// Copyright 2019 Google LLC // // 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 // // https://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 #include #include #include #include "sandboxed_api/util/flag.h" #include "absl/memory/memory.h" #include "absl/status/status.h" #include "absl/strings/str_cat.h" #include "sandboxed_api/examples/sum/sandbox.h" #include "sandboxed_api/examples/sum/sum-sapi.sapi.h" #include "sandboxed_api/examples/sum/sum_params.pb.h" #include "sandboxed_api/transaction.h" #include "sandboxed_api/vars.h" namespace { class SumParams : public sapi::v::Struct {}; class SumTransaction : public sapi::Transaction { public: SumTransaction(std::unique_ptr sandbox, bool crash, bool violate, bool time_out) : sapi::Transaction(std::move(sandbox)), crash_(crash), violate_(violate), time_out_(time_out) { sapi::Transaction::SetTimeLimit(kTimeOutVal); } private: // Default timeout value for each transaction run. const time_t kTimeOutVal = 2; // Should the sandboxee crash at some point? bool crash_; // Should the sandboxee invoke a disallowed syscall? bool violate_; // Should the sandboxee time_out_? bool time_out_; // The main processing function. absl::Status Main() override; }; absl::Status SumTransaction::Main() { SumApi f(sandbox()); SAPI_ASSIGN_OR_RETURN(int v, f.sum(1000, 337)); LOG(INFO) << "1000 + 337 = " << v; TRANSACTION_FAIL_IF_NOT(v == 1337, "1000 + 337 != 1337"); // Sums two int's held in a structure. SumParams params; params.mutable_data()->a = 1111; params.mutable_data()->b = 222; params.mutable_data()->ret = 0; SAPI_RETURN_IF_ERROR(f.sums(params.PtrBoth())); LOG(INFO) << "1111 + 222 = " << params.data().ret; TRANSACTION_FAIL_IF_NOT(params.data().ret == 1333, "1111 + 222 != 1333"); params.mutable_data()->b = -1000; SAPI_RETURN_IF_ERROR(f.sums(params.PtrBoth())); LOG(INFO) << "1111 - 1000 = " << params.data().ret; TRANSACTION_FAIL_IF_NOT(params.data().ret == 111, "1111 - 1000 != 111"); // Without the wrapper class for struct. sapi::v::Struct p; p.mutable_data()->a = 1234; p.mutable_data()->b = 5678; p.mutable_data()->ret = 0; SAPI_RETURN_IF_ERROR(f.sums(p.PtrBoth())); LOG(INFO) << "1234 + 5678 = " << p.data().ret; TRANSACTION_FAIL_IF_NOT(p.data().ret == 6912, "1234 + 5678 != 6912"); // Gets symbol address and prints its value. int* ssaddr; SAPI_RETURN_IF_ERROR( sandbox()->Symbol("sumsymbol", reinterpret_cast(&ssaddr))); sapi::v::Int sumsymbol; sumsymbol.SetRemote(ssaddr); SAPI_RETURN_IF_ERROR(sandbox()->TransferFromSandboxee(&sumsymbol)); LOG(INFO) << "sumsymbol value (exp: 5): " << sumsymbol.GetValue() << ", address: " << ssaddr; TRANSACTION_FAIL_IF_NOT(sumsymbol.GetValue() == 5, "sumsymbol.GetValue() != 5"); // Sums all int's inside an array. int arr[10]; sapi::v::Array iarr(arr, ABSL_ARRAYSIZE(arr)); for (size_t i = 0; i < ABSL_ARRAYSIZE(arr); i++) { iarr[i] = i; } SAPI_ASSIGN_OR_RETURN(v, f.sumarr(iarr.PtrBefore(), iarr.GetNElem())); LOG(INFO) << "Sum(iarr, 10 elem, from 0 to 9, exp: 45) = " << v; TRANSACTION_FAIL_IF_NOT(v == 45, "Sum(iarr, 10 elem, from 0 to 9) != 45"); float a = 0.99999f; double b = 1.5423432l; long double c = 1.1001L; SAPI_ASSIGN_OR_RETURN(long double r, f.addf(a, b, c)); LOG(INFO) << "Addf(" << a << ", " << b << ", " << c << ") = " << r; // TODO(szwl): floating point comparison. // Prints "Hello World!!!" via puts() const char hwstr[] = "Hello World!!!"; LOG(INFO) << "Print: '" << hwstr << "' via puts()"; sapi::v::Array hwarr(hwstr, sizeof(hwstr)); sapi::v::Int ret; SAPI_RETURN_IF_ERROR(sandbox()->Call("puts", &ret, hwarr.PtrBefore())); TRANSACTION_FAIL_IF_NOT(ret.GetValue() == 15, "puts('Hello World!!!') != 15"); sapi::v::Int vp; sapi::v::NullPtr nptr; LOG(INFO) << "Test whether pointer is NOT NULL - new pointers"; SAPI_RETURN_IF_ERROR(f.testptr(vp.PtrBefore())); LOG(INFO) << "Test whether pointer is NULL"; SAPI_RETURN_IF_ERROR(f.testptr(&nptr)); // Protobuf test. sumsapi::SumParamsProto proto; proto.set_a(10); proto.set_b(20); proto.set_c(30); auto pp = sapi::v::Proto::FromMessage(proto); if (!pp.ok()) { return pp.status(); } SAPI_ASSIGN_OR_RETURN(v, f.sumproto(pp->PtrBefore())); LOG(INFO) << "sumproto(proto {a = 10; b = 20; c = 30}) = " << v; TRANSACTION_FAIL_IF_NOT(v == 60, "sumproto(proto {a = 10; b = 20; c = 30}) != 60"); // Fd transfer test. int fdesc = open("/proc/self/exe", O_RDONLY); sapi::v::Fd fd(fdesc); SAPI_RETURN_IF_ERROR(sandbox()->TransferToSandboxee(&fd)); LOG(INFO) << "remote_fd = " << fd.GetRemoteFd(); TRANSACTION_FAIL_IF_NOT(fd.GetRemoteFd() == 3, "remote_fd != 3"); fdesc = open("/proc/self/comm", O_RDONLY); sapi::v::Fd fd2(fdesc); SAPI_RETURN_IF_ERROR(sandbox()->TransferToSandboxee(&fd2)); LOG(INFO) << "remote_fd2 = " << fd2.GetRemoteFd(); TRANSACTION_FAIL_IF_NOT(fd2.GetRemoteFd() == 4, "remote_fd2 != 4"); // Read from fd test. char buffer[1024] = {0}; sapi::v::Array buf(buffer, sizeof(buffer)); sapi::v::UInt size(128); SAPI_RETURN_IF_ERROR( sandbox()->Call("read", &ret, &fd2, buf.PtrBoth(), &size)); LOG(INFO) << "Read from /proc/self/comm = [" << buffer << "]"; // Close test. SAPI_RETURN_IF_ERROR(fd2.CloseRemoteFd(sandbox()->rpc_channel())); memset(buffer, 0, sizeof(buffer)); SAPI_RETURN_IF_ERROR( sandbox()->Call("read", &ret, &fd2, buf.PtrBoth(), &size)); LOG(INFO) << "Read from closed /proc/self/comm = [" << buffer << "]"; // Pass fd as function arg example. fdesc = open("/proc/self/statm", O_RDONLY); sapi::v::Fd fd3(fdesc); SAPI_RETURN_IF_ERROR(sandbox()->TransferToSandboxee(&fd3)); SAPI_ASSIGN_OR_RETURN(int r2, f.read_int(fd3.GetRemoteFd())); LOG(INFO) << "statm value (should not be 0) = " << r2; if (crash_) { // Crashes the sandboxed part with SIGSEGV LOG(INFO) << "Crash with SIGSEGV"; SAPI_RETURN_IF_ERROR(f.crash()); } if (violate_) { LOG(INFO) << "Cause a sandbox (syscall) violation"; SAPI_RETURN_IF_ERROR(f.violate()); } if (time_out_) { SAPI_RETURN_IF_ERROR(f.sleep_for_sec(kTimeOutVal * 2)); } return absl::OkStatus(); } absl::Status test_addition(sapi::Sandbox* sandbox, int a, int b, int c) { SumApi f(sandbox); SAPI_ASSIGN_OR_RETURN(int v, f.sum(a, b)); TRANSACTION_FAIL_IF_NOT(v == c, absl::StrCat(a, " + ", b, " != ", c)); return absl::OkStatus(); } } // namespace int main(int argc, char** argv) { gflags::ParseCommandLineFlags(&argc, &argv, true); google::InitGoogleLogging(argv[0]); absl::Status status; sapi::BasicTransaction st{absl::make_unique()}; // Using the simple transaction (and function pointers): CHECK(st.Run(test_addition, 1, 1, 2).ok()); CHECK(st.Run(test_addition, 1336, 1, 1337).ok()); CHECK(st.Run(test_addition, 1336, 1, 7).code() == absl::StatusCode::kFailedPrecondition); status = st.Run([](sapi::Sandbox* sandbox) -> absl::Status { SumApi f(sandbox); // Sums two int's held in a structure. SumParams params; params.mutable_data()->a = 1111; params.mutable_data()->b = 222; params.mutable_data()->ret = 0; SAPI_RETURN_IF_ERROR(f.sums(params.PtrBoth())); LOG(INFO) << "1111 + 222 = " << params.data().ret; TRANSACTION_FAIL_IF_NOT(params.data().ret == 1333, "1111 + 222 != 1333"); return absl::OkStatus(); }); CHECK(status.ok()) << status.message(); status = st.Run([](sapi::Sandbox* sandbox) -> absl::Status { SumApi f(sandbox); SumParams params; params.mutable_data()->a = 1111; params.mutable_data()->b = -1000; params.mutable_data()->ret = 0; SAPI_RETURN_IF_ERROR(f.sums(params.PtrBoth())); LOG(INFO) << "1111 - 1000 = " << params.data().ret; TRANSACTION_FAIL_IF_NOT(params.data().ret == 111, "1111 - 1000 != 111"); // Without the wrapper class for struct. sapi::v::Struct p; p.mutable_data()->a = 1234; p.mutable_data()->b = 5678; p.mutable_data()->ret = 0; SAPI_RETURN_IF_ERROR(f.sums(p.PtrBoth())); LOG(INFO) << "1234 + 5678 = " << p.data().ret; TRANSACTION_FAIL_IF_NOT(p.data().ret == 6912, "1234 + 5678 != 6912"); return absl::OkStatus(); }); CHECK(status.ok()) << status.message(); // Using overloaded transaction class: SumTransaction sapi_crash{absl::make_unique(), /*crash=*/true, /*violate=*/false, /*time_out=*/false}; status = sapi_crash.Run(); LOG(INFO) << "Final run result for crash: " << status; CHECK(status.code() == absl::StatusCode::kUnavailable); SumTransaction sapi_violate{absl::make_unique(), /*crash=*/false, /*violate=*/true, /*time_out=*/false}; status = sapi_violate.Run(); LOG(INFO) << "Final run result for violate: " << status; CHECK(status.code() == absl::StatusCode::kUnavailable); SumTransaction sapi_timeout{absl::make_unique(), /*crash=*/false, /*violate=*/false, /*time_out=*/true}; status = sapi_timeout.Run(); LOG(INFO) << "Final run result for timeout: " << status; CHECK(status.code() == absl::StatusCode::kUnavailable); SumTransaction sapi{absl::make_unique(), /*crash=*/false, /*violate=*/false, /*time_out=*/false}; for (int i = 0; i < 32; ++i) { status = sapi.Run(); LOG(INFO) << "Final run result for not a crash: " << status.message(); CHECK(status.ok()); } return 0; }