"] = it2.UnitsNeeded; // Intentionally commented out
res["slots"] = it2.SlotsNeeded;
requirements.append(res);
}
jsonResourceGroup["requirements"] = requirements;
jsonResourceGroups.append(jsonResourceGroup);
}
return jsonResourceGroups;
}
static Json::Value DumpCTestProperty(std::string const& name,
Json::Value value)
{
Json::Value property = Json::objectValue;
property["name"] = name;
property["value"] = std::move(value);
return property;
}
static Json::Value DumpCTestProperties(
cmCTestTestHandler::cmCTestTestProperties& testProperties)
{
Json::Value properties = Json::arrayValue;
if (!testProperties.AttachOnFail.empty()) {
properties.append(DumpCTestProperty(
"ATTACHED_FILES_ON_FAIL", DumpToJsonArray(testProperties.AttachOnFail)));
}
if (!testProperties.AttachedFiles.empty()) {
properties.append(DumpCTestProperty(
"ATTACHED_FILES", DumpToJsonArray(testProperties.AttachedFiles)));
}
if (testProperties.Cost != 0.0f) {
properties.append(
DumpCTestProperty("COST", static_cast<double>(testProperties.Cost)));
}
if (!testProperties.Depends.empty()) {
properties.append(
DumpCTestProperty("DEPENDS", DumpToJsonArray(testProperties.Depends)));
}
if (testProperties.Disabled) {
properties.append(DumpCTestProperty("DISABLED", testProperties.Disabled));
}
if (!testProperties.Environment.empty()) {
properties.append(DumpCTestProperty(
"ENVIRONMENT", DumpToJsonArray(testProperties.Environment)));
}
if (!testProperties.EnvironmentModification.empty()) {
properties.append(DumpCTestProperty(
"ENVIRONMENT_MODIFICATION",
DumpToJsonArray(testProperties.EnvironmentModification)));
}
if (!testProperties.ErrorRegularExpressions.empty()) {
properties.append(DumpCTestProperty(
"FAIL_REGULAR_EXPRESSION",
DumpRegExToJsonArray(testProperties.ErrorRegularExpressions)));
}
if (!testProperties.SkipRegularExpressions.empty()) {
properties.append(DumpCTestProperty(
"SKIP_REGULAR_EXPRESSION",
DumpRegExToJsonArray(testProperties.SkipRegularExpressions)));
}
if (!testProperties.FixturesCleanup.empty()) {
properties.append(DumpCTestProperty(
"FIXTURES_CLEANUP", DumpToJsonArray(testProperties.FixturesCleanup)));
}
if (!testProperties.FixturesRequired.empty()) {
properties.append(DumpCTestProperty(
"FIXTURES_REQUIRED", DumpToJsonArray(testProperties.FixturesRequired)));
}
if (!testProperties.FixturesSetup.empty()) {
properties.append(DumpCTestProperty(
"FIXTURES_SETUP", DumpToJsonArray(testProperties.FixturesSetup)));
}
if (!testProperties.Labels.empty()) {
properties.append(
DumpCTestProperty("LABELS", DumpToJsonArray(testProperties.Labels)));
}
if (!testProperties.Measurements.empty()) {
properties.append(DumpCTestProperty(
"MEASUREMENT", DumpMeasurementToJsonArray(testProperties.Measurements)));
}
if (!testProperties.RequiredRegularExpressions.empty()) {
properties.append(DumpCTestProperty(
"PASS_REGULAR_EXPRESSION",
DumpRegExToJsonArray(testProperties.RequiredRegularExpressions)));
}
if (!testProperties.ResourceGroups.empty()) {
properties.append(DumpCTestProperty(
"RESOURCE_GROUPS",
DumpResourceGroupsToJsonArray(testProperties.ResourceGroups)));
}
if (testProperties.WantAffinity) {
properties.append(
DumpCTestProperty("PROCESSOR_AFFINITY", testProperties.WantAffinity));
}
if (testProperties.Processors != 1) {
properties.append(
DumpCTestProperty("PROCESSORS", testProperties.Processors));
}
if (!testProperties.RequiredFiles.empty()) {
properties.append(DumpCTestProperty(
"REQUIRED_FILES", DumpToJsonArray(testProperties.RequiredFiles)));
}
if (!testProperties.ProjectResources.empty()) {
properties.append(DumpCTestProperty(
"RESOURCE_LOCK", DumpToJsonArray(testProperties.ProjectResources)));
}
if (testProperties.RunSerial) {
properties.append(
DumpCTestProperty("RUN_SERIAL", testProperties.RunSerial));
}
if (testProperties.SkipReturnCode != -1) {
properties.append(
DumpCTestProperty("SKIP_RETURN_CODE", testProperties.SkipReturnCode));
}
if (testProperties.Timeout) {
properties.append(
DumpCTestProperty("TIMEOUT", testProperties.Timeout->count()));
}
if (!testProperties.TimeoutRegularExpressions.empty()) {
properties.append(DumpCTestProperty(
"TIMEOUT_AFTER_MATCH", DumpTimeoutAfterMatch(testProperties)));
}
if (testProperties.WillFail) {
properties.append(DumpCTestProperty("WILL_FAIL", testProperties.WillFail));
}
if (!testProperties.Directory.empty()) {
properties.append(
DumpCTestProperty("WORKING_DIRECTORY", testProperties.Directory));
}
if (!testProperties.CustomProperties.empty()) {
for (auto const& it : testProperties.CustomProperties) {
properties.append(DumpCTestProperty(it.first, it.second));
}
}
return properties;
}
class BacktraceData
{
std::unordered_map<std::string, Json::ArrayIndex> CommandMap;
std::unordered_map<std::string, Json::ArrayIndex> FileMap;
std::unordered_map<cmListFileContext const*, Json::ArrayIndex> NodeMap;
Json::Value Commands = Json::arrayValue;
Json::Value Files = Json::arrayValue;
Json::Value Nodes = Json::arrayValue;
Json::ArrayIndex AddCommand(std::string const& command)
{
auto i = this->CommandMap.find(command);
if (i == this->CommandMap.end()) {
i = this->CommandMap.emplace(command, this->Commands.size()).first;
this->Commands.append(command);
}
return i->second;
}
Json::ArrayIndex AddFile(std::string const& file)
{
auto i = this->FileMap.find(file);
if (i == this->FileMap.end()) {
i = this->FileMap.emplace(file, this->Files.size()).first;
this->Files.append(file);
}
return i->second;
}
public:
bool Add(cmListFileBacktrace const& bt, Json::ArrayIndex& index);
Json::Value Dump();
};
bool BacktraceData::Add(cmListFileBacktrace const& bt, Json::ArrayIndex& index)
{
if (bt.Empty()) {
return false;
}
cmListFileContext const* top = &bt.Top();
auto found = this->NodeMap.find(top);
if (found != this->NodeMap.end()) {
index = found->second;
return true;
}
Json::Value entry = Json::objectValue;
entry["file"] = this->AddFile(top->FilePath);
if (top->Line) {
entry["line"] = static_cast<int>(top->Line);
}
if (!top->Name.empty()) {
entry["command"] = this->AddCommand(top->Name);
}
Json::ArrayIndex parent;
if (this->Add(bt.Pop(), parent)) {
entry["parent"] = parent;
}
index = this->NodeMap[top] = this->Nodes.size();
this->Nodes.append(std::move(entry)); // NOLINT(*)
return true;
}
Json::Value BacktraceData::Dump()
{
Json::Value backtraceGraph;
this->CommandMap.clear();
this->FileMap.clear();
this->NodeMap.clear();
backtraceGraph["commands"] = std::move(this->Commands);
backtraceGraph["files"] = std::move(this->Files);
backtraceGraph["nodes"] = std::move(this->Nodes);
return backtraceGraph;
}
static void AddBacktrace(BacktraceData& backtraceGraph, Json::Value& object,
cmListFileBacktrace const& bt)
{
Json::ArrayIndex backtrace;
if (backtraceGraph.Add(bt, backtrace)) {
object["backtrace"] = backtrace;
}
}
static Json::Value DumpCTestInfo(
cmCTestRunTest& testRun,
cmCTestTestHandler::cmCTestTestProperties& testProperties,
BacktraceData& backtraceGraph)
{
Json::Value testInfo = Json::objectValue;
// test name should always be present
testInfo["name"] = testProperties.Name;
std::string const& config = testRun.GetCTest()->GetConfigType();
if (!config.empty()) {
testInfo["config"] = config;
}
std::string const& command = testRun.GetActualCommand();
if (!command.empty()) {
std::vector<std::string> commandAndArgs;
commandAndArgs.push_back(command);
const std::vector<std::string>& args = testRun.GetArguments();
if (!args.empty()) {
commandAndArgs.reserve(args.size() + 1);
cm::append(commandAndArgs, args);
}
testInfo["command"] = DumpToJsonArray(commandAndArgs);
}
Json::Value properties = DumpCTestProperties(testProperties);
if (!properties.empty()) {
testInfo["properties"] = properties;
}
if (!testProperties.Backtrace.Empty()) {
AddBacktrace(backtraceGraph, testInfo, testProperties.Backtrace);
}
return testInfo;
}
static Json::Value DumpVersion(int major, int minor)
{
Json::Value version = Json::objectValue;
version["major"] = major;
version["minor"] = minor;
return version;
}
void cmCTestMultiProcessHandler::PrintOutputAsJson()
{
this->TestHandler->SetMaxIndex(this->FindMaxIndex());
Json::Value result = Json::objectValue;
result["kind"] = "ctestInfo";
result["version"] = DumpVersion(1, 0);
BacktraceData backtraceGraph;
Json::Value tests = Json::arrayValue;
for (auto& it : this->Properties) {
cmCTestTestHandler::cmCTestTestProperties& p = *it.second;
// Don't worry if this fails, we are only showing the test list, not
// running the tests
cmWorkingDirectory workdir(p.Directory);
cmCTestRunTest testRun(*this, p.Index);
testRun.ComputeArguments();
// Skip tests not available in this configuration.
if (p.Args.size() >= 2 && p.Args[1] == "NOT_AVAILABLE") {
continue;
}
Json::Value testInfo = DumpCTestInfo(testRun, p, backtraceGraph);
tests.append(testInfo);
}
result["backtraceGraph"] = backtraceGraph.Dump();
result["tests"] = std::move(tests);
Json::StreamWriterBuilder builder;
builder["indentation"] = " ";
std::unique_ptr<Json::StreamWriter> jout(builder.newStreamWriter());
jout->write(result, &std::cout);
}
// For ShowOnly mode
void cmCTestMultiProcessHandler::PrintTestList()
{
if (this->CTest->GetOutputAsJson()) {
this->PrintOutputAsJson();
return;
}
this->TestHandler->SetMaxIndex(this->FindMaxIndex());
for (auto& it : this->Properties) {
cmCTestTestHandler::cmCTestTestProperties& p = *it.second;
// Don't worry if this fails, we are only showing the test list, not
// running the tests
cmWorkingDirectory workdir(p.Directory);
cmCTestRunTest testRun(*this, p.Index);
testRun.ComputeArguments(); // logs the command in verbose mode
if (!p.Labels.empty()) // print the labels
{
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Labels:", this->Quiet);
}
for (std::string const& label : p.Labels) {
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT, " " << label,
this->Quiet);
}
if (!p.Labels.empty()) // print the labels
{
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT, std::endl,
this->Quiet);
}
if (this->TestHandler->MemCheck) {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, " Memory Check",
this->Quiet);
} else {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, " Test", this->Quiet);
}
std::ostringstream indexStr;
indexStr << " #" << p.Index << ":";
cmCTestOptionalLog(
this->CTest, HANDLER_OUTPUT,
std::setw(3 + getNumWidth(this->TestHandler->GetMaxIndex()))
<< indexStr.str(),
this->Quiet);
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, " " << p.Name,
this->Quiet);
if (p.Disabled) {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, " (Disabled)",
this->Quiet);
}
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, std::endl, this->Quiet);
}
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
std::endl
<< "Total Tests: " << this->Total << std::endl,
this->Quiet);
}
void cmCTestMultiProcessHandler::PrintLabels()
{
std::set<std::string> allLabels;
for (auto& it : this->Properties) {
cmCTestTestHandler::cmCTestTestProperties& p = *it.second;
allLabels.insert(p.Labels.begin(), p.Labels.end());
}
if (!allLabels.empty()) {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, "All Labels:" << std::endl,
this->Quiet);
} else {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT,
"No Labels Exist" << std::endl, this->Quiet);
}
for (std::string const& label : allLabels) {
cmCTestOptionalLog(this->CTest, HANDLER_OUTPUT, " " << label << std::endl,
this->Quiet);
}
}
void cmCTestMultiProcessHandler::CheckResume()
{
std::string fname =
this->CTest->GetBinaryDir() + "/Testing/Temporary/CTestCheckpoint.txt";
if (this->CTest->GetFailover()) {
if (cmSystemTools::FileExists(fname, true)) {
*this->TestHandler->LogFile
<< "Resuming previously interrupted test set" << std::endl
<< "----------------------------------------------------------"
<< std::endl;
cmsys::ifstream fin;
fin.open(fname.c_str());
std::string line;
while (std::getline(fin, line)) {
int index = atoi(line.c_str());
this->RemoveTest(index);
}
fin.close();
}
} else if (cmSystemTools::FileExists(fname, true)) {
cmSystemTools::RemoveFile(fname);
}
}
void cmCTestMultiProcessHandler::RemoveTest(int index)
{
this->OrderedTests.erase(
std::find(this->OrderedTests.begin(), this->OrderedTests.end(), index));
this->PendingTests.erase(index);
this->Properties.erase(index);
this->Completed++;
}
int cmCTestMultiProcessHandler::FindMaxIndex()
{
int max = 0;
for (auto const& i : this->PendingTests) {
if (i.first > max) {
max = i.first;
}
}
return max;
}
// Returns true if no cycles exist in the dependency graph
bool cmCTestMultiProcessHandler::CheckCycles()
{
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Checking test dependency graph..." << std::endl,
this->Quiet);
for (auto const& it : this->PendingTests) {
// DFS from each element to itself
int root = it.first;
std::set<int> visited;
std::stack<int> s;
s.push(root);
while (!s.empty()) {
int test = s.top();
s.pop();
if (visited.insert(test).second) {
for (auto const& d : this->PendingTests[test].Depends) {
if (d == root) {
// cycle exists
cmCTestLog(
this->CTest, ERROR_MESSAGE,
"Error: a cycle exists in the test dependency graph "
"for the test \""
<< this->Properties[root]->Name
<< "\".\nPlease fix the cycle and run ctest again.\n");
return false;
}
s.push(d);
}
}
}
}
cmCTestOptionalLog(this->CTest, HANDLER_VERBOSE_OUTPUT,
"Checking test dependency graph end" << std::endl,
this->Quiet);
return true;
}
bool cmCTestMultiProcessHandler::CheckGeneratedResourceSpec()
{
for (auto& test : this->Properties) {
if (!test.second->GeneratedResourceSpecFile.empty()) {
if (this->ResourceSpecSetupTest) {
cmCTestLog(
this->CTest, ERROR_MESSAGE,
"Only one test may define the GENERATED_RESOURCE_SPEC_FILE property"
<< std::endl);
return false;
}
if (test.second->FixturesSetup.size() != 1) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"Test that defines GENERATED_RESOURCE_SPEC_FILE must have "
"exactly one FIXTURES_SETUP"
<< std::endl);
return false;
}
if (!cmSystemTools::FileIsFullPath(
test.second->GeneratedResourceSpecFile)) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"GENERATED_RESOURCE_SPEC_FILE must be an absolute path"
<< std::endl);
return false;
}
this->ResourceSpecSetupTest = test.first;
this->ResourceSpecSetupFixture = *test.second->FixturesSetup.begin();
}
}
if (!this->ResourceSpecSetupFixture.empty()) {
for (auto& test : this->Properties) {
if (!test.second->ResourceGroups.empty() &&
!test.second->FixturesRequired.count(
this->ResourceSpecSetupFixture)) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"All tests that have RESOURCE_GROUPS must include the "
"resource spec generator fixture in their FIXTURES_REQUIRED"
<< std::endl);
return false;
}
}
}
if (!this->ResourceSpecFile.empty()) {
if (this->ResourceSpecSetupTest) {
cmCTestLog(this->CTest, ERROR_MESSAGE,
"GENERATED_RESOURCE_SPEC_FILE test property cannot be used "
"in conjunction with ResourceSpecFile option"
<< std::endl);
return false;
}
std::string error;
if (!this->InitResourceAllocator(error)) {
cmCTestLog(this->CTest, ERROR_MESSAGE, error << std::endl);
return false;
}
}
return true;
}
bool cmCTestMultiProcessHandler::InitResourceAllocator(std::string& error)
{
if (!this->ResourceSpec.ReadFromJSONFile(this->ResourceSpecFile)) {
error = cmStrCat("Could not read/parse resource spec file ",
this->ResourceSpecFile, ": ",
this->ResourceSpec.parseState.GetErrorMessage());
return false;
}
this->UseResourceSpec = true;
this->ResourceAllocator.InitializeFromResourceSpec(this->ResourceSpec);
return true;
}