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|
// Copyright 2018 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <elf.h>
#include <errno.h>
#include <signal.h>
#include <sys/ptrace.h>
#include <sys/syscall.h>
#include <sys/types.h>
#include <sys/user.h>
#include <unistd.h>
#include <algorithm>
#include <functional>
#include <iterator>
#include <tuple>
#include <utility>
#include <vector>
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "absl/strings/str_cat.h"
#include "absl/strings/string_view.h"
#include "test/util/cleanup.h"
#include "test/util/file_descriptor.h"
#include "test/util/fs_util.h"
#include "test/util/multiprocess_util.h"
#include "test/util/posix_error.h"
#include "test/util/proc_util.h"
#include "test/util/temp_path.h"
#include "test/util/test_util.h"
namespace gvisor {
namespace testing {
namespace {
using ::testing::AnyOf;
using ::testing::Eq;
#ifndef __x86_64__
// The assembly stub and ELF internal details must be ported to other arches.
#error "Test only supported on x86-64"
#endif // __x86_64__
// amd64 stub that calls PTRACE_TRACEME and sends itself SIGSTOP.
const char kPtraceCode[] = {
// movq $101, %rax /* ptrace */
'\x48',
'\xc7',
'\xc0',
'\x65',
'\x00',
'\x00',
'\x00',
// movq $0, %rsi /* PTRACE_TRACEME */
'\x48',
'\xc7',
'\xc6',
'\x00',
'\x00',
'\x00',
'\x00',
// movq $0, %rdi
'\x48',
'\xc7',
'\xc7',
'\x00',
'\x00',
'\x00',
'\x00',
// movq $0, %rdx
'\x48',
'\xc7',
'\xc2',
'\x00',
'\x00',
'\x00',
'\x00',
// movq $0, %r10
'\x49',
'\xc7',
'\xc2',
'\x00',
'\x00',
'\x00',
'\x00',
// syscall
'\x0f',
'\x05',
// movq $39, %rax /* getpid */
'\x48',
'\xc7',
'\xc0',
'\x27',
'\x00',
'\x00',
'\x00',
// syscall
'\x0f',
'\x05',
// movq %rax, %rdi /* pid */
'\x48',
'\x89',
'\xc7',
// movq $62, %rax /* kill */
'\x48',
'\xc7',
'\xc0',
'\x3e',
'\x00',
'\x00',
'\x00',
// movq $19, %rsi /* SIGSTOP */
'\x48',
'\xc7',
'\xc6',
'\x13',
'\x00',
'\x00',
'\x00',
// syscall
'\x0f',
'\x05',
};
// Size of a syscall instruction.
constexpr int kSyscallSize = 2;
// This test suite tests executable loading in the kernel (ELF and interpreter
// scripts).
// Parameterized ELF types for 64 and 32 bit.
template <int Size>
struct ElfTypes;
template <>
struct ElfTypes<64> {
typedef Elf64_Ehdr ElfEhdr;
typedef Elf64_Phdr ElfPhdr;
};
template <>
struct ElfTypes<32> {
typedef Elf32_Ehdr ElfEhdr;
typedef Elf32_Phdr ElfPhdr;
};
template <int Size>
struct ElfBinary {
using ElfEhdr = typename ElfTypes<Size>::ElfEhdr;
using ElfPhdr = typename ElfTypes<Size>::ElfPhdr;
ElfEhdr header = {};
std::vector<ElfPhdr> phdrs;
std::vector<char> data;
// UpdateOffsets updates p_offset, p_vaddr in all phdrs to account for the
// space taken by the header and phdrs.
//
// It also updates header.e_phnum and adds the offset to header.e_entry to
// account for the headers residing in the first PT_LOAD segment.
//
// Before calling UpdateOffsets each of those fields should be the appropriate
// offset into data.
void UpdateOffsets() {
size_t offset = sizeof(header) + phdrs.size() * sizeof(ElfPhdr);
header.e_entry += offset;
header.e_phnum = phdrs.size();
for (auto& p : phdrs) {
p.p_offset += offset;
p.p_vaddr += offset;
}
}
// AddInterpreter adds a PT_INTERP segment with the passed contents.
//
// A later call to UpdateOffsets is required to make the new phdr valid.
void AddInterpreter(std::vector<char> contents) {
const int start = data.size();
data.insert(data.end(), contents.begin(), contents.end());
const int size = data.size() - start;
ElfPhdr phdr = {};
phdr.p_type = PT_INTERP;
phdr.p_offset = start;
phdr.p_filesz = size;
phdr.p_memsz = size;
// "If [PT_INTERP] is present, it must precede any loadable segment entry."
phdrs.insert(phdrs.begin(), phdr);
}
// Writes the header, phdrs, and data to fd.
PosixError Write(int fd) const {
int ret = WriteFd(fd, &header, sizeof(header));
if (ret < 0) {
return PosixError(errno, "failed to write header");
} else if (ret != sizeof(header)) {
return PosixError(EIO, absl::StrCat("short write of header: ", ret));
}
for (auto const& p : phdrs) {
ret = WriteFd(fd, &p, sizeof(p));
if (ret < 0) {
return PosixError(errno, "failed to write phdr");
} else if (ret != sizeof(p)) {
return PosixError(EIO, absl::StrCat("short write of phdr: ", ret));
}
}
ret = WriteFd(fd, data.data(), data.size());
if (ret < 0) {
return PosixError(errno, "failed to write data");
} else if (ret != static_cast<int>(data.size())) {
return PosixError(EIO, absl::StrCat("short write of data: ", ret));
}
return NoError();
}
};
// Creates a new temporary executable ELF file in parent with elf as the
// contents.
template <int Size>
PosixErrorOr<TempPath> CreateElfWith(absl::string_view parent,
ElfBinary<Size> const& elf) {
ASSIGN_OR_RETURN_ERRNO(
auto file, TempPath::CreateFileWith(parent, absl::string_view(), 0755));
ASSIGN_OR_RETURN_ERRNO(auto fd, Open(file.path(), O_RDWR));
RETURN_IF_ERRNO(elf.Write(fd.get()));
return std::move(file);
}
// Creates a new temporary executable ELF file with elf as the contents.
template <int Size>
PosixErrorOr<TempPath> CreateElfWith(ElfBinary<Size> const& elf) {
return CreateElfWith(GetAbsoluteTestTmpdir(), elf);
}
// Wait for pid to stop, and assert that it stopped via SIGSTOP.
PosixError WaitStopped(pid_t pid) {
int status;
int ret = RetryEINTR(waitpid)(pid, &status, 0);
MaybeSave();
if (ret < 0) {
return PosixError(errno, "wait failed");
} else if (ret != pid) {
return PosixError(ESRCH, absl::StrCat("wait got ", ret, " want ", pid));
}
if (!WIFSTOPPED(status) || WSTOPSIG(status) != SIGSTOP) {
return PosixError(EINVAL,
absl::StrCat("pid did not SIGSTOP; status = ", status));
}
return NoError();
}
// Returns a valid ELF that PTRACE_TRACEME and SIGSTOPs itself.
//
// UpdateOffsets must be called before writing this ELF.
ElfBinary<64> StandardElf() {
ElfBinary<64> elf;
elf.header.e_ident[EI_MAG0] = ELFMAG0;
elf.header.e_ident[EI_MAG1] = ELFMAG1;
elf.header.e_ident[EI_MAG2] = ELFMAG2;
elf.header.e_ident[EI_MAG3] = ELFMAG3;
elf.header.e_ident[EI_CLASS] = ELFCLASS64;
elf.header.e_ident[EI_DATA] = ELFDATA2LSB;
elf.header.e_ident[EI_VERSION] = EV_CURRENT;
elf.header.e_type = ET_EXEC;
elf.header.e_machine = EM_X86_64;
elf.header.e_version = EV_CURRENT;
elf.header.e_phoff = sizeof(elf.header);
elf.header.e_phentsize = sizeof(decltype(elf)::ElfPhdr);
// TODO(gvisor.dev/issue/153): Always include a PT_GNU_STACK segment to
// disable executable stacks. With this omitted the stack (and all PROT_READ)
// mappings should be executable, but gVisor doesn't support that.
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_GNU_STACK;
phdr.p_flags = PF_R | PF_W;
elf.phdrs.push_back(phdr);
phdr = {};
phdr.p_type = PT_LOAD;
phdr.p_flags = PF_R | PF_X;
phdr.p_offset = 0;
phdr.p_vaddr = 0x40000;
phdr.p_filesz = sizeof(kPtraceCode);
phdr.p_memsz = phdr.p_filesz;
elf.phdrs.push_back(phdr);
elf.header.e_entry = phdr.p_vaddr;
elf.data.assign(kPtraceCode, kPtraceCode + sizeof(kPtraceCode));
return elf;
}
// Test that a trivial binary executes.
TEST(ElfTest, Execute) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
// Ensure it made it to SIGSTOP.
ASSERT_NO_ERRNO(WaitStopped(child));
struct user_regs_struct regs;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
// RIP is just beyond the final syscall instruction.
EXPECT_EQ(regs.rip, elf.header.e_entry + sizeof(kPtraceCode));
EXPECT_THAT(child, ContainsMappings(std::vector<ProcMapsEntry>({
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
file.path().c_str()},
})));
}
// StandardElf without data completes execve, but faults once running.
TEST(ElfTest, MissingText) {
ElfBinary<64> elf = StandardElf();
elf.data.clear();
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
int status;
ASSERT_THAT(RetryEINTR(waitpid)(child, &status, 0),
SyscallSucceedsWithValue(child));
// It runs off the end of the zeroes filling the end of the page.
EXPECT_TRUE(WIFSIGNALED(status) && WTERMSIG(status) == SIGSEGV) << status;
}
// Typical ELF with a data + bss segment
TEST(ElfTest, DataSegment) {
ElfBinary<64> elf = StandardElf();
// Create a standard ELF, but extend to 1.5 pages. The second page will be the
// beginning of a multi-page data + bss segment.
elf.data.resize(kPageSize + kPageSize / 2);
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
phdr.p_flags = PF_R | PF_W;
phdr.p_offset = kPageSize;
phdr.p_vaddr = 0x41000;
phdr.p_filesz = kPageSize / 2;
// The header is going to push vaddr up by a few hundred bytes. Keep p_memsz a
// bit less than 2 pages so this mapping doesn't extend beyond 0x43000.
phdr.p_memsz = 2 * kPageSize - kPageSize / 2;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
EXPECT_THAT(
child, ContainsMappings(std::vector<ProcMapsEntry>({
// text page.
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
file.path().c_str()},
// data + bss page from file.
{0x41000, 0x42000, true, true, false, true, kPageSize, 0, 0, 0,
file.path().c_str()},
// bss page from anon.
{0x42000, 0x43000, true, true, false, true, 0, 0, 0, 0, ""},
})));
}
// Additonal pages beyond filesz are always RW.
//
// N.B. Linux uses set_brk -> vm_brk to additional pages beyond filesz (even
// though start_brk itself will always be beyond memsz). As a result, the
// segment permissions don't apply; the mapping is always RW.
TEST(ElfTest, ExtraMemPages) {
ElfBinary<64> elf = StandardElf();
// Create a standard ELF, but extend to 1.5 pages. The second page will be the
// beginning of a multi-page data + bss segment.
elf.data.resize(kPageSize + kPageSize / 2);
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
// RWX segment. The extra anon page will be RW anyways.
//
// N.B. Linux uses clear_user to clear the end of the file-mapped page, which
// respects the mapping protections. Thus if we map this RO with memsz >
// (unaligned) filesz, then execve will fail with EFAULT. See padzero(elf_bss)
// in fs/binfmt_elf.c:load_elf_binary.
//
// N.N.B.B. The above only applies to the last segment. For earlier segments,
// the clear_user error is ignored.
phdr.p_flags = PF_R | PF_W | PF_X;
phdr.p_offset = kPageSize;
phdr.p_vaddr = 0x41000;
phdr.p_filesz = kPageSize / 2;
// The header is going to push vaddr up by a few hundred bytes. Keep p_memsz a
// bit less than 2 pages so this mapping doesn't extend beyond 0x43000.
phdr.p_memsz = 2 * kPageSize - kPageSize / 2;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
EXPECT_THAT(child,
ContainsMappings(std::vector<ProcMapsEntry>({
// text page.
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
file.path().c_str()},
// data + bss page from file.
{0x41000, 0x42000, true, true, true, true, kPageSize, 0, 0, 0,
file.path().c_str()},
// extra page from anon.
{0x42000, 0x43000, true, true, false, true, 0, 0, 0, 0, ""},
})));
}
// An aligned segment with filesz == 0, memsz > 0 is anon-only.
TEST(ElfTest, AnonOnlySegment) {
ElfBinary<64> elf = StandardElf();
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
// RO segment. The extra anon page will be RW anyways.
phdr.p_flags = PF_R;
phdr.p_offset = 0;
phdr.p_vaddr = 0x41000;
phdr.p_filesz = 0;
phdr.p_memsz = kPageSize - 0xe8;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
// UpdateOffsets adjusts p_vaddr and p_offset by the header size, but we need
// a page-aligned p_vaddr to get a truly anon-only page.
elf.phdrs[2].p_vaddr = 0x41000;
// N.B. p_offset is now unaligned, but Linux doesn't care since this is
// anon-only.
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
EXPECT_THAT(child,
ContainsMappings(std::vector<ProcMapsEntry>({
// text page.
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
file.path().c_str()},
// anon page.
{0x41000, 0x42000, true, true, false, true, 0, 0, 0, 0, ""},
})));
}
// p_offset must have the same alignment as p_vaddr.
TEST(ElfTest, UnalignedOffset) {
ElfBinary<64> elf = StandardElf();
// Unaligned offset.
elf.phdrs[1].p_offset += 1;
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
// execve(2) return EINVAL, but behavior varies between Linux and gVisor.
//
// On Linux, the new mm is committed before attempting to map into it. By the
// time we hit EINVAL in the segment mmap, the old mm is gone. Linux returns
// to an empty mm, which immediately segfaults.
//
// OTOH, gVisor maps into the new mm before committing it. Thus when it hits
// failure, the caller is still intact to receive the error.
if (IsRunningOnGvisor()) {
ASSERT_EQ(execve_errno, EINVAL);
} else {
ASSERT_EQ(execve_errno, 0);
int status;
ASSERT_THAT(RetryEINTR(waitpid)(child, &status, 0),
SyscallSucceedsWithValue(child));
EXPECT_TRUE(WIFSIGNALED(status) && WTERMSIG(status) == SIGSEGV) << status;
}
}
// Linux will allow PT_LOAD segments to overlap.
TEST(ElfTest, DirectlyOverlappingSegments) {
// NOTE(b/37289926): see PIEOutOfOrderSegments.
SKIP_IF(IsRunningOnGvisor());
ElfBinary<64> elf = StandardElf();
// Same as the StandardElf mapping.
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
// Add PF_W so we can differentiate this mapping from the first.
phdr.p_flags = PF_R | PF_W | PF_X;
phdr.p_offset = 0;
phdr.p_vaddr = 0x40000;
phdr.p_filesz = sizeof(kPtraceCode);
phdr.p_memsz = phdr.p_filesz;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
EXPECT_THAT(child, ContainsMappings(std::vector<ProcMapsEntry>({
{0x40000, 0x41000, true, true, true, true, 0, 0, 0, 0,
file.path().c_str()},
})));
}
// Linux allows out-of-order PT_LOAD segments.
TEST(ElfTest, OutOfOrderSegments) {
// NOTE(b/37289926): see PIEOutOfOrderSegments.
SKIP_IF(IsRunningOnGvisor());
ElfBinary<64> elf = StandardElf();
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
phdr.p_flags = PF_R | PF_X;
phdr.p_offset = 0;
phdr.p_vaddr = 0x20000;
phdr.p_filesz = sizeof(kPtraceCode);
phdr.p_memsz = phdr.p_filesz;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
EXPECT_THAT(child, ContainsMappings(std::vector<ProcMapsEntry>({
{0x20000, 0x21000, true, false, true, true, 0, 0, 0, 0,
file.path().c_str()},
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
file.path().c_str()},
})));
}
// header.e_phoff is bound the end of the file.
TEST(ElfTest, OutOfBoundsPhdrs) {
ElfBinary<64> elf = StandardElf();
elf.header.e_phoff = 0x100000;
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
// On Linux 3.11, this caused EIO. On newer Linux, it causes ENOEXEC.
EXPECT_THAT(execve_errno, AnyOf(Eq(ENOEXEC), Eq(EIO)));
}
// Claim there is a phdr beyond the end of the file, but don't include it.
TEST(ElfTest, MissingPhdr) {
ElfBinary<64> elf = StandardElf();
// Clear data so the file ends immediately after the phdrs.
// N.B. Per ElfTest.MissingData, StandardElf without data completes execve
// without error.
elf.data.clear();
elf.UpdateOffsets();
// Claim that there is another phdr just beyond the end of the file. Of
// course, it isn't accessible.
elf.header.e_phnum++;
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
// On Linux 3.11, this caused EIO. On newer Linux, it causes ENOEXEC.
EXPECT_THAT(execve_errno, AnyOf(Eq(ENOEXEC), Eq(EIO)));
}
// No headers at all, just the ELF magic.
TEST(ElfTest, MissingHeader) {
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileMode(0755));
FileDescriptor fd = ASSERT_NO_ERRNO_AND_VALUE(Open(file.path(), O_RDWR));
const char kElfMagic[] = {0x7f, 'E', 'L', 'F'};
ASSERT_THAT(WriteFd(fd.get(), &kElfMagic, sizeof(kElfMagic)),
SyscallSucceeds());
fd.reset();
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, ENOEXEC);
}
// Load a PIE ELF with a data + bss segment.
TEST(ElfTest, PIE) {
ElfBinary<64> elf = StandardElf();
elf.header.e_type = ET_DYN;
// Create a standard ELF, but extend to 1.5 pages. The second page will be the
// beginning of a multi-page data + bss segment.
elf.data.resize(kPageSize + kPageSize / 2);
elf.header.e_entry = 0x0;
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
phdr.p_flags = PF_R | PF_W;
phdr.p_offset = kPageSize;
// Put the data segment at a bit of an offset.
phdr.p_vaddr = 0x20000;
phdr.p_filesz = kPageSize / 2;
// The header is going to push vaddr up by a few hundred bytes. Keep p_memsz a
// bit less than 2 pages so this mapping doesn't extend beyond 0x43000.
phdr.p_memsz = 2 * kPageSize - kPageSize / 2;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
// The first segment really needs to start at 0 for a normal PIE binary, and
// thus includes the headers.
const uint64_t offset = elf.phdrs[1].p_offset;
elf.phdrs[1].p_offset = 0x0;
elf.phdrs[1].p_vaddr = 0x0;
elf.phdrs[1].p_filesz += offset;
elf.phdrs[1].p_memsz += offset;
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
// RIP tells us which page the first segment was loaded into.
struct user_regs_struct regs;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
const uint64_t load_addr = regs.rip & ~(kPageSize - 1);
EXPECT_THAT(child, ContainsMappings(std::vector<ProcMapsEntry>({
// text page.
{load_addr, load_addr + 0x1000, true, false, true,
true, 0, 0, 0, 0, file.path().c_str()},
// data + bss page from file.
{load_addr + 0x20000, load_addr + 0x21000, true, true,
false, true, kPageSize, 0, 0, 0, file.path().c_str()},
// bss page from anon.
{load_addr + 0x21000, load_addr + 0x22000, true, true,
false, true, 0, 0, 0, 0, ""},
})));
}
// PIE binary with a non-zero start address.
//
// This is non-standard for a PIE binary, but valid. The binary is still loaded
// at an arbitrary address, not the first PT_LOAD vaddr.
//
// N.B. Linux changed this behavior in d1fd836dcf00d2028c700c7e44d2c23404062c90.
// Previously, with "randomization" enabled, PIE binaries with a non-zero start
// address would be be loaded at the address they specified because mmap was
// passed the load address, which wasn't 0 as expected.
//
// This change is present in kernel v4.1+.
TEST(ElfTest, PIENonZeroStart) {
// gVisor has the newer behavior.
if (!IsRunningOnGvisor()) {
auto version = ASSERT_NO_ERRNO_AND_VALUE(GetKernelVersion());
SKIP_IF(version.major < 4 || (version.major == 4 && version.minor < 1));
}
ElfBinary<64> elf = StandardElf();
elf.header.e_type = ET_DYN;
// Create a standard ELF, but extend to 1.5 pages. The second page will be the
// beginning of a multi-page data + bss segment.
elf.data.resize(kPageSize + kPageSize / 2);
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
phdr.p_flags = PF_R | PF_W;
phdr.p_offset = kPageSize;
// Put the data segment at a bit of an offset.
phdr.p_vaddr = 0x60000;
phdr.p_filesz = kPageSize / 2;
// The header is going to push vaddr up by a few hundred bytes. Keep p_memsz a
// bit less than 2 pages so this mapping doesn't extend beyond 0x43000.
phdr.p_memsz = 2 * kPageSize - kPageSize / 2;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
// RIP tells us which page the first segment was loaded into.
struct user_regs_struct regs;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
const uint64_t load_addr = regs.rip & ~(kPageSize - 1);
// The ELF is loaded at an arbitrary address, not the first PT_LOAD vaddr.
//
// N.B. this is technically flaky, but Linux is *extremely* unlikely to pick
// this as the start address, as it searches from the top down.
EXPECT_NE(load_addr, 0x40000);
EXPECT_THAT(child, ContainsMappings(std::vector<ProcMapsEntry>({
// text page.
{load_addr, load_addr + 0x1000, true, false, true,
true, 0, 0, 0, 0, file.path().c_str()},
// data + bss page from file.
{load_addr + 0x20000, load_addr + 0x21000, true, true,
false, true, kPageSize, 0, 0, 0, file.path().c_str()},
// bss page from anon.
{load_addr + 0x21000, load_addr + 0x22000, true, true,
false, true, 0, 0, 0, 0, ""},
})));
}
TEST(ElfTest, PIEOutOfOrderSegments) {
// TODO(b/37289926): This triggers a bug in Linux where it computes the size
// of the binary as 0x20000 - 0x40000 = 0xfffffffffffe0000, which obviously
// fails to map.
//
// We test gVisor's behavior (of rejecting the binary) because I assert that
// Linux is wrong and needs to be fixed.
SKIP_IF(!IsRunningOnGvisor());
ElfBinary<64> elf = StandardElf();
elf.header.e_type = ET_DYN;
// Create a standard ELF, but extend to 1.5 pages. The second page will be the
// beginning of a multi-page data + bss segment.
elf.data.resize(kPageSize + kPageSize / 2);
decltype(elf)::ElfPhdr phdr = {};
phdr.p_type = PT_LOAD;
phdr.p_flags = PF_R | PF_W;
phdr.p_offset = kPageSize;
// Put the data segment *before* the first segment.
phdr.p_vaddr = 0x20000;
phdr.p_filesz = kPageSize / 2;
// The header is going to push vaddr up by a few hundred bytes. Keep p_memsz a
// bit less than 2 pages so this mapping doesn't extend beyond 0x43000.
phdr.p_memsz = 2 * kPageSize - kPageSize / 2;
elf.phdrs.push_back(phdr);
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, ENOEXEC);
}
// Standard dynamically linked binary with an ELF interpreter.
TEST(ElfTest, ELFInterpreter) {
ElfBinary<64> interpreter = StandardElf();
interpreter.header.e_type = ET_DYN;
interpreter.header.e_entry = 0x0;
interpreter.UpdateOffsets();
// The first segment really needs to start at 0 for a normal PIE binary, and
// thus includes the headers.
uint64_t const offset = interpreter.phdrs[1].p_offset;
interpreter.phdrs[1].p_offset = 0x0;
interpreter.phdrs[1].p_vaddr = 0x0;
interpreter.phdrs[1].p_filesz += offset;
interpreter.phdrs[1].p_memsz += offset;
TempPath interpreter_file =
ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(interpreter));
ElfBinary<64> binary = StandardElf();
// Append the interpreter path.
int const interp_data_start = binary.data.size();
for (char const c : interpreter_file.path()) {
binary.data.push_back(c);
}
// NUL-terminate.
binary.data.push_back(0);
int const interp_data_size = binary.data.size() - interp_data_start;
decltype(binary)::ElfPhdr phdr = {};
phdr.p_type = PT_INTERP;
phdr.p_offset = interp_data_start;
phdr.p_filesz = interp_data_size;
phdr.p_memsz = interp_data_size;
// "If [PT_INTERP] is present, it must precede any loadable segment entry."
//
// However, Linux allows it anywhere, so we just stick it at the end to make
// sure out-of-order PT_INTERP is OK.
binary.phdrs.push_back(phdr);
binary.UpdateOffsets();
TempPath binary_file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(binary));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(ForkAndExec(
binary_file.path(), {binary_file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
// RIP tells us which page the first segment of the interpreter was loaded
// into.
struct user_regs_struct regs;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
const uint64_t interp_load_addr = regs.rip & ~(kPageSize - 1);
EXPECT_THAT(child,
ContainsMappings(std::vector<ProcMapsEntry>({
// Main binary
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
binary_file.path().c_str()},
// Interpreter
{interp_load_addr, interp_load_addr + 0x1000, true, false,
true, true, 0, 0, 0, 0, interpreter_file.path().c_str()},
})));
}
// Test parameter to ElfInterpterStaticTest cases. The first item is a suffix to
// add to the end of the interpreter path in the PT_INTERP segment and the
// second is the expected execve(2) errno.
using ElfInterpreterStaticParam = std::tuple<std::vector<char>, int>;
class ElfInterpreterStaticTest
: public ::testing::TestWithParam<ElfInterpreterStaticParam> {};
// Statically linked ELF with a statically linked ELF interpreter.
TEST_P(ElfInterpreterStaticTest, Test) {
const std::vector<char> segment_suffix = std::get<0>(GetParam());
const int expected_errno = std::get<1>(GetParam());
ElfBinary<64> interpreter = StandardElf();
interpreter.UpdateOffsets();
TempPath interpreter_file =
ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(interpreter));
ElfBinary<64> binary = StandardElf();
// The PT_LOAD segment conflicts with the interpreter's PT_LOAD segment. The
// interpreter's will be mapped directly over the binary's.
// Interpreter path plus the parameterized suffix in the PT_INTERP segment.
const std::string path = interpreter_file.path();
std::vector<char> segment(path.begin(), path.end());
segment.insert(segment.end(), segment_suffix.begin(), segment_suffix.end());
binary.AddInterpreter(segment);
binary.UpdateOffsets();
TempPath binary_file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(binary));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(ForkAndExec(
binary_file.path(), {binary_file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, expected_errno);
if (expected_errno == 0) {
ASSERT_NO_ERRNO(WaitStopped(child));
EXPECT_THAT(child, ContainsMappings(std::vector<ProcMapsEntry>({
// Interpreter.
{0x40000, 0x41000, true, false, true, true, 0, 0, 0,
0, interpreter_file.path().c_str()},
})));
}
}
INSTANTIATE_TEST_SUITE_P(
Cases, ElfInterpreterStaticTest,
::testing::ValuesIn({
// Simple NUL-terminator to run the interpreter as normal.
std::make_tuple(std::vector<char>({'\0'}), 0),
// Add some garbage to the segment followed by a NUL-terminator. This is
// ignored.
std::make_tuple(std::vector<char>({'\0', 'b', '\0'}), 0),
// Add some garbage to the segment without a NUL-terminator. Linux will
// reject
// this.
std::make_tuple(std::vector<char>({'\0', 'b'}), ENOEXEC),
}));
// Test parameter to ElfInterpterBadPathTest cases. The first item is the
// contents of the PT_INTERP segment and the second is the expected execve(2)
// errno.
using ElfInterpreterBadPathParam = std::tuple<std::vector<char>, int>;
class ElfInterpreterBadPathTest
: public ::testing::TestWithParam<ElfInterpreterBadPathParam> {};
TEST_P(ElfInterpreterBadPathTest, Test) {
const std::vector<char> segment = std::get<0>(GetParam());
const int expected_errno = std::get<1>(GetParam());
ElfBinary<64> binary = StandardElf();
binary.AddInterpreter(segment);
binary.UpdateOffsets();
TempPath binary_file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(binary));
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(ForkAndExec(
binary_file.path(), {binary_file.path()}, {}, nullptr, &execve_errno));
EXPECT_EQ(execve_errno, expected_errno);
}
INSTANTIATE_TEST_SUITE_P(
Cases, ElfInterpreterBadPathTest,
::testing::ValuesIn({
// NUL-terminated fake path in the PT_INTERP segment.
std::make_tuple(std::vector<char>({'/', 'f', '/', 'b', '\0'}), ENOENT),
// ELF interpreter not NUL-terminated.
std::make_tuple(std::vector<char>({'/', 'f', '/', 'b'}), ENOEXEC),
// ELF interpreter path omitted entirely.
//
// fs/binfmt_elf.c:load_elf_binary returns ENOEXEC if p_filesz is < 2
// bytes.
std::make_tuple(std::vector<char>({'\0'}), ENOEXEC),
// ELF interpreter path = "\0".
//
// fs/binfmt_elf.c:load_elf_binary returns ENOEXEC if p_filesz is < 2
// bytes, so add an extra byte to pass that check.
//
// load_elf_binary -> open_exec -> do_open_execat fails to check that
// name != '\0' before calling do_filp_open, which thus opens the
// working directory. do_open_execat returns EACCES because the
// directory is not a regular file.
std::make_tuple(std::vector<char>({'\0', '\0'}), EACCES),
}));
// Relative path to ELF interpreter.
TEST(ElfTest, ELFInterpreterRelative) {
ElfBinary<64> interpreter = StandardElf();
interpreter.header.e_type = ET_DYN;
interpreter.header.e_entry = 0x0;
interpreter.UpdateOffsets();
// The first segment really needs to start at 0 for a normal PIE binary, and
// thus includes the headers.
uint64_t const offset = interpreter.phdrs[1].p_offset;
interpreter.phdrs[1].p_offset = 0x0;
interpreter.phdrs[1].p_vaddr = 0x0;
interpreter.phdrs[1].p_filesz += offset;
interpreter.phdrs[1].p_memsz += offset;
TempPath interpreter_file =
ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(interpreter));
auto cwd = ASSERT_NO_ERRNO_AND_VALUE(GetCWD());
auto interpreter_relative =
ASSERT_NO_ERRNO_AND_VALUE(GetRelativePath(cwd, interpreter_file.path()));
ElfBinary<64> binary = StandardElf();
// NUL-terminated path in the PT_INTERP segment.
std::vector<char> segment(interpreter_relative.begin(),
interpreter_relative.end());
segment.push_back(0);
binary.AddInterpreter(segment);
binary.UpdateOffsets();
TempPath binary_file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(binary));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(ForkAndExec(
binary_file.path(), {binary_file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
// RIP tells us which page the first segment of the interpreter was loaded
// into.
struct user_regs_struct regs;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
const uint64_t interp_load_addr = regs.rip & ~(kPageSize - 1);
EXPECT_THAT(child,
ContainsMappings(std::vector<ProcMapsEntry>({
// Main binary
{0x40000, 0x41000, true, false, true, true, 0, 0, 0, 0,
binary_file.path().c_str()},
// Interpreter
{interp_load_addr, interp_load_addr + 0x1000, true, false,
true, true, 0, 0, 0, 0, interpreter_file.path().c_str()},
})));
}
// ELF interpreter architecture doesn't match the binary.
TEST(ElfTest, ELFInterpreterWrongArch) {
ElfBinary<64> interpreter = StandardElf();
interpreter.header.e_machine = EM_PPC64;
interpreter.header.e_type = ET_DYN;
interpreter.header.e_entry = 0x0;
interpreter.UpdateOffsets();
// The first segment really needs to start at 0 for a normal PIE binary, and
// thus includes the headers.
uint64_t const offset = interpreter.phdrs[1].p_offset;
interpreter.phdrs[1].p_offset = 0x0;
interpreter.phdrs[1].p_vaddr = 0x0;
interpreter.phdrs[1].p_filesz += offset;
interpreter.phdrs[1].p_memsz += offset;
TempPath interpreter_file =
ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(interpreter));
ElfBinary<64> binary = StandardElf();
// NUL-terminated path in the PT_INTERP segment.
const std::string path = interpreter_file.path();
std::vector<char> segment(path.begin(), path.end());
segment.push_back(0);
binary.AddInterpreter(segment);
binary.UpdateOffsets();
TempPath binary_file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(binary));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(ForkAndExec(
binary_file.path(), {binary_file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, ELIBBAD);
}
// No execute permissions on the binary.
TEST(ElfTest, NoExecute) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
ASSERT_THAT(chmod(file.path().c_str(), 0644), SyscallSucceeds());
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, EACCES);
}
// Execute, but no read permissions on the binary works just fine.
TEST(ElfTest, NoRead) {
// TODO(gvisor.dev/issue/160): gVisor's backing filesystem may prevent the
// sentry from reading the executable.
SKIP_IF(IsRunningOnGvisor());
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
ASSERT_THAT(chmod(file.path().c_str(), 0111), SyscallSucceeds());
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
ASSERT_NO_ERRNO(WaitStopped(child));
// TODO(gvisor.dev/issue/160): A task with a non-readable executable is marked
// non-dumpable, preventing access to proc files. gVisor does not implement
// this behavior.
}
// No execute permissions on the ELF interpreter.
TEST(ElfTest, ElfInterpreterNoExecute) {
ElfBinary<64> interpreter = StandardElf();
interpreter.header.e_type = ET_DYN;
interpreter.header.e_entry = 0x0;
interpreter.UpdateOffsets();
// The first segment really needs to start at 0 for a normal PIE binary, and
// thus includes the headers.
uint64_t const offset = interpreter.phdrs[1].p_offset;
interpreter.phdrs[1].p_offset = 0x0;
interpreter.phdrs[1].p_vaddr = 0x0;
interpreter.phdrs[1].p_filesz += offset;
interpreter.phdrs[1].p_memsz += offset;
TempPath interpreter_file =
ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(interpreter));
ElfBinary<64> binary = StandardElf();
// NUL-terminated path in the PT_INTERP segment.
const std::string path = interpreter_file.path();
std::vector<char> segment(path.begin(), path.end());
segment.push_back(0);
binary.AddInterpreter(segment);
binary.UpdateOffsets();
TempPath binary_file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(binary));
ASSERT_THAT(chmod(interpreter_file.path().c_str(), 0644), SyscallSucceeds());
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(interpreter_file.path(), {interpreter_file.path()}, {},
&child, &execve_errno));
EXPECT_EQ(execve_errno, EACCES);
}
// Execute a basic interpreter script.
TEST(InterpreterScriptTest, Execute) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!", binary.path()), 0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
EXPECT_NO_ERRNO(WaitStopped(child));
}
// Whitespace after #!.
TEST(InterpreterScriptTest, Whitespace) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#! \t \t", binary.path()), 0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
EXPECT_NO_ERRNO(WaitStopped(child));
}
// Interpreter script is missing execute permission.
TEST(InterpreterScriptTest, InterpreterScriptNoExecute) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!", binary.path()), 0644));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, EACCES);
}
// Binary interpreter script refers to is missing execute permission.
TEST(InterpreterScriptTest, BinaryNoExecute) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
ASSERT_THAT(chmod(binary.path().c_str(), 0644), SyscallSucceeds());
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!", binary.path()), 0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, EACCES);
}
// Linux will load interpreter scripts five levels deep, but no more.
TEST(InterpreterScriptTest, MaxRecursion) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
TempPath script1 = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
"/tmp", absl::StrCat("#!", binary.path()), 0755));
TempPath script2 = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
"/tmp", absl::StrCat("#!", script1.path()), 0755));
TempPath script3 = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
"/tmp", absl::StrCat("#!", script2.path()), 0755));
TempPath script4 = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
"/tmp", absl::StrCat("#!", script3.path()), 0755));
TempPath script5 = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
"/tmp", absl::StrCat("#!", script4.path()), 0755));
TempPath script6 = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
"/tmp", absl::StrCat("#!", script5.path()), 0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script6.path(), {script6.path()}, {}, &child, &execve_errno));
// Too many levels of recursion.
EXPECT_EQ(execve_errno, ELOOP);
// The next level up is OK.
auto cleanup2 = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script5.path(), {script5.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
EXPECT_NO_ERRNO(WaitStopped(child));
}
// Interpreter script with a relative path.
TEST(InterpreterScriptTest, RelativePath) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
auto cwd = ASSERT_NO_ERRNO_AND_VALUE(GetCWD());
auto binary_relative =
ASSERT_NO_ERRNO_AND_VALUE(GetRelativePath(cwd, binary.path()));
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!", binary_relative), 0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
EXPECT_NO_ERRNO(WaitStopped(child));
}
// Interpreter script with .. in a path component.
TEST(InterpreterScriptTest, UncleanPath) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!/tmp/../", binary.path()),
0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
EXPECT_NO_ERRNO(WaitStopped(child));
}
// Passed interpreter script is a symlink.
TEST(InterpreterScriptTest, Symlink) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
// Use /tmp explicitly to ensure the path is short enough.
TempPath binary = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith("/tmp", elf));
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!", binary.path()), 0755));
TempPath link = ASSERT_NO_ERRNO_AND_VALUE(
TempPath::CreateSymlinkTo(GetAbsoluteTestTmpdir(), script.path()));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(link.path(), {link.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
EXPECT_NO_ERRNO(WaitStopped(child));
}
// Interpreter script points to a symlink loop.
TEST(InterpreterScriptTest, SymlinkLoop) {
std::string const link1 = NewTempAbsPathInDir("/tmp");
std::string const link2 = NewTempAbsPathInDir("/tmp");
ASSERT_THAT(symlink(link2.c_str(), link1.c_str()), SyscallSucceeds());
auto remove_link1 = Cleanup(
[&link1] { EXPECT_THAT(unlink(link1.c_str()), SyscallSucceeds()); });
ASSERT_THAT(symlink(link1.c_str(), link2.c_str()), SyscallSucceeds());
auto remove_link2 = Cleanup(
[&link2] { EXPECT_THAT(unlink(link2.c_str()), SyscallSucceeds()); });
TempPath script = ASSERT_NO_ERRNO_AND_VALUE(TempPath::CreateFileWith(
GetAbsoluteTestTmpdir(), absl::StrCat("#!", link1), 0755));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(script.path(), {script.path()}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, ELOOP);
}
// Binary is a symlink loop.
TEST(ExecveTest, SymlinkLoop) {
std::string const link1 = NewTempAbsPathInDir("/tmp");
std::string const link2 = NewTempAbsPathInDir("/tmp");
ASSERT_THAT(symlink(link2.c_str(), link1.c_str()), SyscallSucceeds());
auto remove_link = Cleanup(
[&link1] { EXPECT_THAT(unlink(link1.c_str()), SyscallSucceeds()); });
ASSERT_THAT(symlink(link1.c_str(), link2.c_str()), SyscallSucceeds());
auto remove_link2 = Cleanup(
[&link2] { EXPECT_THAT(unlink(link2.c_str()), SyscallSucceeds()); });
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(link1, {link1}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, ELOOP);
}
// Binary is a directory.
TEST(ExecveTest, Directory) {
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec("/tmp", {"/tmp"}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, EACCES);
}
// Pass a valid binary as a directory (extra / on the end).
TEST(ExecveTest, BinaryAsDirectory) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
std::string const path = absl::StrCat(file.path(), "/");
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(path, {path}, {}, &child, &execve_errno));
EXPECT_EQ(execve_errno, ENOTDIR);
}
// The initial brk value is after the page at the end of the binary.
TEST(ExecveTest, BrkAfterBinary) {
ElfBinary<64> elf = StandardElf();
elf.UpdateOffsets();
TempPath file = ASSERT_NO_ERRNO_AND_VALUE(CreateElfWith(elf));
pid_t child;
int execve_errno;
auto cleanup = ASSERT_NO_ERRNO_AND_VALUE(
ForkAndExec(file.path(), {file.path()}, {}, &child, &execve_errno));
ASSERT_EQ(execve_errno, 0);
// Ensure it made it to SIGSTOP.
ASSERT_NO_ERRNO(WaitStopped(child));
struct user_regs_struct regs;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
// RIP is just beyond the final syscall instruction. Rewind to execute a brk
// syscall.
regs.rip -= kSyscallSize;
regs.rax = __NR_brk;
regs.rdi = 0;
ASSERT_THAT(ptrace(PTRACE_SETREGS, child, 0, ®s), SyscallSucceeds());
// Resume the child, waiting for syscall entry.
ASSERT_THAT(ptrace(PTRACE_SYSCALL, child, 0, 0), SyscallSucceeds());
int status;
ASSERT_THAT(RetryEINTR(waitpid)(child, &status, 0),
SyscallSucceedsWithValue(child));
ASSERT_TRUE(WIFSTOPPED(status) && WSTOPSIG(status) == SIGTRAP)
<< "status = " << status;
// Execute the syscall.
ASSERT_THAT(ptrace(PTRACE_SYSCALL, child, 0, 0), SyscallSucceeds());
ASSERT_THAT(RetryEINTR(waitpid)(child, &status, 0),
SyscallSucceedsWithValue(child));
ASSERT_TRUE(WIFSTOPPED(status) && WSTOPSIG(status) == SIGTRAP)
<< "status = " << status;
ASSERT_THAT(ptrace(PTRACE_GETREGS, child, 0, ®s), SyscallSucceeds());
// brk is after the text page.
//
// The kernel does brk randomization, so we can't be sure what the exact
// address will be, but it is always beyond the final page in the binary.
// i.e., it does not start immediately after memsz in the middle of a page.
// Userspace may expect to use that space.
EXPECT_GE(regs.rax, 0x41000);
}
} // namespace
} // namespace testing
} // namespace gvisor
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