llvm-project/llvm/unittests/Support/VirtualFileSystemTest.cpp

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//===- unittests/Support/VirtualFileSystem.cpp -------------- VFS tests ---===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "llvm/Support/VirtualFileSystem.h"
[VFS] Reapply #2: Reconstruct the VFS overlay tree for more accurate lookup Reapply r269100 and r269270, reverted due to https://llvm.org/bugs/show_bug.cgi?id=27725. Isolate the testcase that corresponds to the new feature side of this commit and skip it on windows hosts until we find why it does not work on these platforms. Original commit message: The way we currently build the internal VFS overlay representation leads to inefficient path search and might yield wrong answers when asked for recursive or regular directory iteration. Currently, when reading an YAML file, each YAML root entry is placed inside a new root in the filesystem overlay. In the crash reproducer, a simple "@import Foundation" currently maps to 43 roots, and when looking up paths, we traverse a directory tree for each of these different roots, until we find a match (or don't). This has two consequences: - It's slow. - Directory iteration gives incomplete results since it only return results within one root - since contents of the same directory can be declared inside different roots, the result isn't accurate. This is in part fault of the way we currently write out the YAML file when emitting the crash reproducer - we could generate only one root and that would make it fast and correct again. However, we should not rely on how the client writes the YAML, but provide a good internal representation regardless. Build a proper virtual directory tree out of the YAML representation, allowing faster search and proper iteration. Besides the crash reproducer, this potentially benefits other VFS clients. llvm-svn: 269327
2016-05-13 03:13:07 +08:00
#include "llvm/ADT/Triple.h"
#include "llvm/Config/llvm-config.h"
#include "llvm/Support/Errc.h"
[VFS] Reapply #2: Reconstruct the VFS overlay tree for more accurate lookup Reapply r269100 and r269270, reverted due to https://llvm.org/bugs/show_bug.cgi?id=27725. Isolate the testcase that corresponds to the new feature side of this commit and skip it on windows hosts until we find why it does not work on these platforms. Original commit message: The way we currently build the internal VFS overlay representation leads to inefficient path search and might yield wrong answers when asked for recursive or regular directory iteration. Currently, when reading an YAML file, each YAML root entry is placed inside a new root in the filesystem overlay. In the crash reproducer, a simple "@import Foundation" currently maps to 43 roots, and when looking up paths, we traverse a directory tree for each of these different roots, until we find a match (or don't). This has two consequences: - It's slow. - Directory iteration gives incomplete results since it only return results within one root - since contents of the same directory can be declared inside different roots, the result isn't accurate. This is in part fault of the way we currently write out the YAML file when emitting the crash reproducer - we could generate only one root and that would make it fast and correct again. However, we should not rely on how the client writes the YAML, but provide a good internal representation regardless. Build a proper virtual directory tree out of the YAML representation, allowing faster search and proper iteration. Besides the crash reproducer, this potentially benefits other VFS clients. llvm-svn: 269327
2016-05-13 03:13:07 +08:00
#include "llvm/Support/Host.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/SourceMgr.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include <map>
#include <string>
using namespace llvm;
using llvm::sys::fs::UniqueID;
using testing::ElementsAre;
using testing::Pair;
using testing::UnorderedElementsAre;
namespace {
struct DummyFile : public vfs::File {
vfs::Status S;
explicit DummyFile(vfs::Status S) : S(S) {}
llvm::ErrorOr<vfs::Status> status() override { return S; }
llvm::ErrorOr<std::unique_ptr<llvm::MemoryBuffer>>
getBuffer(const Twine &Name, int64_t FileSize, bool RequiresNullTerminator,
bool IsVolatile) override {
llvm_unreachable("unimplemented");
}
std::error_code close() override { return std::error_code(); }
};
class DummyFileSystem : public vfs::FileSystem {
int FSID; // used to produce UniqueIDs
int FileID; // used to produce UniqueIDs
std::string WorkingDirectory;
std::map<std::string, vfs::Status> FilesAndDirs;
typedef std::map<std::string, vfs::Status>::const_iterator const_iterator;
static int getNextFSID() {
static int Count = 0;
return Count++;
}
public:
DummyFileSystem() : FSID(getNextFSID()), FileID(0) {}
ErrorOr<vfs::Status> status(const Twine &Path) override {
auto I = findEntry(Path);
if (I == FilesAndDirs.end())
return make_error_code(llvm::errc::no_such_file_or_directory);
return I->second;
}
ErrorOr<std::unique_ptr<vfs::File>>
openFileForRead(const Twine &Path) override {
auto S = status(Path);
if (S)
return std::unique_ptr<vfs::File>(new DummyFile{*S});
return S.getError();
}
llvm::ErrorOr<std::string> getCurrentWorkingDirectory() const override {
return WorkingDirectory;
}
std::error_code setCurrentWorkingDirectory(const Twine &Path) override {
WorkingDirectory = Path.str();
return std::error_code();
}
// Map any symlink to "/symlink".
std::error_code getRealPath(const Twine &Path,
SmallVectorImpl<char> &Output) const override {
auto I = findEntry(Path);
if (I == FilesAndDirs.end())
return make_error_code(llvm::errc::no_such_file_or_directory);
if (I->second.isSymlink()) {
Output.clear();
Twine("/symlink").toVector(Output);
return std::error_code();
}
Output.clear();
Path.toVector(Output);
return std::error_code();
}
struct DirIterImpl : public llvm::vfs::detail::DirIterImpl {
std::map<std::string, vfs::Status> &FilesAndDirs;
std::map<std::string, vfs::Status>::iterator I;
std::string Path;
bool isInPath(StringRef S) {
if (Path.size() < S.size() && S.find(Path) == 0) {
auto LastSep = S.find_last_of('/');
if (LastSep == Path.size() || LastSep == Path.size() - 1)
return true;
}
return false;
}
DirIterImpl(std::map<std::string, vfs::Status> &FilesAndDirs,
const Twine &_Path)
: FilesAndDirs(FilesAndDirs), I(FilesAndDirs.begin()),
Path(_Path.str()) {
for (; I != FilesAndDirs.end(); ++I) {
if (isInPath(I->first)) {
CurrentEntry = vfs::directory_entry(std::string(I->second.getName()),
I->second.getType());
break;
}
}
}
std::error_code increment() override {
++I;
for (; I != FilesAndDirs.end(); ++I) {
if (isInPath(I->first)) {
CurrentEntry = vfs::directory_entry(std::string(I->second.getName()),
I->second.getType());
break;
}
}
if (I == FilesAndDirs.end())
CurrentEntry = vfs::directory_entry();
return std::error_code();
}
};
vfs::directory_iterator dir_begin(const Twine &Dir,
std::error_code &EC) override {
return vfs::directory_iterator(
std::make_shared<DirIterImpl>(FilesAndDirs, Dir));
}
void addEntry(StringRef Path, const vfs::Status &Status) {
FilesAndDirs[std::string(Path)] = Status;
}
const_iterator findEntry(const Twine &Path) const {
SmallString<128> P;
Path.toVector(P);
std::error_code EC = makeAbsolute(P);
assert(!EC);
(void)EC;
return FilesAndDirs.find(std::string(P.str()));
}
void addRegularFile(StringRef Path, sys::fs::perms Perms = sys::fs::all_all) {
vfs::Status S(Path, UniqueID(FSID, FileID++),
std::chrono::system_clock::now(), 0, 0, 1024,
sys::fs::file_type::regular_file, Perms);
addEntry(Path, S);
}
void addDirectory(StringRef Path, sys::fs::perms Perms = sys::fs::all_all) {
vfs::Status S(Path, UniqueID(FSID, FileID++),
std::chrono::system_clock::now(), 0, 0, 0,
sys::fs::file_type::directory_file, Perms);
addEntry(Path, S);
}
void addSymlink(StringRef Path) {
vfs::Status S(Path, UniqueID(FSID, FileID++),
std::chrono::system_clock::now(), 0, 0, 0,
sys::fs::file_type::symlink_file, sys::fs::all_all);
addEntry(Path, S);
}
};
class ErrorDummyFileSystem : public DummyFileSystem {
std::error_code setCurrentWorkingDirectory(const Twine &Path) override {
return llvm::errc::no_such_file_or_directory;
}
};
/// Replace back-slashes by front-slashes.
std::string getPosixPath(std::string S) {
SmallString<128> Result;
llvm::sys::path::native(S, Result, llvm::sys::path::Style::posix);
return std::string(Result.str());
}
} // end anonymous namespace
TEST(VirtualFileSystemTest, StatusQueries) {
IntrusiveRefCntPtr<DummyFileSystem> D(new DummyFileSystem());
ErrorOr<vfs::Status> Status((std::error_code()));
D->addRegularFile("/foo");
Status = D->status("/foo");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->isStatusKnown());
EXPECT_FALSE(Status->isDirectory());
EXPECT_TRUE(Status->isRegularFile());
EXPECT_FALSE(Status->isSymlink());
EXPECT_FALSE(Status->isOther());
EXPECT_TRUE(Status->exists());
D->addDirectory("/bar");
Status = D->status("/bar");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->isStatusKnown());
EXPECT_TRUE(Status->isDirectory());
EXPECT_FALSE(Status->isRegularFile());
EXPECT_FALSE(Status->isSymlink());
EXPECT_FALSE(Status->isOther());
EXPECT_TRUE(Status->exists());
D->addSymlink("/baz");
Status = D->status("/baz");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->isStatusKnown());
EXPECT_FALSE(Status->isDirectory());
EXPECT_FALSE(Status->isRegularFile());
EXPECT_TRUE(Status->isSymlink());
EXPECT_FALSE(Status->isOther());
EXPECT_TRUE(Status->exists());
EXPECT_TRUE(Status->equivalent(*Status));
ErrorOr<vfs::Status> Status2 = D->status("/foo");
ASSERT_FALSE(Status2.getError());
EXPECT_FALSE(Status->equivalent(*Status2));
}
TEST(VirtualFileSystemTest, BaseOnlyOverlay) {
IntrusiveRefCntPtr<DummyFileSystem> D(new DummyFileSystem());
ErrorOr<vfs::Status> Status((std::error_code()));
EXPECT_FALSE(Status = D->status("/foo"));
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(new vfs::OverlayFileSystem(D));
EXPECT_FALSE(Status = O->status("/foo"));
D->addRegularFile("/foo");
Status = D->status("/foo");
EXPECT_FALSE(Status.getError());
ErrorOr<vfs::Status> Status2((std::error_code()));
Status2 = O->status("/foo");
EXPECT_FALSE(Status2.getError());
EXPECT_TRUE(Status->equivalent(*Status2));
}
TEST(VirtualFileSystemTest, GetRealPathInOverlay) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("/foo");
Lower->addSymlink("/lower_link");
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Upper);
// Regular file.
SmallString<16> RealPath;
EXPECT_FALSE(O->getRealPath("/foo", RealPath));
EXPECT_EQ(RealPath.str(), "/foo");
// Expect no error getting real path for symlink in lower overlay.
EXPECT_FALSE(O->getRealPath("/lower_link", RealPath));
EXPECT_EQ(RealPath.str(), "/symlink");
// Try a non-existing link.
EXPECT_EQ(O->getRealPath("/upper_link", RealPath),
errc::no_such_file_or_directory);
// Add a new symlink in upper.
Upper->addSymlink("/upper_link");
EXPECT_FALSE(O->getRealPath("/upper_link", RealPath));
EXPECT_EQ(RealPath.str(), "/symlink");
}
TEST(VirtualFileSystemTest, OverlayFiles) {
IntrusiveRefCntPtr<DummyFileSystem> Base(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Middle(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Top(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Base));
O->pushOverlay(Middle);
O->pushOverlay(Top);
ErrorOr<vfs::Status> Status1((std::error_code())),
Status2((std::error_code())), Status3((std::error_code())),
StatusB((std::error_code())), StatusM((std::error_code())),
StatusT((std::error_code()));
Base->addRegularFile("/foo");
StatusB = Base->status("/foo");
ASSERT_FALSE(StatusB.getError());
Status1 = O->status("/foo");
ASSERT_FALSE(Status1.getError());
Middle->addRegularFile("/foo");
StatusM = Middle->status("/foo");
ASSERT_FALSE(StatusM.getError());
Status2 = O->status("/foo");
ASSERT_FALSE(Status2.getError());
Top->addRegularFile("/foo");
StatusT = Top->status("/foo");
ASSERT_FALSE(StatusT.getError());
Status3 = O->status("/foo");
ASSERT_FALSE(Status3.getError());
EXPECT_TRUE(Status1->equivalent(*StatusB));
EXPECT_TRUE(Status2->equivalent(*StatusM));
EXPECT_TRUE(Status3->equivalent(*StatusT));
EXPECT_FALSE(Status1->equivalent(*Status2));
EXPECT_FALSE(Status2->equivalent(*Status3));
EXPECT_FALSE(Status1->equivalent(*Status3));
}
TEST(VirtualFileSystemTest, OverlayDirsNonMerged) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Upper);
Lower->addDirectory("/lower-only");
Upper->addDirectory("/upper-only");
// non-merged paths should be the same
ErrorOr<vfs::Status> Status1 = Lower->status("/lower-only");
ASSERT_FALSE(Status1.getError());
ErrorOr<vfs::Status> Status2 = O->status("/lower-only");
ASSERT_FALSE(Status2.getError());
EXPECT_TRUE(Status1->equivalent(*Status2));
Status1 = Upper->status("/upper-only");
ASSERT_FALSE(Status1.getError());
Status2 = O->status("/upper-only");
ASSERT_FALSE(Status2.getError());
EXPECT_TRUE(Status1->equivalent(*Status2));
}
TEST(VirtualFileSystemTest, MergedDirPermissions) {
// merged directories get the permissions of the upper dir
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Upper);
ErrorOr<vfs::Status> Status((std::error_code()));
Lower->addDirectory("/both", sys::fs::owner_read);
Upper->addDirectory("/both", sys::fs::owner_all | sys::fs::group_read);
Status = O->status("/both");
ASSERT_FALSE(Status.getError());
EXPECT_EQ(0740, Status->getPermissions());
// permissions (as usual) are not recursively applied
Lower->addRegularFile("/both/foo", sys::fs::owner_read);
Upper->addRegularFile("/both/bar", sys::fs::owner_write);
Status = O->status("/both/foo");
ASSERT_FALSE(Status.getError());
EXPECT_EQ(0400, Status->getPermissions());
Status = O->status("/both/bar");
ASSERT_FALSE(Status.getError());
EXPECT_EQ(0200, Status->getPermissions());
}
TEST(VirtualFileSystemTest, OverlayIterator) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("/foo");
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Upper);
ErrorOr<vfs::Status> Status((std::error_code()));
{
auto it = O->overlays_begin();
auto end = O->overlays_end();
EXPECT_NE(it, end);
Status = (*it)->status("/foo");
ASSERT_TRUE(Status.getError());
it++;
EXPECT_NE(it, end);
Status = (*it)->status("/foo");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
it++;
EXPECT_EQ(it, end);
}
{
auto it = O->overlays_rbegin();
auto end = O->overlays_rend();
EXPECT_NE(it, end);
Status = (*it)->status("/foo");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
it++;
EXPECT_NE(it, end);
Status = (*it)->status("/foo");
ASSERT_TRUE(Status.getError());
it++;
EXPECT_EQ(it, end);
}
}
namespace {
struct ScopedDir {
SmallString<128> Path;
ScopedDir(const Twine &Name, bool Unique = false) {
std::error_code EC;
if (Unique) {
EC = llvm::sys::fs::createUniqueDirectory(Name, Path);
if (!EC) {
// Resolve any symlinks in the new directory.
std::string UnresolvedPath = std::string(Path.str());
EC = llvm::sys::fs::real_path(UnresolvedPath, Path);
}
} else {
Path = Name.str();
EC = llvm::sys::fs::create_directory(Twine(Path));
}
if (EC)
Path = "";
EXPECT_FALSE(EC) << EC.message();
}
~ScopedDir() {
if (Path != "") {
EXPECT_FALSE(llvm::sys::fs::remove(Path.str()));
}
}
operator StringRef() { return Path.str(); }
};
struct ScopedLink {
SmallString<128> Path;
ScopedLink(const Twine &To, const Twine &From) {
Path = From.str();
std::error_code EC = sys::fs::create_link(To, From);
if (EC)
Path = "";
EXPECT_FALSE(EC);
}
~ScopedLink() {
if (Path != "") {
EXPECT_FALSE(llvm::sys::fs::remove(Path.str()));
}
}
operator StringRef() { return Path.str(); }
};
struct ScopedFile {
SmallString<128> Path;
ScopedFile(const Twine &Path, StringRef Contents) {
Path.toVector(this->Path);
std::error_code EC;
raw_fd_ostream OS(this->Path, EC);
EXPECT_FALSE(EC);
OS << Contents;
OS.flush();
EXPECT_FALSE(OS.error());
if (EC || OS.error())
this->Path = "";
}
~ScopedFile() {
if (Path != "") {
EXPECT_FALSE(llvm::sys::fs::remove(Path.str()));
}
}
};
} // end anonymous namespace
TEST(VirtualFileSystemTest, BasicRealFSIteration) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
IntrusiveRefCntPtr<vfs::FileSystem> FS = vfs::getRealFileSystem();
std::error_code EC;
vfs::directory_iterator I = FS->dir_begin(Twine(TestDirectory), EC);
ASSERT_FALSE(EC);
EXPECT_EQ(vfs::directory_iterator(), I); // empty directory is empty
ScopedDir _a(TestDirectory + "/a");
ScopedDir _ab(TestDirectory + "/a/b");
ScopedDir _c(TestDirectory + "/c");
ScopedDir _cd(TestDirectory + "/c/d");
I = FS->dir_begin(Twine(TestDirectory), EC);
ASSERT_FALSE(EC);
ASSERT_NE(vfs::directory_iterator(), I);
// Check either a or c, since we can't rely on the iteration order.
EXPECT_TRUE(I->path().endswith("a") || I->path().endswith("c"));
I.increment(EC);
ASSERT_FALSE(EC);
ASSERT_NE(vfs::directory_iterator(), I);
EXPECT_TRUE(I->path().endswith("a") || I->path().endswith("c"));
I.increment(EC);
EXPECT_EQ(vfs::directory_iterator(), I);
}
#ifdef LLVM_ON_UNIX
TEST(VirtualFileSystemTest, MultipleWorkingDirs) {
// Our root contains a/aa, b/bb, c, where c is a link to a/.
// Run tests both in root/b/ and root/c/ (to test "normal" and symlink dirs).
// Interleave operations to show the working directories are independent.
ScopedDir Root("r", true), ADir(Root.Path + "/a"), BDir(Root.Path + "/b");
ScopedLink C(ADir.Path, Root.Path + "/c");
ScopedFile AA(ADir.Path + "/aa", "aaaa"), BB(BDir.Path + "/bb", "bbbb");
std::unique_ptr<vfs::FileSystem> BFS = vfs::createPhysicalFileSystem(),
CFS = vfs::createPhysicalFileSystem();
ASSERT_FALSE(BFS->setCurrentWorkingDirectory(BDir.Path));
ASSERT_FALSE(CFS->setCurrentWorkingDirectory(C.Path));
EXPECT_EQ(BDir.Path, *BFS->getCurrentWorkingDirectory());
EXPECT_EQ(C.Path, *CFS->getCurrentWorkingDirectory());
// openFileForRead(), indirectly.
auto BBuf = BFS->getBufferForFile("bb");
ASSERT_TRUE(BBuf);
EXPECT_EQ("bbbb", (*BBuf)->getBuffer());
auto ABuf = CFS->getBufferForFile("aa");
ASSERT_TRUE(ABuf);
EXPECT_EQ("aaaa", (*ABuf)->getBuffer());
// status()
auto BStat = BFS->status("bb");
ASSERT_TRUE(BStat);
EXPECT_EQ("bb", BStat->getName());
auto AStat = CFS->status("aa");
ASSERT_TRUE(AStat);
EXPECT_EQ("aa", AStat->getName()); // unresolved name
// getRealPath()
SmallString<128> BPath;
ASSERT_FALSE(BFS->getRealPath("bb", BPath));
EXPECT_EQ(BB.Path, BPath);
SmallString<128> APath;
ASSERT_FALSE(CFS->getRealPath("aa", APath));
EXPECT_EQ(AA.Path, APath); // Reports resolved name.
// dir_begin
std::error_code EC;
auto BIt = BFS->dir_begin(".", EC);
ASSERT_FALSE(EC);
ASSERT_NE(BIt, vfs::directory_iterator());
EXPECT_EQ((BDir.Path + "/./bb").str(), BIt->path());
BIt.increment(EC);
ASSERT_FALSE(EC);
ASSERT_EQ(BIt, vfs::directory_iterator());
auto CIt = CFS->dir_begin(".", EC);
ASSERT_FALSE(EC);
ASSERT_NE(CIt, vfs::directory_iterator());
EXPECT_EQ((ADir.Path + "/./aa").str(), CIt->path()); // Partly resolved name!
CIt.increment(EC); // Because likely to read through this path.
ASSERT_FALSE(EC);
ASSERT_EQ(CIt, vfs::directory_iterator());
}
TEST(VirtualFileSystemTest, BrokenSymlinkRealFSIteration) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
IntrusiveRefCntPtr<vfs::FileSystem> FS = vfs::getRealFileSystem();
ScopedLink _a("no_such_file", TestDirectory + "/a");
ScopedDir _b(TestDirectory + "/b");
ScopedLink _c("no_such_file", TestDirectory + "/c");
// Should get no iteration error, but a stat error for the broken symlinks.
std::map<std::string, std::error_code> StatResults;
std::error_code EC;
for (vfs::directory_iterator I = FS->dir_begin(Twine(TestDirectory), EC), E;
I != E; I.increment(EC)) {
EXPECT_FALSE(EC);
StatResults[std::string(sys::path::filename(I->path()))] =
FS->status(I->path()).getError();
}
EXPECT_THAT(
StatResults,
ElementsAre(
Pair("a", std::make_error_code(std::errc::no_such_file_or_directory)),
Pair("b", std::error_code()),
Pair("c",
std::make_error_code(std::errc::no_such_file_or_directory))));
}
#endif
TEST(VirtualFileSystemTest, BasicRealFSRecursiveIteration) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
IntrusiveRefCntPtr<vfs::FileSystem> FS = vfs::getRealFileSystem();
std::error_code EC;
auto I = vfs::recursive_directory_iterator(*FS, Twine(TestDirectory), EC);
ASSERT_FALSE(EC);
EXPECT_EQ(vfs::recursive_directory_iterator(), I); // empty directory is empty
ScopedDir _a(TestDirectory + "/a");
ScopedDir _ab(TestDirectory + "/a/b");
ScopedDir _c(TestDirectory + "/c");
ScopedDir _cd(TestDirectory + "/c/d");
I = vfs::recursive_directory_iterator(*FS, Twine(TestDirectory), EC);
ASSERT_FALSE(EC);
ASSERT_NE(vfs::recursive_directory_iterator(), I);
std::vector<std::string> Contents;
for (auto E = vfs::recursive_directory_iterator(); !EC && I != E;
I.increment(EC)) {
Contents.push_back(std::string(I->path()));
}
// Check contents, which may be in any order
EXPECT_EQ(4U, Contents.size());
int Counts[4] = {0, 0, 0, 0};
for (const std::string &Name : Contents) {
ASSERT_FALSE(Name.empty());
int Index = Name[Name.size() - 1] - 'a';
ASSERT_TRUE(Index >= 0 && Index < 4);
Counts[Index]++;
}
EXPECT_EQ(1, Counts[0]); // a
EXPECT_EQ(1, Counts[1]); // b
EXPECT_EQ(1, Counts[2]); // c
EXPECT_EQ(1, Counts[3]); // d
}
TEST(VirtualFileSystemTest, BasicRealFSRecursiveIterationNoPush) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
ScopedDir _a(TestDirectory + "/a");
ScopedDir _ab(TestDirectory + "/a/b");
ScopedDir _c(TestDirectory + "/c");
ScopedDir _cd(TestDirectory + "/c/d");
ScopedDir _e(TestDirectory + "/e");
ScopedDir _ef(TestDirectory + "/e/f");
ScopedDir _g(TestDirectory + "/g");
IntrusiveRefCntPtr<vfs::FileSystem> FS = vfs::getRealFileSystem();
// Test that calling no_push on entries without subdirectories has no effect.
{
std::error_code EC;
auto I = vfs::recursive_directory_iterator(*FS, Twine(TestDirectory), EC);
ASSERT_FALSE(EC);
std::vector<std::string> Contents;
for (auto E = vfs::recursive_directory_iterator(); !EC && I != E;
I.increment(EC)) {
Contents.push_back(std::string(I->path()));
char last = I->path().back();
switch (last) {
case 'b':
case 'd':
case 'f':
case 'g':
I.no_push();
break;
default:
break;
}
}
EXPECT_EQ(7U, Contents.size());
}
// Test that calling no_push skips subdirectories.
{
std::error_code EC;
auto I = vfs::recursive_directory_iterator(*FS, Twine(TestDirectory), EC);
ASSERT_FALSE(EC);
std::vector<std::string> Contents;
for (auto E = vfs::recursive_directory_iterator(); !EC && I != E;
I.increment(EC)) {
Contents.push_back(std::string(I->path()));
char last = I->path().back();
switch (last) {
case 'a':
case 'c':
case 'e':
I.no_push();
break;
default:
break;
}
}
// Check contents, which may be in any order
EXPECT_EQ(4U, Contents.size());
int Counts[7] = {0, 0, 0, 0, 0, 0, 0};
for (const std::string &Name : Contents) {
ASSERT_FALSE(Name.empty());
int Index = Name[Name.size() - 1] - 'a';
ASSERT_TRUE(Index >= 0 && Index < 7);
Counts[Index]++;
}
EXPECT_EQ(1, Counts[0]); // a
EXPECT_EQ(0, Counts[1]); // b
EXPECT_EQ(1, Counts[2]); // c
EXPECT_EQ(0, Counts[3]); // d
EXPECT_EQ(1, Counts[4]); // e
EXPECT_EQ(0, Counts[5]); // f
EXPECT_EQ(1, Counts[6]); // g
}
}
#ifdef LLVM_ON_UNIX
TEST(VirtualFileSystemTest, BrokenSymlinkRealFSRecursiveIteration) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
IntrusiveRefCntPtr<vfs::FileSystem> FS = vfs::getRealFileSystem();
ScopedLink _a("no_such_file", TestDirectory + "/a");
ScopedDir _b(TestDirectory + "/b");
ScopedLink _ba("no_such_file", TestDirectory + "/b/a");
ScopedDir _bb(TestDirectory + "/b/b");
ScopedLink _bc("no_such_file", TestDirectory + "/b/c");
ScopedLink _c("no_such_file", TestDirectory + "/c");
ScopedDir _d(TestDirectory + "/d");
ScopedDir _dd(TestDirectory + "/d/d");
ScopedDir _ddd(TestDirectory + "/d/d/d");
ScopedLink _e("no_such_file", TestDirectory + "/e");
std::vector<std::string> VisitedBrokenSymlinks;
std::vector<std::string> VisitedNonBrokenSymlinks;
std::error_code EC;
for (vfs::recursive_directory_iterator I(*FS, Twine(TestDirectory), EC), E;
I != E; I.increment(EC)) {
EXPECT_FALSE(EC);
(FS->status(I->path()) ? VisitedNonBrokenSymlinks : VisitedBrokenSymlinks)
.push_back(std::string(I->path()));
}
// Check visited file names.
EXPECT_THAT(VisitedBrokenSymlinks,
UnorderedElementsAre(StringRef(_a).str(), StringRef(_ba).str(),
StringRef(_bc).str(), StringRef(_c).str(),
StringRef(_e).str()));
EXPECT_THAT(VisitedNonBrokenSymlinks,
UnorderedElementsAre(StringRef(_b).str(), StringRef(_bb).str(),
StringRef(_d).str(), StringRef(_dd).str(),
StringRef(_ddd).str()));
}
#endif
template <typename DirIter>
static void checkContents(DirIter I, ArrayRef<StringRef> ExpectedOut) {
std::error_code EC;
SmallVector<StringRef, 4> Expected(ExpectedOut.begin(), ExpectedOut.end());
SmallVector<std::string, 4> InputToCheck;
// Do not rely on iteration order to check for contents, sort both
// content vectors before comparison.
for (DirIter E; !EC && I != E; I.increment(EC))
InputToCheck.push_back(std::string(I->path()));
llvm::sort(InputToCheck);
llvm::sort(Expected);
EXPECT_EQ(InputToCheck.size(), Expected.size());
unsigned LastElt = std::min(InputToCheck.size(), Expected.size());
for (unsigned Idx = 0; Idx != LastElt; ++Idx)
EXPECT_EQ(StringRef(InputToCheck[Idx]), Expected[Idx]);
}
TEST(VirtualFileSystemTest, OverlayIteration) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Upper);
std::error_code EC;
checkContents(O->dir_begin("/", EC), ArrayRef<StringRef>());
Lower->addRegularFile("/file1");
checkContents(O->dir_begin("/", EC), ArrayRef<StringRef>("/file1"));
Upper->addRegularFile("/file2");
checkContents(O->dir_begin("/", EC), {"/file2", "/file1"});
Lower->addDirectory("/dir1");
Lower->addRegularFile("/dir1/foo");
Upper->addDirectory("/dir2");
Upper->addRegularFile("/dir2/foo");
checkContents(O->dir_begin("/dir2", EC), ArrayRef<StringRef>("/dir2/foo"));
checkContents(O->dir_begin("/", EC), {"/dir2", "/file2", "/dir1", "/file1"});
}
TEST(VirtualFileSystemTest, OverlayRecursiveIteration) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Middle(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Middle);
O->pushOverlay(Upper);
std::error_code EC;
checkContents(vfs::recursive_directory_iterator(*O, "/", EC),
ArrayRef<StringRef>());
Lower->addRegularFile("/file1");
checkContents(vfs::recursive_directory_iterator(*O, "/", EC),
ArrayRef<StringRef>("/file1"));
Upper->addDirectory("/dir");
Upper->addRegularFile("/dir/file2");
checkContents(vfs::recursive_directory_iterator(*O, "/", EC),
{"/dir", "/dir/file2", "/file1"});
Lower->addDirectory("/dir1");
Lower->addRegularFile("/dir1/foo");
Lower->addDirectory("/dir1/a");
Lower->addRegularFile("/dir1/a/b");
Middle->addDirectory("/a");
Middle->addDirectory("/a/b");
Middle->addDirectory("/a/b/c");
Middle->addRegularFile("/a/b/c/d");
Middle->addRegularFile("/hiddenByUp");
Upper->addDirectory("/dir2");
Upper->addRegularFile("/dir2/foo");
Upper->addRegularFile("/hiddenByUp");
checkContents(vfs::recursive_directory_iterator(*O, "/dir2", EC),
ArrayRef<StringRef>("/dir2/foo"));
checkContents(vfs::recursive_directory_iterator(*O, "/", EC),
{"/dir", "/dir/file2", "/dir2", "/dir2/foo", "/hiddenByUp",
"/a", "/a/b", "/a/b/c", "/a/b/c/d", "/dir1", "/dir1/a",
"/dir1/a/b", "/dir1/foo", "/file1"});
}
TEST(VirtualFileSystemTest, ThreeLevelIteration) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Middle(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Middle);
O->pushOverlay(Upper);
std::error_code EC;
checkContents(O->dir_begin("/", EC), ArrayRef<StringRef>());
Middle->addRegularFile("/file2");
checkContents(O->dir_begin("/", EC), ArrayRef<StringRef>("/file2"));
Lower->addRegularFile("/file1");
Upper->addRegularFile("/file3");
checkContents(O->dir_begin("/", EC), {"/file3", "/file2", "/file1"});
}
TEST(VirtualFileSystemTest, HiddenInIteration) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Middle(new DummyFileSystem());
IntrusiveRefCntPtr<DummyFileSystem> Upper(new DummyFileSystem());
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(Middle);
O->pushOverlay(Upper);
std::error_code EC;
Lower->addRegularFile("/onlyInLow");
Lower->addDirectory("/hiddenByMid");
Lower->addDirectory("/hiddenByUp");
Middle->addRegularFile("/onlyInMid");
Middle->addRegularFile("/hiddenByMid");
Middle->addDirectory("/hiddenByUp");
Upper->addRegularFile("/onlyInUp");
Upper->addRegularFile("/hiddenByUp");
checkContents(
O->dir_begin("/", EC),
{"/hiddenByUp", "/onlyInUp", "/hiddenByMid", "/onlyInMid", "/onlyInLow"});
// Make sure we get the top-most entry
{
std::error_code EC;
vfs::directory_iterator I = O->dir_begin("/", EC), E;
for (; !EC && I != E; I.increment(EC))
if (I->path() == "/hiddenByUp")
break;
ASSERT_NE(E, I);
EXPECT_EQ(sys::fs::file_type::regular_file, I->type());
}
{
std::error_code EC;
vfs::directory_iterator I = O->dir_begin("/", EC), E;
for (; !EC && I != E; I.increment(EC))
if (I->path() == "/hiddenByMid")
break;
ASSERT_NE(E, I);
EXPECT_EQ(sys::fs::file_type::regular_file, I->type());
}
}
TEST(ProxyFileSystemTest, Basic) {
IntrusiveRefCntPtr<vfs::InMemoryFileSystem> Base(
new vfs::InMemoryFileSystem());
vfs::ProxyFileSystem PFS(Base);
Base->addFile("/a", 0, MemoryBuffer::getMemBuffer("test"));
auto Stat = PFS.status("/a");
ASSERT_FALSE(Stat.getError());
auto File = PFS.openFileForRead("/a");
ASSERT_FALSE(File.getError());
EXPECT_EQ("test", (*(*File)->getBuffer("ignored"))->getBuffer());
std::error_code EC;
vfs::directory_iterator I = PFS.dir_begin("/", EC);
ASSERT_FALSE(EC);
ASSERT_EQ("/a", I->path());
I.increment(EC);
ASSERT_FALSE(EC);
ASSERT_EQ(vfs::directory_iterator(), I);
ASSERT_FALSE(PFS.setCurrentWorkingDirectory("/"));
auto PWD = PFS.getCurrentWorkingDirectory();
ASSERT_FALSE(PWD.getError());
ASSERT_EQ("/", *PWD);
SmallString<16> Path;
ASSERT_FALSE(PFS.getRealPath("a", Path));
ASSERT_EQ("/a", Path);
bool Local = true;
ASSERT_FALSE(PFS.isLocal("/a", Local));
EXPECT_FALSE(Local);
}
class InMemoryFileSystemTest : public ::testing::Test {
protected:
llvm::vfs::InMemoryFileSystem FS;
llvm::vfs::InMemoryFileSystem NormalizedFS;
InMemoryFileSystemTest()
: FS(/*UseNormalizedPaths=*/false),
NormalizedFS(/*UseNormalizedPaths=*/true) {}
};
MATCHER_P2(IsHardLinkTo, FS, Target, "") {
StringRef From = arg;
StringRef To = Target;
auto OpenedFrom = FS->openFileForRead(From);
auto OpenedTo = FS->openFileForRead(To);
return !OpenedFrom.getError() && !OpenedTo.getError() &&
(*OpenedFrom)->status()->getUniqueID() ==
(*OpenedTo)->status()->getUniqueID();
}
TEST_F(InMemoryFileSystemTest, IsEmpty) {
auto Stat = FS.status("/a");
ASSERT_EQ(Stat.getError(), errc::no_such_file_or_directory) << FS.toString();
Stat = FS.status("/");
ASSERT_EQ(Stat.getError(), errc::no_such_file_or_directory) << FS.toString();
}
TEST_F(InMemoryFileSystemTest, WindowsPath) {
FS.addFile("c:/windows/system128/foo.cpp", 0, MemoryBuffer::getMemBuffer(""));
auto Stat = FS.status("c:");
#if !defined(_WIN32)
ASSERT_FALSE(Stat.getError()) << Stat.getError() << FS.toString();
#endif
Stat = FS.status("c:/windows/system128/foo.cpp");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << FS.toString();
FS.addFile("d:/windows/foo.cpp", 0, MemoryBuffer::getMemBuffer(""));
Stat = FS.status("d:/windows/foo.cpp");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << FS.toString();
}
TEST_F(InMemoryFileSystemTest, OverlayFile) {
FS.addFile("/a", 0, MemoryBuffer::getMemBuffer("a"));
NormalizedFS.addFile("/a", 0, MemoryBuffer::getMemBuffer("a"));
auto Stat = FS.status("/");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << FS.toString();
Stat = FS.status("/.");
ASSERT_FALSE(Stat);
Stat = NormalizedFS.status("/.");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << FS.toString();
Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_EQ("/a", Stat->getName());
}
TEST_F(InMemoryFileSystemTest, OverlayFileNoOwn) {
auto Buf = MemoryBuffer::getMemBuffer("a");
FS.addFileNoOwn("/a", 0, Buf.get());
auto Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_EQ("/a", Stat->getName());
}
TEST_F(InMemoryFileSystemTest, OpenFileForRead) {
FS.addFile("/a", 0, MemoryBuffer::getMemBuffer("a"));
FS.addFile("././c", 0, MemoryBuffer::getMemBuffer("c"));
FS.addFile("./d/../d", 0, MemoryBuffer::getMemBuffer("d"));
NormalizedFS.addFile("/a", 0, MemoryBuffer::getMemBuffer("a"));
NormalizedFS.addFile("././c", 0, MemoryBuffer::getMemBuffer("c"));
NormalizedFS.addFile("./d/../d", 0, MemoryBuffer::getMemBuffer("d"));
auto File = FS.openFileForRead("/a");
ASSERT_EQ("a", (*(*File)->getBuffer("ignored"))->getBuffer());
File = FS.openFileForRead("/a"); // Open again.
ASSERT_EQ("a", (*(*File)->getBuffer("ignored"))->getBuffer());
File = NormalizedFS.openFileForRead("/././a"); // Open again.
ASSERT_EQ("a", (*(*File)->getBuffer("ignored"))->getBuffer());
File = FS.openFileForRead("/");
ASSERT_EQ(File.getError(), errc::invalid_argument) << FS.toString();
File = FS.openFileForRead("/b");
ASSERT_EQ(File.getError(), errc::no_such_file_or_directory) << FS.toString();
File = FS.openFileForRead("./c");
ASSERT_FALSE(File);
File = FS.openFileForRead("e/../d");
ASSERT_FALSE(File);
File = NormalizedFS.openFileForRead("./c");
ASSERT_EQ("c", (*(*File)->getBuffer("ignored"))->getBuffer());
File = NormalizedFS.openFileForRead("e/../d");
ASSERT_EQ("d", (*(*File)->getBuffer("ignored"))->getBuffer());
}
TEST_F(InMemoryFileSystemTest, DuplicatedFile) {
ASSERT_TRUE(FS.addFile("/a", 0, MemoryBuffer::getMemBuffer("a")));
ASSERT_FALSE(FS.addFile("/a/b", 0, MemoryBuffer::getMemBuffer("a")));
ASSERT_TRUE(FS.addFile("/a", 0, MemoryBuffer::getMemBuffer("a")));
ASSERT_FALSE(FS.addFile("/a", 0, MemoryBuffer::getMemBuffer("b")));
}
TEST_F(InMemoryFileSystemTest, DirectoryIteration) {
FS.addFile("/a", 0, MemoryBuffer::getMemBuffer(""));
FS.addFile("/b/c", 0, MemoryBuffer::getMemBuffer(""));
std::error_code EC;
vfs::directory_iterator I = FS.dir_begin("/", EC);
ASSERT_FALSE(EC);
ASSERT_EQ("/a", I->path());
I.increment(EC);
ASSERT_FALSE(EC);
ASSERT_EQ("/b", I->path());
I.increment(EC);
ASSERT_FALSE(EC);
ASSERT_EQ(vfs::directory_iterator(), I);
I = FS.dir_begin("/b", EC);
ASSERT_FALSE(EC);
// When on Windows, we end up with "/b\\c" as the name. Convert to Posix
// path for the sake of the comparison.
ASSERT_EQ("/b/c", getPosixPath(std::string(I->path())));
I.increment(EC);
ASSERT_FALSE(EC);
ASSERT_EQ(vfs::directory_iterator(), I);
}
TEST_F(InMemoryFileSystemTest, WorkingDirectory) {
FS.setCurrentWorkingDirectory("/b");
FS.addFile("c", 0, MemoryBuffer::getMemBuffer(""));
auto Stat = FS.status("/b/c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_EQ("/b/c", Stat->getName());
ASSERT_EQ("/b", *FS.getCurrentWorkingDirectory());
Stat = FS.status("c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
NormalizedFS.setCurrentWorkingDirectory("/b/c");
NormalizedFS.setCurrentWorkingDirectory(".");
ASSERT_EQ("/b/c",
getPosixPath(NormalizedFS.getCurrentWorkingDirectory().get()));
NormalizedFS.setCurrentWorkingDirectory("..");
ASSERT_EQ("/b",
getPosixPath(NormalizedFS.getCurrentWorkingDirectory().get()));
}
TEST_F(InMemoryFileSystemTest, IsLocal) {
FS.setCurrentWorkingDirectory("/b");
FS.addFile("c", 0, MemoryBuffer::getMemBuffer(""));
std::error_code EC;
bool IsLocal = true;
EC = FS.isLocal("c", IsLocal);
ASSERT_FALSE(EC);
ASSERT_FALSE(IsLocal);
}
#if !defined(_WIN32)
TEST_F(InMemoryFileSystemTest, GetRealPath) {
SmallString<16> Path;
EXPECT_EQ(FS.getRealPath("b", Path), errc::operation_not_permitted);
auto GetRealPath = [this](StringRef P) {
SmallString<16> Output;
auto EC = FS.getRealPath(P, Output);
EXPECT_FALSE(EC);
return std::string(Output);
};
FS.setCurrentWorkingDirectory("a");
EXPECT_EQ(GetRealPath("b"), "a/b");
EXPECT_EQ(GetRealPath("../b"), "b");
EXPECT_EQ(GetRealPath("b/./c"), "a/b/c");
FS.setCurrentWorkingDirectory("/a");
EXPECT_EQ(GetRealPath("b"), "/a/b");
EXPECT_EQ(GetRealPath("../b"), "/b");
EXPECT_EQ(GetRealPath("b/./c"), "/a/b/c");
}
#endif // _WIN32
TEST_F(InMemoryFileSystemTest, AddFileWithUser) {
FS.addFile("/a/b/c", 0, MemoryBuffer::getMemBuffer("abc"), 0xFEEDFACE);
auto Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
ASSERT_EQ(0xFEEDFACE, Stat->getUser());
Stat = FS.status("/a/b");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
ASSERT_EQ(0xFEEDFACE, Stat->getUser());
Stat = FS.status("/a/b/c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isRegularFile());
ASSERT_EQ(sys::fs::perms::all_all, Stat->getPermissions());
ASSERT_EQ(0xFEEDFACE, Stat->getUser());
}
TEST_F(InMemoryFileSystemTest, AddFileWithGroup) {
FS.addFile("/a/b/c", 0, MemoryBuffer::getMemBuffer("abc"), None, 0xDABBAD00);
auto Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
ASSERT_EQ(0xDABBAD00, Stat->getGroup());
Stat = FS.status("/a/b");
ASSERT_TRUE(Stat->isDirectory());
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_EQ(0xDABBAD00, Stat->getGroup());
Stat = FS.status("/a/b/c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isRegularFile());
ASSERT_EQ(sys::fs::perms::all_all, Stat->getPermissions());
ASSERT_EQ(0xDABBAD00, Stat->getGroup());
}
TEST_F(InMemoryFileSystemTest, AddFileWithFileType) {
FS.addFile("/a/b/c", 0, MemoryBuffer::getMemBuffer("abc"), None, None,
sys::fs::file_type::socket_file);
auto Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
Stat = FS.status("/a/b");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
Stat = FS.status("/a/b/c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_EQ(sys::fs::file_type::socket_file, Stat->getType());
ASSERT_EQ(sys::fs::perms::all_all, Stat->getPermissions());
}
TEST_F(InMemoryFileSystemTest, AddFileWithPerms) {
FS.addFile("/a/b/c", 0, MemoryBuffer::getMemBuffer("abc"), None, None, None,
sys::fs::perms::owner_read | sys::fs::perms::owner_write);
auto Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
ASSERT_EQ(sys::fs::perms::owner_read | sys::fs::perms::owner_write |
sys::fs::perms::owner_exe,
Stat->getPermissions());
Stat = FS.status("/a/b");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
ASSERT_EQ(sys::fs::perms::owner_read | sys::fs::perms::owner_write |
sys::fs::perms::owner_exe,
Stat->getPermissions());
Stat = FS.status("/a/b/c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isRegularFile());
ASSERT_EQ(sys::fs::perms::owner_read | sys::fs::perms::owner_write,
Stat->getPermissions());
}
TEST_F(InMemoryFileSystemTest, AddDirectoryThenAddChild) {
FS.addFile("/a", 0, MemoryBuffer::getMemBuffer(""), /*User=*/None,
/*Group=*/None, sys::fs::file_type::directory_file);
FS.addFile("/a/b", 0, MemoryBuffer::getMemBuffer("abc"), /*User=*/None,
/*Group=*/None, sys::fs::file_type::regular_file);
auto Stat = FS.status("/a");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isDirectory());
Stat = FS.status("/a/b");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n" << FS.toString();
ASSERT_TRUE(Stat->isRegularFile());
}
// Test that the name returned by status() is in the same form as the path that
// was requested (to match the behavior of RealFileSystem).
TEST_F(InMemoryFileSystemTest, StatusName) {
NormalizedFS.addFile("/a/b/c", 0, MemoryBuffer::getMemBuffer("abc"),
/*User=*/None,
/*Group=*/None, sys::fs::file_type::regular_file);
NormalizedFS.setCurrentWorkingDirectory("/a/b");
// Access using InMemoryFileSystem::status.
auto Stat = NormalizedFS.status("../b/c");
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n"
<< NormalizedFS.toString();
ASSERT_TRUE(Stat->isRegularFile());
ASSERT_EQ("../b/c", Stat->getName());
// Access using InMemoryFileAdaptor::status.
auto File = NormalizedFS.openFileForRead("../b/c");
ASSERT_FALSE(File.getError()) << File.getError() << "\n"
<< NormalizedFS.toString();
Stat = (*File)->status();
ASSERT_FALSE(Stat.getError()) << Stat.getError() << "\n"
<< NormalizedFS.toString();
ASSERT_TRUE(Stat->isRegularFile());
ASSERT_EQ("../b/c", Stat->getName());
// Access using a directory iterator.
std::error_code EC;
llvm::vfs::directory_iterator It = NormalizedFS.dir_begin("../b", EC);
// When on Windows, we end up with "../b\\c" as the name. Convert to Posix
// path for the sake of the comparison.
ASSERT_EQ("../b/c", getPosixPath(std::string(It->path())));
}
TEST_F(InMemoryFileSystemTest, AddHardLinkToFile) {
StringRef FromLink = "/path/to/FROM/link";
StringRef Target = "/path/to/TO/file";
FS.addFile(Target, 0, MemoryBuffer::getMemBuffer("content of target"));
EXPECT_TRUE(FS.addHardLink(FromLink, Target));
EXPECT_THAT(FromLink, IsHardLinkTo(&FS, Target));
EXPECT_TRUE(FS.status(FromLink)->getSize() == FS.status(Target)->getSize());
EXPECT_TRUE(FS.getBufferForFile(FromLink)->get()->getBuffer() ==
FS.getBufferForFile(Target)->get()->getBuffer());
}
TEST_F(InMemoryFileSystemTest, AddHardLinkInChainPattern) {
StringRef Link0 = "/path/to/0/link";
StringRef Link1 = "/path/to/1/link";
StringRef Link2 = "/path/to/2/link";
StringRef Target = "/path/to/target";
FS.addFile(Target, 0, MemoryBuffer::getMemBuffer("content of target file"));
EXPECT_TRUE(FS.addHardLink(Link2, Target));
EXPECT_TRUE(FS.addHardLink(Link1, Link2));
EXPECT_TRUE(FS.addHardLink(Link0, Link1));
EXPECT_THAT(Link0, IsHardLinkTo(&FS, Target));
EXPECT_THAT(Link1, IsHardLinkTo(&FS, Target));
EXPECT_THAT(Link2, IsHardLinkTo(&FS, Target));
}
TEST_F(InMemoryFileSystemTest, AddHardLinkToAFileThatWasNotAddedBefore) {
EXPECT_FALSE(FS.addHardLink("/path/to/link", "/path/to/target"));
}
TEST_F(InMemoryFileSystemTest, AddHardLinkFromAFileThatWasAddedBefore) {
StringRef Link = "/path/to/link";
StringRef Target = "/path/to/target";
FS.addFile(Target, 0, MemoryBuffer::getMemBuffer("content of target"));
FS.addFile(Link, 0, MemoryBuffer::getMemBuffer("content of link"));
EXPECT_FALSE(FS.addHardLink(Link, Target));
}
TEST_F(InMemoryFileSystemTest, AddSameHardLinkMoreThanOnce) {
StringRef Link = "/path/to/link";
StringRef Target = "/path/to/target";
FS.addFile(Target, 0, MemoryBuffer::getMemBuffer("content of target"));
EXPECT_TRUE(FS.addHardLink(Link, Target));
EXPECT_FALSE(FS.addHardLink(Link, Target));
}
TEST_F(InMemoryFileSystemTest, AddFileInPlaceOfAHardLinkWithSameContent) {
StringRef Link = "/path/to/link";
StringRef Target = "/path/to/target";
StringRef Content = "content of target";
EXPECT_TRUE(FS.addFile(Target, 0, MemoryBuffer::getMemBuffer(Content)));
EXPECT_TRUE(FS.addHardLink(Link, Target));
EXPECT_TRUE(FS.addFile(Link, 0, MemoryBuffer::getMemBuffer(Content)));
}
TEST_F(InMemoryFileSystemTest, AddFileInPlaceOfAHardLinkWithDifferentContent) {
StringRef Link = "/path/to/link";
StringRef Target = "/path/to/target";
StringRef Content = "content of target";
StringRef LinkContent = "different content of link";
EXPECT_TRUE(FS.addFile(Target, 0, MemoryBuffer::getMemBuffer(Content)));
EXPECT_TRUE(FS.addHardLink(Link, Target));
EXPECT_FALSE(FS.addFile(Link, 0, MemoryBuffer::getMemBuffer(LinkContent)));
}
TEST_F(InMemoryFileSystemTest, AddHardLinkToADirectory) {
StringRef Dir = "path/to/dummy/dir";
StringRef Link = "/path/to/link";
StringRef File = "path/to/dummy/dir/target";
StringRef Content = "content of target";
EXPECT_TRUE(FS.addFile(File, 0, MemoryBuffer::getMemBuffer(Content)));
EXPECT_FALSE(FS.addHardLink(Link, Dir));
}
TEST_F(InMemoryFileSystemTest, AddHardLinkFromADirectory) {
StringRef Dir = "path/to/dummy/dir";
StringRef Target = "path/to/dummy/dir/target";
StringRef Content = "content of target";
EXPECT_TRUE(FS.addFile(Target, 0, MemoryBuffer::getMemBuffer(Content)));
EXPECT_FALSE(FS.addHardLink(Dir, Target));
}
TEST_F(InMemoryFileSystemTest, AddHardLinkUnderAFile) {
StringRef CommonContent = "content string";
FS.addFile("/a/b", 0, MemoryBuffer::getMemBuffer(CommonContent));
FS.addFile("/c/d", 0, MemoryBuffer::getMemBuffer(CommonContent));
EXPECT_FALSE(FS.addHardLink("/c/d/e", "/a/b"));
}
TEST_F(InMemoryFileSystemTest, RecursiveIterationWithHardLink) {
std::error_code EC;
FS.addFile("/a/b", 0, MemoryBuffer::getMemBuffer("content string"));
EXPECT_TRUE(FS.addHardLink("/c/d", "/a/b"));
auto I = vfs::recursive_directory_iterator(FS, "/", EC);
ASSERT_FALSE(EC);
std::vector<std::string> Nodes;
for (auto E = vfs::recursive_directory_iterator(); !EC && I != E;
I.increment(EC)) {
Nodes.push_back(getPosixPath(std::string(I->path())));
}
EXPECT_THAT(Nodes, testing::UnorderedElementsAre("/a", "/a/b", "/c", "/c/d"));
}
// NOTE: in the tests below, we use '//root/' as our root directory, since it is
// a legal *absolute* path on Windows as well as *nix.
class VFSFromYAMLTest : public ::testing::Test {
public:
int NumDiagnostics;
void SetUp() override { NumDiagnostics = 0; }
static void CountingDiagHandler(const SMDiagnostic &, void *Context) {
VFSFromYAMLTest *Test = static_cast<VFSFromYAMLTest *>(Context);
++Test->NumDiagnostics;
}
IntrusiveRefCntPtr<vfs::FileSystem>
getFromYAMLRawString(StringRef Content,
IntrusiveRefCntPtr<vfs::FileSystem> ExternalFS) {
std::unique_ptr<MemoryBuffer> Buffer = MemoryBuffer::getMemBuffer(Content);
Reapply [2] [VFS] Add 'overlay-relative' field to YAML files This reapplies r261552 and r263748. Fixed testcase to reapply. The VFS overlay mapping between virtual paths and real paths is done through the 'external-contents' entries in YAML files, which contains hardcoded paths to the real files. When a module compilation crashes, headers are dumped into <name>.cache/vfs directory and are mapped via the <name>.cache/vfs/vfs.yaml. The script generated for reproduction uses -ivfsoverlay pointing to file to gather the mapping between virtual paths and files inside <name>.cache/vfs. Currently, we are only capable of reproducing such crashes in the same machine as they happen, because of the hardcoded paths in 'external-contents'. To be able to reproduce a crash in another machine, this patch introduces a new option in the VFS yaml file called 'overlay-relative'. When it's equal to 'true' it means that the provided path to the YAML file through the -ivfsoverlay option should also be used to prefix the final path for every 'external-contents'. Example, given the invocation snippet "... -ivfsoverlay <name>.cache/vfs/vfs.yaml" and the following entry in the yaml file: "overlay-relative": "true", "roots": [ ... "type": "directory", "name": "/usr/include", "contents": [ { "type": "file", "name": "stdio.h", "external-contents": "/usr/include/stdio.h" }, ... Here, a file manager request for virtual "/usr/include/stdio.h", that will map into real path "/<absolute_path_to>/<name>.cache/vfs/usr/include/stdio.h. This is a useful feature for debugging module crashes in machines other than the one where the error happened. Differential Revision: http://reviews.llvm.org/D17457 rdar://problem/24499339 llvm-svn: 263893
2016-03-20 10:08:48 +08:00
return getVFSFromYAML(std::move(Buffer), CountingDiagHandler, "", this,
ExternalFS);
}
IntrusiveRefCntPtr<vfs::FileSystem> getFromYAMLString(
StringRef Content,
IntrusiveRefCntPtr<vfs::FileSystem> ExternalFS = new DummyFileSystem()) {
std::string VersionPlusContent("{\n 'version':0,\n");
VersionPlusContent += Content.slice(Content.find('{') + 1, StringRef::npos);
return getFromYAMLRawString(VersionPlusContent, ExternalFS);
}
[VFS] Reapply #2: Reconstruct the VFS overlay tree for more accurate lookup Reapply r269100 and r269270, reverted due to https://llvm.org/bugs/show_bug.cgi?id=27725. Isolate the testcase that corresponds to the new feature side of this commit and skip it on windows hosts until we find why it does not work on these platforms. Original commit message: The way we currently build the internal VFS overlay representation leads to inefficient path search and might yield wrong answers when asked for recursive or regular directory iteration. Currently, when reading an YAML file, each YAML root entry is placed inside a new root in the filesystem overlay. In the crash reproducer, a simple "@import Foundation" currently maps to 43 roots, and when looking up paths, we traverse a directory tree for each of these different roots, until we find a match (or don't). This has two consequences: - It's slow. - Directory iteration gives incomplete results since it only return results within one root - since contents of the same directory can be declared inside different roots, the result isn't accurate. This is in part fault of the way we currently write out the YAML file when emitting the crash reproducer - we could generate only one root and that would make it fast and correct again. However, we should not rely on how the client writes the YAML, but provide a good internal representation regardless. Build a proper virtual directory tree out of the YAML representation, allowing faster search and proper iteration. Besides the crash reproducer, this potentially benefits other VFS clients. llvm-svn: 269327
2016-05-13 03:13:07 +08:00
// This is intended as a "XFAIL" for windows hosts.
bool supportsSameDirMultipleYAMLEntries() {
Triple Host(Triple::normalize(sys::getProcessTriple()));
return !Host.isOSWindows();
}
};
TEST_F(VFSFromYAMLTest, BasicVFSFromYAML) {
IntrusiveRefCntPtr<vfs::FileSystem> FS;
FS = getFromYAMLString("");
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString("[]");
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString("'string'");
EXPECT_EQ(nullptr, FS.get());
EXPECT_EQ(3, NumDiagnostics);
}
TEST_F(VFSFromYAMLTest, MappedFiles) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("//root/foo/bar/a");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'file1',\n"
" 'external-contents': '//root/foo/bar/a'\n"
" },\n"
" {\n"
" 'type': 'file',\n"
" 'name': 'file2',\n"
" 'external-contents': '//root/foo/b'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(FS);
// file
ErrorOr<vfs::Status> S = O->status("//root/file1");
ASSERT_FALSE(S.getError());
EXPECT_EQ("//root/foo/bar/a", S->getName());
EXPECT_TRUE(S->IsVFSMapped);
ErrorOr<vfs::Status> SLower = O->status("//root/foo/bar/a");
EXPECT_EQ("//root/foo/bar/a", SLower->getName());
EXPECT_TRUE(S->equivalent(*SLower));
EXPECT_FALSE(SLower->IsVFSMapped);
// file after opening
auto OpenedF = O->openFileForRead("//root/file1");
ASSERT_FALSE(OpenedF.getError());
auto OpenedS = (*OpenedF)->status();
ASSERT_FALSE(OpenedS.getError());
EXPECT_EQ("//root/foo/bar/a", OpenedS->getName());
EXPECT_TRUE(OpenedS->IsVFSMapped);
// directory
S = O->status("//root/");
ASSERT_FALSE(S.getError());
EXPECT_TRUE(S->isDirectory());
EXPECT_TRUE(S->equivalent(*O->status("//root/"))); // non-volatile UniqueID
// broken mapping
EXPECT_EQ(O->status("//root/file2").getError(),
llvm::errc::no_such_file_or_directory);
EXPECT_EQ(0, NumDiagnostics);
}
TEST_F(VFSFromYAMLTest, CaseInsensitive) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("//root/foo/bar/a");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'case-sensitive': 'false',\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'XX',\n"
" 'external-contents': '//root/foo/bar/a'\n"
" }\n"
" ]\n"
"}]}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(FS);
ErrorOr<vfs::Status> S = O->status("//root/XX");
ASSERT_FALSE(S.getError());
ErrorOr<vfs::Status> SS = O->status("//root/xx");
ASSERT_FALSE(SS.getError());
EXPECT_TRUE(S->equivalent(*SS));
SS = O->status("//root/xX");
EXPECT_TRUE(S->equivalent(*SS));
SS = O->status("//root/Xx");
EXPECT_TRUE(S->equivalent(*SS));
EXPECT_EQ(0, NumDiagnostics);
}
TEST_F(VFSFromYAMLTest, CaseSensitive) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("//root/foo/bar/a");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'case-sensitive': 'true',\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'XX',\n"
" 'external-contents': '//root/foo/bar/a'\n"
" }\n"
" ]\n"
"}]}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(FS);
ErrorOr<vfs::Status> SS = O->status("//root/xx");
EXPECT_EQ(SS.getError(), llvm::errc::no_such_file_or_directory);
SS = O->status("//root/xX");
EXPECT_EQ(SS.getError(), llvm::errc::no_such_file_or_directory);
SS = O->status("//root/Xx");
EXPECT_EQ(SS.getError(), llvm::errc::no_such_file_or_directory);
EXPECT_EQ(0, NumDiagnostics);
}
TEST_F(VFSFromYAMLTest, IllegalVFSFile) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
// invalid YAML at top-level
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString("{]", Lower);
EXPECT_EQ(nullptr, FS.get());
// invalid YAML in roots
FS = getFromYAMLString("{ 'roots':[}", Lower);
// invalid YAML in directory
FS = getFromYAMLString(
"{ 'roots':[ { 'name': 'foo', 'type': 'directory', 'contents': [}",
Lower);
EXPECT_EQ(nullptr, FS.get());
// invalid configuration
FS = getFromYAMLString("{ 'knobular': 'true', 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString("{ 'case-sensitive': 'maybe', 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
// invalid roots
FS = getFromYAMLString("{ 'roots':'' }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString("{ 'roots':{} }", Lower);
EXPECT_EQ(nullptr, FS.get());
// invalid entries
FS = getFromYAMLString(
"{ 'roots':[ { 'type': 'other', 'name': 'me', 'contents': '' }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString("{ 'roots':[ { 'type': 'file', 'name': [], "
"'external-contents': 'other' }",
Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'roots':[ { 'type': 'file', 'name': 'me', 'external-contents': [] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'roots':[ { 'type': 'file', 'name': 'me', 'external-contents': {} }",
Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'roots':[ { 'type': 'directory', 'name': 'me', 'contents': {} }",
Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'roots':[ { 'type': 'directory', 'name': 'me', 'contents': '' }",
Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'roots':[ { 'thingy': 'directory', 'name': 'me', 'contents': [] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
// missing mandatory fields
FS = getFromYAMLString("{ 'roots':[ { 'type': 'file', 'name': 'me' }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'roots':[ { 'type': 'file', 'external-contents': 'other' }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString("{ 'roots':[ { 'name': 'me', 'contents': [] }", Lower);
EXPECT_EQ(nullptr, FS.get());
// duplicate keys
FS = getFromYAMLString("{ 'roots':[], 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLString(
"{ 'case-sensitive':'true', 'case-sensitive':'true', 'roots':[] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
FS =
getFromYAMLString("{ 'roots':[{'name':'me', 'name':'you', 'type':'file', "
"'external-contents':'blah' } ] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
// missing version
FS = getFromYAMLRawString("{ 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
// bad version number
FS = getFromYAMLRawString("{ 'version':'foo', 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLRawString("{ 'version':-1, 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
FS = getFromYAMLRawString("{ 'version':100000, 'roots':[] }", Lower);
EXPECT_EQ(nullptr, FS.get());
EXPECT_EQ(24, NumDiagnostics);
}
TEST_F(VFSFromYAMLTest, UseExternalName) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("//root/external/file");
IntrusiveRefCntPtr<vfs::FileSystem> FS =
getFromYAMLString("{ 'roots': [\n"
" { 'type': 'file', 'name': '//root/A',\n"
" 'external-contents': '//root/external/file'\n"
" },\n"
" { 'type': 'file', 'name': '//root/B',\n"
" 'use-external-name': true,\n"
" 'external-contents': '//root/external/file'\n"
" },\n"
" { 'type': 'file', 'name': '//root/C',\n"
" 'use-external-name': false,\n"
" 'external-contents': '//root/external/file'\n"
" }\n"
"] }",
Lower);
ASSERT_TRUE(nullptr != FS.get());
// default true
EXPECT_EQ("//root/external/file", FS->status("//root/A")->getName());
// explicit
EXPECT_EQ("//root/external/file", FS->status("//root/B")->getName());
EXPECT_EQ("//root/C", FS->status("//root/C")->getName());
// global configuration
FS = getFromYAMLString("{ 'use-external-names': false,\n"
" 'roots': [\n"
" { 'type': 'file', 'name': '//root/A',\n"
" 'external-contents': '//root/external/file'\n"
" },\n"
" { 'type': 'file', 'name': '//root/B',\n"
" 'use-external-name': true,\n"
" 'external-contents': '//root/external/file'\n"
" },\n"
" { 'type': 'file', 'name': '//root/C',\n"
" 'use-external-name': false,\n"
" 'external-contents': '//root/external/file'\n"
" }\n"
"] }",
Lower);
ASSERT_TRUE(nullptr != FS.get());
// default
EXPECT_EQ("//root/A", FS->status("//root/A")->getName());
// explicit
EXPECT_EQ("//root/external/file", FS->status("//root/B")->getName());
EXPECT_EQ("//root/C", FS->status("//root/C")->getName());
}
TEST_F(VFSFromYAMLTest, MultiComponentPath) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("//root/other");
// file in roots
IntrusiveRefCntPtr<vfs::FileSystem> FS =
getFromYAMLString("{ 'roots': [\n"
" { 'type': 'file', 'name': '//root/path/to/file',\n"
" 'external-contents': '//root/other' }]\n"
"}",
Lower);
ASSERT_TRUE(nullptr != FS.get());
EXPECT_FALSE(FS->status("//root/path/to/file").getError());
EXPECT_FALSE(FS->status("//root/path/to").getError());
EXPECT_FALSE(FS->status("//root/path").getError());
EXPECT_FALSE(FS->status("//root/").getError());
// at the start
FS = getFromYAMLString(
"{ 'roots': [\n"
" { 'type': 'directory', 'name': '//root/path/to',\n"
" 'contents': [ { 'type': 'file', 'name': 'file',\n"
" 'external-contents': '//root/other' }]}]\n"
"}",
Lower);
ASSERT_TRUE(nullptr != FS.get());
EXPECT_FALSE(FS->status("//root/path/to/file").getError());
EXPECT_FALSE(FS->status("//root/path/to").getError());
EXPECT_FALSE(FS->status("//root/path").getError());
EXPECT_FALSE(FS->status("//root/").getError());
// at the end
FS = getFromYAMLString(
"{ 'roots': [\n"
" { 'type': 'directory', 'name': '//root/',\n"
" 'contents': [ { 'type': 'file', 'name': 'path/to/file',\n"
" 'external-contents': '//root/other' }]}]\n"
"}",
Lower);
ASSERT_TRUE(nullptr != FS.get());
EXPECT_FALSE(FS->status("//root/path/to/file").getError());
EXPECT_FALSE(FS->status("//root/path/to").getError());
EXPECT_FALSE(FS->status("//root/path").getError());
EXPECT_FALSE(FS->status("//root/").getError());
}
TEST_F(VFSFromYAMLTest, TrailingSlashes) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addRegularFile("//root/other");
// file in roots
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'roots': [\n"
" { 'type': 'directory', 'name': '//root/path/to////',\n"
" 'contents': [ { 'type': 'file', 'name': 'file',\n"
" 'external-contents': '//root/other' }]}]\n"
"}",
Lower);
ASSERT_TRUE(nullptr != FS.get());
EXPECT_FALSE(FS->status("//root/path/to/file").getError());
EXPECT_FALSE(FS->status("//root/path/to").getError());
EXPECT_FALSE(FS->status("//root/path").getError());
EXPECT_FALSE(FS->status("//root/").getError());
}
TEST_F(VFSFromYAMLTest, DirectoryIteration) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/");
Lower->addDirectory("//root/foo");
Lower->addDirectory("//root/foo/bar");
Lower->addRegularFile("//root/foo/bar/a");
Lower->addRegularFile("//root/foo/bar/b");
Lower->addRegularFile("//root/file3");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'file1',\n"
" 'external-contents': '//root/foo/bar/a'\n"
" },\n"
" {\n"
" 'type': 'file',\n"
" 'name': 'file2',\n"
" 'external-contents': '//root/foo/bar/b'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(FS);
std::error_code EC;
checkContents(O->dir_begin("//root/", EC),
{"//root/file1", "//root/file2", "//root/file3", "//root/foo"});
checkContents(O->dir_begin("//root/foo/bar", EC),
{"//root/foo/bar/a", "//root/foo/bar/b"});
}
[VFS] Reapply #2: Reconstruct the VFS overlay tree for more accurate lookup Reapply r269100 and r269270, reverted due to https://llvm.org/bugs/show_bug.cgi?id=27725. Isolate the testcase that corresponds to the new feature side of this commit and skip it on windows hosts until we find why it does not work on these platforms. Original commit message: The way we currently build the internal VFS overlay representation leads to inefficient path search and might yield wrong answers when asked for recursive or regular directory iteration. Currently, when reading an YAML file, each YAML root entry is placed inside a new root in the filesystem overlay. In the crash reproducer, a simple "@import Foundation" currently maps to 43 roots, and when looking up paths, we traverse a directory tree for each of these different roots, until we find a match (or don't). This has two consequences: - It's slow. - Directory iteration gives incomplete results since it only return results within one root - since contents of the same directory can be declared inside different roots, the result isn't accurate. This is in part fault of the way we currently write out the YAML file when emitting the crash reproducer - we could generate only one root and that would make it fast and correct again. However, we should not rely on how the client writes the YAML, but provide a good internal representation regardless. Build a proper virtual directory tree out of the YAML representation, allowing faster search and proper iteration. Besides the crash reproducer, this potentially benefits other VFS clients. llvm-svn: 269327
2016-05-13 03:13:07 +08:00
TEST_F(VFSFromYAMLTest, DirectoryIterationSameDirMultipleEntries) {
// https://llvm.org/bugs/show_bug.cgi?id=27725
if (!supportsSameDirMultipleYAMLEntries())
return;
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/zab");
Lower->addDirectory("//root/baz");
Lower->addRegularFile("//root/zab/a");
Lower->addRegularFile("//root/zab/b");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/baz/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'x',\n"
" 'external-contents': '//root/zab/a'\n"
" }\n"
" ]\n"
"},\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/baz/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'y',\n"
" 'external-contents': '//root/zab/b'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(FS);
std::error_code EC;
checkContents(O->dir_begin("//root/baz/", EC),
{"//root/baz/x", "//root/baz/y"});
}
TEST_F(VFSFromYAMLTest, RecursiveDirectoryIterationLevel) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/a");
Lower->addDirectory("//root/a/b");
Lower->addDirectory("//root/a/b/c");
Lower->addRegularFile("//root/a/b/c/file");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/a/b/c/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'file',\n"
" 'external-contents': '//root/a/b/c/file'\n"
" }\n"
" ]\n"
"},\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
IntrusiveRefCntPtr<vfs::OverlayFileSystem> O(
new vfs::OverlayFileSystem(Lower));
O->pushOverlay(FS);
std::error_code EC;
// Test recursive_directory_iterator level()
vfs::recursive_directory_iterator I = vfs::recursive_directory_iterator(
*O, "//root", EC),
E;
ASSERT_FALSE(EC);
for (int l = 0; I != E; I.increment(EC), ++l) {
ASSERT_FALSE(EC);
EXPECT_EQ(I.level(), l);
}
EXPECT_EQ(I, E);
}
TEST_F(VFSFromYAMLTest, RelativePaths) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
// Filename at root level without a parent directory.
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'roots': [\n"
" { 'type': 'file', 'name': 'file-not-in-directory.h',\n"
" 'external-contents': '//root/external/file'\n"
" }\n"
"] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
// Relative file path.
FS = getFromYAMLString("{ 'roots': [\n"
" { 'type': 'file', 'name': 'relative/file/path.h',\n"
" 'external-contents': '//root/external/file'\n"
" }\n"
"] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
// Relative directory path.
FS = getFromYAMLString(
"{ 'roots': [\n"
" { 'type': 'directory', 'name': 'relative/directory/path.h',\n"
" 'contents': []\n"
" }\n"
"] }",
Lower);
EXPECT_EQ(nullptr, FS.get());
EXPECT_EQ(3, NumDiagnostics);
}
TEST_F(VFSFromYAMLTest, NonFallthroughDirectoryIteration) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/");
Lower->addRegularFile("//root/a");
Lower->addRegularFile("//root/b");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'fallthrough': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'c',\n"
" 'external-contents': '//root/a'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
std::error_code EC;
checkContents(FS->dir_begin("//root/", EC),
{"//root/c"});
}
TEST_F(VFSFromYAMLTest, DirectoryIterationWithDuplicates) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/");
Lower->addRegularFile("//root/a");
Lower->addRegularFile("//root/b");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'a',\n"
" 'external-contents': '//root/a'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
std::error_code EC;
checkContents(FS->dir_begin("//root/", EC),
{"//root/a", "//root/b"});
}
TEST_F(VFSFromYAMLTest, DirectoryIterationErrorInVFSLayer) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/");
Lower->addDirectory("//root/foo");
Lower->addRegularFile("//root/foo/a");
Lower->addRegularFile("//root/foo/b");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'bar/a',\n"
" 'external-contents': '//root/foo/a'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
std::error_code EC;
checkContents(FS->dir_begin("//root/foo", EC),
{"//root/foo/a", "//root/foo/b"});
}
TEST_F(VFSFromYAMLTest, GetRealPath) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//dir/");
Lower->addRegularFile("/foo");
Lower->addSymlink("/link");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'bar',\n"
" 'external-contents': '/link'\n"
" }\n"
" ]\n"
"},\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//dir/',\n"
" 'contents': []\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
// Regular file present in underlying file system.
SmallString<16> RealPath;
EXPECT_FALSE(FS->getRealPath("/foo", RealPath));
EXPECT_EQ(RealPath.str(), "/foo");
// File present in YAML pointing to symlink in underlying file system.
EXPECT_FALSE(FS->getRealPath("//root/bar", RealPath));
EXPECT_EQ(RealPath.str(), "/symlink");
// Directories should fall back to the underlying file system is possible.
EXPECT_FALSE(FS->getRealPath("//dir/", RealPath));
EXPECT_EQ(RealPath.str(), "//dir/");
// Try a non-existing file.
EXPECT_EQ(FS->getRealPath("/non_existing", RealPath),
errc::no_such_file_or_directory);
}
TEST_F(VFSFromYAMLTest, WorkingDirectory) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/");
Lower->addDirectory("//root/foo");
Lower->addRegularFile("//root/foo/a");
Lower->addRegularFile("//root/foo/b");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/bar',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'a',\n"
" 'external-contents': '//root/foo/a'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
std::error_code EC = FS->setCurrentWorkingDirectory("//root/bar");
ASSERT_FALSE(EC);
llvm::ErrorOr<std::string> WorkingDir = FS->getCurrentWorkingDirectory();
ASSERT_TRUE(WorkingDir);
EXPECT_EQ(*WorkingDir, "//root/bar");
llvm::ErrorOr<vfs::Status> Status = FS->status("./a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->isStatusKnown());
EXPECT_FALSE(Status->isDirectory());
EXPECT_TRUE(Status->isRegularFile());
EXPECT_FALSE(Status->isSymlink());
EXPECT_FALSE(Status->isOther());
EXPECT_TRUE(Status->exists());
EC = FS->setCurrentWorkingDirectory("bogus");
ASSERT_TRUE(EC);
WorkingDir = FS->getCurrentWorkingDirectory();
ASSERT_TRUE(WorkingDir);
EXPECT_EQ(*WorkingDir, "//root/bar");
EC = FS->setCurrentWorkingDirectory("//root/");
ASSERT_FALSE(EC);
WorkingDir = FS->getCurrentWorkingDirectory();
ASSERT_TRUE(WorkingDir);
EXPECT_EQ(*WorkingDir, "//root/");
EC = FS->setCurrentWorkingDirectory("bar");
ASSERT_FALSE(EC);
WorkingDir = FS->getCurrentWorkingDirectory();
ASSERT_TRUE(WorkingDir);
EXPECT_EQ(*WorkingDir, "//root/bar");
}
TEST_F(VFSFromYAMLTest, WorkingDirectoryFallthrough) {
IntrusiveRefCntPtr<DummyFileSystem> Lower(new DummyFileSystem());
Lower->addDirectory("//root/");
Lower->addDirectory("//root/foo");
Lower->addRegularFile("//root/foo/a");
Lower->addRegularFile("//root/foo/b");
Lower->addRegularFile("//root/c");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/bar',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'a',\n"
" 'external-contents': '//root/foo/a'\n"
" }\n"
" ]\n"
"},\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/bar/baz',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'a',\n"
" 'external-contents': '//root/foo/a'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
std::error_code EC = FS->setCurrentWorkingDirectory("//root/");
ASSERT_FALSE(EC);
ASSERT_TRUE(FS.get() != nullptr);
llvm::ErrorOr<vfs::Status> Status = FS->status("bar/a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
Status = FS->status("foo/a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
EC = FS->setCurrentWorkingDirectory("//root/bar");
ASSERT_FALSE(EC);
Status = FS->status("./a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
Status = FS->status("./b");
ASSERT_TRUE(Status.getError());
Status = FS->status("./c");
ASSERT_TRUE(Status.getError());
EC = FS->setCurrentWorkingDirectory("//root/");
ASSERT_FALSE(EC);
Status = FS->status("c");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
Status = FS->status("./bar/baz/a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
EC = FS->setCurrentWorkingDirectory("//root/bar");
ASSERT_FALSE(EC);
Status = FS->status("./baz/a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
Status = FS->status("../bar/baz/a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
}
TEST_F(VFSFromYAMLTest, WorkingDirectoryFallthroughInvalid) {
IntrusiveRefCntPtr<ErrorDummyFileSystem> Lower(new ErrorDummyFileSystem());
Lower->addDirectory("//root/");
Lower->addDirectory("//root/foo");
Lower->addRegularFile("//root/foo/a");
Lower->addRegularFile("//root/foo/b");
Lower->addRegularFile("//root/c");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLString(
"{ 'use-external-names': false,\n"
" 'roots': [\n"
"{\n"
" 'type': 'directory',\n"
" 'name': '//root/bar',\n"
" 'contents': [ {\n"
" 'type': 'file',\n"
" 'name': 'a',\n"
" 'external-contents': '//root/foo/a'\n"
" }\n"
" ]\n"
"}\n"
"]\n"
"}",
Lower);
ASSERT_TRUE(FS.get() != nullptr);
std::error_code EC = FS->setCurrentWorkingDirectory("//root/");
ASSERT_FALSE(EC);
ASSERT_TRUE(FS.get() != nullptr);
llvm::ErrorOr<vfs::Status> Status = FS->status("bar/a");
ASSERT_FALSE(Status.getError());
EXPECT_TRUE(Status->exists());
Status = FS->status("foo/a");
ASSERT_TRUE(Status.getError());
}
TEST_F(VFSFromYAMLTest, YAMLVFSWriterTest) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
ScopedDir _a(TestDirectory + "/a");
ScopedFile _ab(TestDirectory + "/a/b", "");
ScopedDir _c(TestDirectory + "/c");
ScopedFile _cd(TestDirectory + "/c/d", "");
ScopedDir _e(TestDirectory + "/e");
ScopedDir _ef(TestDirectory + "/e/f");
ScopedFile _g(TestDirectory + "/g", "");
ScopedDir _h(TestDirectory + "/h");
vfs::YAMLVFSWriter VFSWriter;
VFSWriter.addDirectoryMapping(_a.Path, "//root/a");
VFSWriter.addFileMapping(_ab.Path, "//root/a/b");
VFSWriter.addFileMapping(_cd.Path, "//root/c/d");
VFSWriter.addDirectoryMapping(_e.Path, "//root/e");
VFSWriter.addDirectoryMapping(_ef.Path, "//root/e/f");
VFSWriter.addFileMapping(_g.Path, "//root/g");
VFSWriter.addDirectoryMapping(_h.Path, "//root/h");
std::string Buffer;
raw_string_ostream OS(Buffer);
VFSWriter.write(OS);
OS.flush();
IntrusiveRefCntPtr<ErrorDummyFileSystem> Lower(new ErrorDummyFileSystem());
Lower->addDirectory("//root/");
Lower->addDirectory("//root/a");
Lower->addRegularFile("//root/a/b");
Lower->addDirectory("//root/b");
Lower->addDirectory("//root/c");
Lower->addRegularFile("//root/c/d");
Lower->addDirectory("//root/e");
Lower->addDirectory("//root/e/f");
Lower->addRegularFile("//root/g");
Lower->addDirectory("//root/h");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLRawString(Buffer, Lower);
ASSERT_TRUE(FS.get() != nullptr);
EXPECT_TRUE(FS->exists(_a.Path));
EXPECT_TRUE(FS->exists(_ab.Path));
EXPECT_TRUE(FS->exists(_c.Path));
EXPECT_TRUE(FS->exists(_cd.Path));
EXPECT_TRUE(FS->exists(_e.Path));
EXPECT_TRUE(FS->exists(_ef.Path));
EXPECT_TRUE(FS->exists(_g.Path));
EXPECT_TRUE(FS->exists(_h.Path));
}
TEST_F(VFSFromYAMLTest, YAMLVFSWriterTest2) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
ScopedDir _a(TestDirectory + "/a");
ScopedFile _ab(TestDirectory + "/a/b", "");
ScopedDir _ac(TestDirectory + "/a/c");
ScopedFile _acd(TestDirectory + "/a/c/d", "");
ScopedFile _ace(TestDirectory + "/a/c/e", "");
ScopedFile _acf(TestDirectory + "/a/c/f", "");
ScopedDir _ag(TestDirectory + "/a/g");
ScopedFile _agh(TestDirectory + "/a/g/h", "");
vfs::YAMLVFSWriter VFSWriter;
VFSWriter.addDirectoryMapping(_a.Path, "//root/a");
VFSWriter.addFileMapping(_ab.Path, "//root/a/b");
VFSWriter.addDirectoryMapping(_ac.Path, "//root/a/c");
VFSWriter.addFileMapping(_acd.Path, "//root/a/c/d");
VFSWriter.addFileMapping(_ace.Path, "//root/a/c/e");
VFSWriter.addFileMapping(_acf.Path, "//root/a/c/f");
VFSWriter.addDirectoryMapping(_ag.Path, "//root/a/g");
VFSWriter.addFileMapping(_agh.Path, "//root/a/g/h");
std::string Buffer;
raw_string_ostream OS(Buffer);
VFSWriter.write(OS);
OS.flush();
IntrusiveRefCntPtr<ErrorDummyFileSystem> Lower(new ErrorDummyFileSystem());
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLRawString(Buffer, Lower);
// FIXME: Missing comma separator between file entries.
EXPECT_FALSE(FS.get() != nullptr);
}
TEST_F(VFSFromYAMLTest, YAMLVFSWriterTest3) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
ScopedDir _a(TestDirectory + "/a");
ScopedFile _ab(TestDirectory + "/a/b", "");
ScopedDir _ac(TestDirectory + "/a/c");
ScopedDir _acd(TestDirectory + "/a/c/d");
ScopedDir _acde(TestDirectory + "/a/c/d/e");
ScopedFile _acdef(TestDirectory + "/a/c/d/e/f", "");
ScopedFile _acdeg(TestDirectory + "/a/c/d/e/g", "");
ScopedDir _ah(TestDirectory + "/a/h");
ScopedFile _ahi(TestDirectory + "/a/h/i", "");
vfs::YAMLVFSWriter VFSWriter;
VFSWriter.addDirectoryMapping(_a.Path, "//root/a");
VFSWriter.addFileMapping(_ab.Path, "//root/a/b");
VFSWriter.addDirectoryMapping(_ac.Path, "//root/a/c");
VFSWriter.addDirectoryMapping(_acd.Path, "//root/a/c/d");
VFSWriter.addDirectoryMapping(_acde.Path, "//root/a/c/d/e");
VFSWriter.addFileMapping(_acdef.Path, "//root/a/c/d/e/f");
VFSWriter.addFileMapping(_acdeg.Path, "//root/a/c/d/e/g");
VFSWriter.addDirectoryMapping(_ahi.Path, "//root/a/h");
VFSWriter.addFileMapping(_ahi.Path, "//root/a/h/i");
std::string Buffer;
raw_string_ostream OS(Buffer);
VFSWriter.write(OS);
OS.flush();
IntrusiveRefCntPtr<ErrorDummyFileSystem> Lower(new ErrorDummyFileSystem());
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLRawString(Buffer, Lower);
// FIXME: Spurious comma separator before first file entry in directory.
EXPECT_FALSE(FS.get() != nullptr);
}
TEST_F(VFSFromYAMLTest, YAMLVFSWriterTestHandleDirs) {
ScopedDir TestDirectory("virtual-file-system-test", /*Unique*/ true);
ScopedDir _a(TestDirectory + "/a");
ScopedDir _b(TestDirectory + "/b");
ScopedDir _c(TestDirectory + "/c");
vfs::YAMLVFSWriter VFSWriter;
VFSWriter.addDirectoryMapping(_a.Path, "//root/a");
VFSWriter.addDirectoryMapping(_b.Path, "//root/b");
VFSWriter.addDirectoryMapping(_c.Path, "//root/c");
std::string Buffer;
raw_string_ostream OS(Buffer);
VFSWriter.write(OS);
OS.flush();
// We didn't add a single file - only directories.
EXPECT_TRUE(Buffer.find("'type': 'file'") == std::string::npos);
IntrusiveRefCntPtr<ErrorDummyFileSystem> Lower(new ErrorDummyFileSystem());
Lower->addDirectory("//root/a");
Lower->addDirectory("//root/b");
Lower->addDirectory("//root/c");
// canaries
Lower->addRegularFile("//root/a/a");
Lower->addRegularFile("//root/b/b");
Lower->addRegularFile("//root/c/c");
IntrusiveRefCntPtr<vfs::FileSystem> FS = getFromYAMLRawString(Buffer, Lower);
ASSERT_TRUE(FS.get() != nullptr);
EXPECT_FALSE(FS->exists(_a.Path + "/a"));
EXPECT_FALSE(FS->exists(_b.Path + "/b"));
EXPECT_FALSE(FS->exists(_c.Path + "/c"));
}