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llvm-mirror/unittests/DebugInfo/MSF/MSFBuilderTest.cpp
Zachary Turner 896c0d9299 Move some code from PDBFileBuilder to MSFBuilder.
The code to emit the pieces of the MSF file were actually in
PDBFileBuilder.  Move this to MSFBuilder so that we can
theoretically emit an MSF without having a PDB file.

llvm-svn: 335789
2018-06-27 21:18:15 +00:00

397 lines
14 KiB
C++

//===- MSFBuilderTest.cpp Tests manipulation of MSF stream metadata ------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/DebugInfo/MSF/MSFBuilder.h"
#include "llvm/DebugInfo/MSF/MSFCommon.h"
#include "llvm/Testing/Support/Error.h"
#include "gmock/gmock-matchers.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
using namespace llvm;
using namespace llvm::msf;
using namespace testing;
namespace {
class MSFBuilderTest : public testing::Test {
protected:
void initializeSimpleSuperBlock(msf::SuperBlock &SB) {
initializeSuperBlock(SB);
SB.NumBlocks = 1000;
SB.NumDirectoryBytes = 8192;
}
void initializeSuperBlock(msf::SuperBlock &SB) {
::memset(&SB, 0, sizeof(SB));
::memcpy(SB.MagicBytes, msf::Magic, sizeof(msf::Magic));
SB.FreeBlockMapBlock = 1;
SB.BlockMapAddr = 1;
SB.BlockSize = 4096;
SB.NumDirectoryBytes = 0;
SB.NumBlocks = 2; // one for the Super Block, one for the directory
}
BumpPtrAllocator Allocator;
};
} // namespace
TEST_F(MSFBuilderTest, ValidateSuperBlockAccept) {
// Test that a known good super block passes validation.
SuperBlock SB;
initializeSuperBlock(SB);
EXPECT_THAT_ERROR(msf::validateSuperBlock(SB), Succeeded());
}
TEST_F(MSFBuilderTest, ValidateSuperBlockReject) {
// Test that various known problems cause a super block to be rejected.
SuperBlock SB;
initializeSimpleSuperBlock(SB);
// Mismatched magic
SB.MagicBytes[0] = 8;
EXPECT_THAT_ERROR(msf::validateSuperBlock(SB), Failed());
initializeSimpleSuperBlock(SB);
// Block 0 is reserved for super block, can't be occupied by the block map
SB.BlockMapAddr = 0;
EXPECT_THAT_ERROR(msf::validateSuperBlock(SB), Failed());
initializeSimpleSuperBlock(SB);
// Block sizes have to be powers of 2.
SB.BlockSize = 3120;
EXPECT_THAT_ERROR(msf::validateSuperBlock(SB), Failed());
initializeSimpleSuperBlock(SB);
// The directory itself has a maximum size.
SB.NumDirectoryBytes = SB.BlockSize * SB.BlockSize / 4;
EXPECT_THAT_ERROR(msf::validateSuperBlock(SB), Succeeded());
SB.NumDirectoryBytes = SB.NumDirectoryBytes + 4;
EXPECT_THAT_ERROR(msf::validateSuperBlock(SB), Failed());
}
TEST_F(MSFBuilderTest, TestUsedBlocksMarkedAsUsed) {
// Test that when assigning a stream to a known list of blocks, the blocks
// are correctly marked as used after adding, but no other incorrect blocks
// are accidentally marked as used.
std::vector<uint32_t> Blocks = {4, 5, 6, 7, 8, 9, 10, 11, 12};
// Allocate some extra blocks at the end so we can verify that they're free
// after the initialization.
uint32_t NumBlocks = msf::getMinimumBlockCount() + Blocks.size() + 10;
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096, NumBlocks);
ASSERT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(Blocks.size() * 4096, Blocks),
Succeeded());
for (auto B : Blocks) {
EXPECT_FALSE(Msf.isBlockFree(B));
}
uint32_t FreeBlockStart = Blocks.back() + 1;
for (uint32_t I = FreeBlockStart; I < NumBlocks; ++I) {
EXPECT_TRUE(Msf.isBlockFree(I));
}
}
TEST_F(MSFBuilderTest, TestAddStreamNoDirectoryBlockIncrease) {
// Test that adding a new stream correctly updates the directory. This only
// tests the case where the directory *DOES NOT* grow large enough that it
// crosses a Block boundary.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
auto ExpectedL1 = Msf.generateLayout();
EXPECT_THAT_EXPECTED(ExpectedL1, Succeeded());
MSFLayout &L1 = *ExpectedL1;
auto OldDirBlocks = L1.DirectoryBlocks;
EXPECT_EQ(1U, OldDirBlocks.size());
auto ExpectedMsf2 = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf2, Succeeded());
auto &Msf2 = *ExpectedMsf2;
EXPECT_THAT_EXPECTED(Msf2.addStream(4000), Succeeded());
EXPECT_EQ(1U, Msf2.getNumStreams());
EXPECT_EQ(4000U, Msf2.getStreamSize(0));
auto Blocks = Msf2.getStreamBlocks(0);
EXPECT_EQ(1U, Blocks.size());
auto ExpectedL2 = Msf2.generateLayout();
EXPECT_THAT_EXPECTED(ExpectedL2, Succeeded());
MSFLayout &L2 = *ExpectedL2;
auto NewDirBlocks = L2.DirectoryBlocks;
EXPECT_EQ(1U, NewDirBlocks.size());
}
TEST_F(MSFBuilderTest, TestAddStreamWithDirectoryBlockIncrease) {
// Test that adding a new stream correctly updates the directory. This only
// tests the case where the directory *DOES* grow large enough that it
// crosses a Block boundary. This is because the newly added stream occupies
// so many Blocks that need to be indexed in the directory that the directory
// crosses a Block boundary.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(4096 * 4096 / sizeof(uint32_t)),
Succeeded());
auto ExpectedL1 = Msf.generateLayout();
EXPECT_THAT_EXPECTED(ExpectedL1, Succeeded());
MSFLayout &L1 = *ExpectedL1;
auto DirBlocks = L1.DirectoryBlocks;
EXPECT_EQ(2U, DirBlocks.size());
}
TEST_F(MSFBuilderTest, TestGrowStreamNoBlockIncrease) {
// Test growing an existing stream by a value that does not affect the number
// of blocks it occupies.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(1024), Succeeded());
EXPECT_EQ(1024U, Msf.getStreamSize(0));
auto OldStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(1U, OldStreamBlocks.size());
EXPECT_THAT_ERROR(Msf.setStreamSize(0, 2048), Succeeded());
EXPECT_EQ(2048U, Msf.getStreamSize(0));
auto NewStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(1U, NewStreamBlocks.size());
EXPECT_EQ(OldStreamBlocks, NewStreamBlocks);
}
TEST_F(MSFBuilderTest, TestGrowStreamWithBlockIncrease) {
// Test that growing an existing stream to a value large enough that it causes
// the need to allocate new Blocks to the stream correctly updates the
// stream's
// block list.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(2048), Succeeded());
EXPECT_EQ(2048U, Msf.getStreamSize(0));
std::vector<uint32_t> OldStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(1U, OldStreamBlocks.size());
EXPECT_THAT_ERROR(Msf.setStreamSize(0, 6144), Succeeded());
EXPECT_EQ(6144U, Msf.getStreamSize(0));
std::vector<uint32_t> NewStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(2U, NewStreamBlocks.size());
EXPECT_EQ(OldStreamBlocks[0], NewStreamBlocks[0]);
EXPECT_NE(NewStreamBlocks[0], NewStreamBlocks[1]);
}
TEST_F(MSFBuilderTest, TestShrinkStreamNoBlockDecrease) {
// Test that shrinking an existing stream by a value that does not affect the
// number of Blocks it occupies makes no changes to stream's block list.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(2048), Succeeded());
EXPECT_EQ(2048U, Msf.getStreamSize(0));
std::vector<uint32_t> OldStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(1U, OldStreamBlocks.size());
EXPECT_THAT_ERROR(Msf.setStreamSize(0, 1024), Succeeded());
EXPECT_EQ(1024U, Msf.getStreamSize(0));
std::vector<uint32_t> NewStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(1U, NewStreamBlocks.size());
EXPECT_EQ(OldStreamBlocks, NewStreamBlocks);
}
TEST_F(MSFBuilderTest, TestShrinkStreamWithBlockDecrease) {
// Test that shrinking an existing stream to a value large enough that it
// causes the need to deallocate new Blocks to the stream correctly updates
// the stream's block list.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(6144), Succeeded());
EXPECT_EQ(6144U, Msf.getStreamSize(0));
std::vector<uint32_t> OldStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(2U, OldStreamBlocks.size());
EXPECT_THAT_ERROR(Msf.setStreamSize(0, 2048), Succeeded());
EXPECT_EQ(2048U, Msf.getStreamSize(0));
std::vector<uint32_t> NewStreamBlocks = Msf.getStreamBlocks(0);
EXPECT_EQ(1U, NewStreamBlocks.size());
EXPECT_EQ(OldStreamBlocks[0], NewStreamBlocks[0]);
}
TEST_F(MSFBuilderTest, TestRejectReusedStreamBlock) {
// Test that attempting to add a stream and assigning a block that is already
// in use by another stream fails.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
EXPECT_THAT_EXPECTED(Msf.addStream(6144), Succeeded());
std::vector<uint32_t> Blocks = {2, 3};
EXPECT_THAT_EXPECTED(Msf.addStream(6144, Blocks), Failed());
}
TEST_F(MSFBuilderTest, TestBlockCountsWhenAddingStreams) {
// Test that when adding multiple streams, the number of used and free Blocks
// allocated to the MSF file are as expected.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
// one for the super block, one for the directory block map
uint32_t NumUsedBlocks = Msf.getNumUsedBlocks();
EXPECT_EQ(msf::getMinimumBlockCount(), NumUsedBlocks);
EXPECT_EQ(0U, Msf.getNumFreeBlocks());
const uint32_t StreamSizes[] = {4000, 6193, 189723};
for (int I = 0; I < 3; ++I) {
EXPECT_THAT_EXPECTED(Msf.addStream(StreamSizes[I]), Succeeded());
NumUsedBlocks += bytesToBlocks(StreamSizes[I], 4096);
EXPECT_EQ(NumUsedBlocks, Msf.getNumUsedBlocks());
EXPECT_EQ(0U, Msf.getNumFreeBlocks());
}
}
TEST_F(MSFBuilderTest, BuildMsfLayout) {
// Test that we can generate an MSFLayout structure from a valid layout
// specification.
auto ExpectedMsf = MSFBuilder::create(Allocator, 4096);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
const uint32_t StreamSizes[] = {4000, 6193, 189723};
uint32_t ExpectedNumBlocks = msf::getMinimumBlockCount();
for (int I = 0; I < 3; ++I) {
EXPECT_THAT_EXPECTED(Msf.addStream(StreamSizes[I]), Succeeded());
ExpectedNumBlocks += bytesToBlocks(StreamSizes[I], 4096);
}
++ExpectedNumBlocks; // The directory itself should use 1 block
auto ExpectedLayout = Msf.generateLayout();
EXPECT_THAT_EXPECTED(ExpectedLayout, Succeeded());
MSFLayout &L = *ExpectedLayout;
EXPECT_EQ(4096U, L.SB->BlockSize);
EXPECT_EQ(ExpectedNumBlocks, L.SB->NumBlocks);
EXPECT_EQ(1U, L.DirectoryBlocks.size());
EXPECT_EQ(3U, L.StreamMap.size());
EXPECT_EQ(3U, L.StreamSizes.size());
for (int I = 0; I < 3; ++I) {
EXPECT_EQ(StreamSizes[I], L.StreamSizes[I]);
uint32_t ExpectedNumBlocks = bytesToBlocks(StreamSizes[I], 4096);
EXPECT_EQ(ExpectedNumBlocks, L.StreamMap[I].size());
}
}
TEST_F(MSFBuilderTest, UseDirectoryBlockHint) {
Expected<MSFBuilder> ExpectedMsf = MSFBuilder::create(
Allocator, 4096, msf::getMinimumBlockCount() + 1, false);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
uint32_t B = msf::getFirstUnreservedBlock();
EXPECT_THAT_ERROR(Msf.setDirectoryBlocksHint({B + 1}), Succeeded());
EXPECT_THAT_EXPECTED(Msf.addStream(2048, {B + 2}), Succeeded());
auto ExpectedLayout = Msf.generateLayout();
EXPECT_THAT_EXPECTED(ExpectedLayout, Succeeded());
MSFLayout &L = *ExpectedLayout;
EXPECT_EQ(msf::getMinimumBlockCount() + 2, L.SB->NumBlocks);
EXPECT_EQ(1U, L.DirectoryBlocks.size());
EXPECT_EQ(1U, L.StreamMap[0].size());
EXPECT_EQ(B + 1, L.DirectoryBlocks[0]);
EXPECT_EQ(B + 2, L.StreamMap[0].front());
}
TEST_F(MSFBuilderTest, DirectoryBlockHintInsufficient) {
Expected<MSFBuilder> ExpectedMsf =
MSFBuilder::create(Allocator, 4096, msf::getMinimumBlockCount() + 2);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
uint32_t B = msf::getFirstUnreservedBlock();
EXPECT_THAT_ERROR(Msf.setDirectoryBlocksHint({B + 1}), Succeeded());
uint32_t Size = 4096 * 4096 / 4;
EXPECT_THAT_EXPECTED(Msf.addStream(Size), Succeeded());
auto ExpectedLayout = Msf.generateLayout();
EXPECT_THAT_EXPECTED(ExpectedLayout, Succeeded());
MSFLayout &L = *ExpectedLayout;
EXPECT_EQ(2U, L.DirectoryBlocks.size());
EXPECT_EQ(B + 1, L.DirectoryBlocks[0]);
}
TEST_F(MSFBuilderTest, DirectoryBlockHintOverestimated) {
Expected<MSFBuilder> ExpectedMsf =
MSFBuilder::create(Allocator, 4096, msf::getMinimumBlockCount() + 2);
EXPECT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
uint32_t B = msf::getFirstUnreservedBlock();
EXPECT_THAT_ERROR(Msf.setDirectoryBlocksHint({B + 1, B + 2}), Succeeded());
ASSERT_THAT_EXPECTED(Msf.addStream(2048), Succeeded());
auto ExpectedLayout = Msf.generateLayout();
ASSERT_THAT_EXPECTED(ExpectedLayout, Succeeded());
MSFLayout &L = *ExpectedLayout;
EXPECT_EQ(1U, L.DirectoryBlocks.size());
EXPECT_EQ(B + 1, L.DirectoryBlocks[0]);
}
TEST_F(MSFBuilderTest, StreamDoesntUseFpmBlocks) {
Expected<MSFBuilder> ExpectedMsf = MSFBuilder::create(Allocator, 4096);
ASSERT_THAT_EXPECTED(ExpectedMsf, Succeeded());
auto &Msf = *ExpectedMsf;
// A block is 4096 bytes, and every 4096 blocks we have 2 reserved FPM blocks.
// By creating add a stream that spans 4096*4096*3 bytes, we ensure that we
// cross over a couple of reserved FPM blocks, and that none of them are
// allocated to the stream.
constexpr uint32_t StreamSize = 4096 * 4096 * 3;
Expected<uint32_t> SN = Msf.addStream(StreamSize);
ASSERT_THAT_EXPECTED(SN, Succeeded());
auto ExpectedLayout = Msf.generateLayout();
ASSERT_THAT_EXPECTED(ExpectedLayout, Succeeded());
MSFLayout &L = *ExpectedLayout;
auto BlocksRef = L.StreamMap[*SN];
std::vector<uint32_t> Blocks(BlocksRef.begin(), BlocksRef.end());
EXPECT_EQ(StreamSize, L.StreamSizes[*SN]);
for (uint32_t I = 0; I <= 3; ++I) {
// Pages from both FPMs are always allocated.
EXPECT_FALSE(L.FreePageMap.test(2 + I * 4096));
EXPECT_FALSE(L.FreePageMap.test(1 + I * 4096));
}
for (uint32_t I = 1; I <= 3; ++I) {
EXPECT_THAT(Blocks, Not(Contains(1 + I * 4096)));
EXPECT_THAT(Blocks, Not(Contains(2 + I * 4096)));
}
}