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llvm-mirror/unittests/XRay/FDRTraceWriterTest.cpp
Dean Michael Berris 501327fe86 [XRay] Add TSC to NewCPUId Records
Summary:
This more correctly reflects the data written by the FDR mode runtime.

This is a continuation of the work in D50441.

Reviewers: mboerger, eizan

Subscribers: hiraditya, llvm-commits

Differential Revision: https://reviews.llvm.org/D51911

llvm-svn: 341905
2018-09-11 06:36:51 +00:00

184 lines
6.6 KiB
C++

//===- llvm/unittest/XRay/FDRTraceWriterTest.cpp ----------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Test a utility that can write out XRay FDR Mode formatted trace files.
//
//===----------------------------------------------------------------------===//
#include "llvm/XRay/FDRTraceWriter.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/XRay/FDRLogBuilder.h"
#include "llvm/XRay/FDRRecords.h"
#include "llvm/XRay/Trace.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include <string>
namespace llvm {
namespace xray {
namespace {
using testing::ElementsAre;
using testing::Eq;
using testing::Field;
using testing::IsEmpty;
using testing::Not;
// We want to be able to create an instance of an FDRTraceWriter and associate
// it with a stream, which could be loaded and turned into a Trace instance.
// This test writes out version 3 trace logs.
TEST(FDRTraceWriterTest, WriteToStringBufferVersion3) {
std::string Data;
raw_string_ostream OS(Data);
XRayFileHeader H;
H.Version = 3;
H.Type = 1;
H.ConstantTSC = true;
H.NonstopTSC = true;
H.CycleFrequency = 3e9;
FDRTraceWriter Writer(OS, H);
auto L = LogBuilder()
.add<BufferExtents>(80)
.add<NewBufferRecord>(1)
.add<WallclockRecord>(1, 1)
.add<PIDRecord>(1)
.add<NewCPUIDRecord>(1, 2)
.add<FunctionRecord>(RecordTypes::ENTER, 1, 1)
.add<FunctionRecord>(RecordTypes::EXIT, 1, 100)
.consume();
for (auto &P : L)
ASSERT_FALSE(errorToBool(P->apply(Writer)));
OS.flush();
// Then from here we load the Trace file.
DataExtractor DE(Data, sys::IsLittleEndianHost, 8);
auto TraceOrErr = loadTrace(DE, true);
if (!TraceOrErr)
FAIL() << TraceOrErr.takeError();
auto &Trace = TraceOrErr.get();
ASSERT_THAT(Trace, Not(IsEmpty()));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::FuncId, Eq(1)),
Field(&XRayRecord::FuncId, Eq(1))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::TId, Eq(1u)),
Field(&XRayRecord::TId, Eq(1u))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::PId, Eq(1u)),
Field(&XRayRecord::PId, Eq(1u))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::CPU, Eq(1u)),
Field(&XRayRecord::CPU, Eq(1u))));
EXPECT_THAT(Trace,
ElementsAre(Field(&XRayRecord::Type, Eq(RecordTypes::ENTER)),
Field(&XRayRecord::Type, Eq(RecordTypes::EXIT))));
}
// This version is almost exactly the same as above, except writing version 2
// logs, without the PID records.
TEST(FDRTraceWriterTest, WriteToStringBufferVersion2) {
std::string Data;
raw_string_ostream OS(Data);
XRayFileHeader H;
H.Version = 2;
H.Type = 1;
H.ConstantTSC = true;
H.NonstopTSC = true;
H.CycleFrequency = 3e9;
FDRTraceWriter Writer(OS, H);
auto L = LogBuilder()
.add<BufferExtents>(64)
.add<NewBufferRecord>(1)
.add<WallclockRecord>(1, 1)
.add<NewCPUIDRecord>(1, 2)
.add<FunctionRecord>(RecordTypes::ENTER, 1, 1)
.add<FunctionRecord>(RecordTypes::EXIT, 1, 100)
.consume();
for (auto &P : L)
ASSERT_FALSE(errorToBool(P->apply(Writer)));
OS.flush();
// Then from here we load the Trace file.
DataExtractor DE(Data, sys::IsLittleEndianHost, 8);
auto TraceOrErr = loadTrace(DE, true);
if (!TraceOrErr)
FAIL() << TraceOrErr.takeError();
auto &Trace = TraceOrErr.get();
ASSERT_THAT(Trace, Not(IsEmpty()));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::FuncId, Eq(1)),
Field(&XRayRecord::FuncId, Eq(1))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::TId, Eq(1u)),
Field(&XRayRecord::TId, Eq(1u))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::CPU, Eq(1u)),
Field(&XRayRecord::CPU, Eq(1u))));
EXPECT_THAT(Trace,
ElementsAre(Field(&XRayRecord::Type, Eq(RecordTypes::ENTER)),
Field(&XRayRecord::Type, Eq(RecordTypes::EXIT))));
}
// This covers version 1 of the log, without a BufferExtents record but has an
// explicit EndOfBuffer record.
TEST(FDRTraceWriterTest, WriteToStringBufferVersion1) {
std::string Data;
raw_string_ostream OS(Data);
XRayFileHeader H;
H.Version = 1;
H.Type = 1;
H.ConstantTSC = true;
H.NonstopTSC = true;
H.CycleFrequency = 3e9;
// Write the size of buffers out, arbitrarily it's 4k.
constexpr uint64_t BufferSize = 4096;
std::memcpy(H.FreeFormData, reinterpret_cast<const char *>(&BufferSize),
sizeof(BufferSize));
FDRTraceWriter Writer(OS, H);
OS.flush();
// Ensure that at this point the Data buffer has the file header serialized
// size.
ASSERT_THAT(Data.size(), Eq(32u));
auto L = LogBuilder()
.add<NewBufferRecord>(1)
.add<WallclockRecord>(1, 1)
.add<NewCPUIDRecord>(1, 2)
.add<FunctionRecord>(RecordTypes::ENTER, 1, 1)
.add<FunctionRecord>(RecordTypes::EXIT, 1, 100)
.add<EndBufferRecord>()
.consume();
for (auto &P : L)
ASSERT_FALSE(errorToBool(P->apply(Writer)));
// We need to pad the buffer with 4016 (4096 - 80) bytes of zeros.
OS.write_zeros(4016);
OS.flush();
// For version 1 of the log, we need the whole buffer to be the size of the
// file header plus 32.
ASSERT_THAT(Data.size(), Eq(BufferSize + 32));
// Then from here we load the Trace file.
DataExtractor DE(Data, sys::IsLittleEndianHost, 8);
auto TraceOrErr = loadTrace(DE, true);
if (!TraceOrErr)
FAIL() << TraceOrErr.takeError();
auto &Trace = TraceOrErr.get();
ASSERT_THAT(Trace, Not(IsEmpty()));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::FuncId, Eq(1)),
Field(&XRayRecord::FuncId, Eq(1))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::TId, Eq(1u)),
Field(&XRayRecord::TId, Eq(1u))));
EXPECT_THAT(Trace, ElementsAre(Field(&XRayRecord::CPU, Eq(1u)),
Field(&XRayRecord::CPU, Eq(1u))));
EXPECT_THAT(Trace,
ElementsAre(Field(&XRayRecord::Type, Eq(RecordTypes::ENTER)),
Field(&XRayRecord::Type, Eq(RecordTypes::EXIT))));
}
} // namespace
} // namespace xray
} // namespace llvm