/* Copyright (c) 2015, Google Inc. * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ package main import ( "bufio" "bytes" "encoding/json" "errors" "flag" "fmt" "math/rand" "os" "os/exec" "path" "runtime" "strconv" "strings" "sync" "syscall" "boringssl.googlesource.com/boringssl/util/testresult" ) // TODO(davidben): Link tests with the malloc shim and port -malloc-test to this runner. var ( useValgrind = flag.Bool("valgrind", false, "If true, run code under valgrind") useCallgrind = flag.Bool("callgrind", false, "If true, run code under valgrind to generate callgrind traces.") useGDB = flag.Bool("gdb", false, "If true, run BoringSSL code under gdb") useSDE = flag.Bool("sde", false, "If true, run BoringSSL code under Intel's SDE for each supported chip") sdePath = flag.String("sde-path", "sde", "The path to find the sde binary.") buildDir = flag.String("build-dir", "build", "The build directory to run the tests from.") numWorkers = flag.Int("num-workers", runtime.NumCPU(), "Runs the given number of workers when testing.") jsonOutput = flag.String("json-output", "", "The file to output JSON results to.") mallocTest = flag.Int64("malloc-test", -1, "If non-negative, run each test with each malloc in turn failing from the given number onwards.") mallocTestDebug = flag.Bool("malloc-test-debug", false, "If true, ask each test to abort rather than fail a malloc. This can be used with a specific value for --malloc-test to identity the malloc failing that is causing problems.") simulateARMCPUs = flag.Bool("simulate-arm-cpus", simulateARMCPUsDefault(), "If true, runs tests simulating different ARM CPUs.") ) func simulateARMCPUsDefault() bool { return runtime.GOOS == "linux" && (runtime.GOARCH == "arm" || runtime.GOARCH == "arm64") } type test struct { args []string shard, numShards int // cpu, if not empty, contains a code to simulate. For SDE, run `sde64 // -help` to get a list of these codes. For ARM, see gtest_main.cc for // the supported values. cpu string } type result struct { Test test Passed bool Error error } // sdeCPUs contains a list of CPU code that we run all tests under when *useSDE // is true. var sdeCPUs = []string{ "p4p", // Pentium4 Prescott "mrm", // Merom "pnr", // Penryn "nhm", // Nehalem "wsm", // Westmere "snb", // Sandy Bridge "ivb", // Ivy Bridge "hsw", // Haswell "bdw", // Broadwell "skx", // Skylake Server "skl", // Skylake Client "cnl", // Cannonlake "knl", // Knights Landing "slt", // Saltwell "slm", // Silvermont "glm", // Goldmont "knm", // Knights Mill } var armCPUs = []string{ "none", // No support for any ARM extensions. "neon", // Support for NEON. "crypto", // Support for NEON and crypto extensions. } func valgrindOf(dbAttach bool, path string, args ...string) *exec.Cmd { valgrindArgs := []string{"--error-exitcode=99", "--track-origins=yes", "--leak-check=full", "--quiet"} if dbAttach { valgrindArgs = append(valgrindArgs, "--db-attach=yes", "--db-command=xterm -e gdb -nw %f %p") } valgrindArgs = append(valgrindArgs, path) valgrindArgs = append(valgrindArgs, args...) return exec.Command("valgrind", valgrindArgs...) } func callgrindOf(path string, args ...string) *exec.Cmd { valgrindArgs := []string{"-q", "--tool=callgrind", "--dump-instr=yes", "--collect-jumps=yes", "--callgrind-out-file=" + *buildDir + "/callgrind/callgrind.out.%p"} valgrindArgs = append(valgrindArgs, path) valgrindArgs = append(valgrindArgs, args...) return exec.Command("valgrind", valgrindArgs...) } func gdbOf(path string, args ...string) *exec.Cmd { xtermArgs := []string{"-e", "gdb", "--args"} xtermArgs = append(xtermArgs, path) xtermArgs = append(xtermArgs, args...) return exec.Command("xterm", xtermArgs...) } func sdeOf(cpu, path string, args ...string) *exec.Cmd { sdeArgs := []string{"-" + cpu} // The kernel's vdso code for gettimeofday sometimes uses the RDTSCP // instruction. Although SDE has a -chip_check_vsyscall flag that // excludes such code by default, it does not seem to work. Instead, // pass the -chip_check_exe_only flag which retains test coverage when // statically linked and excludes the vdso. if cpu == "p4p" || cpu == "pnr" || cpu == "mrm" || cpu == "slt" { sdeArgs = append(sdeArgs, "-chip_check_exe_only") } sdeArgs = append(sdeArgs, "--", path) sdeArgs = append(sdeArgs, args...) return exec.Command(*sdePath, sdeArgs...) } var ( errMoreMallocs = errors.New("child process did not exhaust all allocation calls") errTestSkipped = errors.New("test was skipped") ) func runTestOnce(test test, mallocNumToFail int64) (passed bool, err error) { prog := path.Join(*buildDir, test.args[0]) args := append([]string{}, test.args[1:]...) if *simulateARMCPUs && test.cpu != "" { args = append(args, "--cpu=" + test.cpu) } if *useSDE { // SDE is neither compatible with the unwind tester nor automatically // detected. args = append(args, "--no_unwind_tests") } var cmd *exec.Cmd if *useValgrind { cmd = valgrindOf(false, prog, args...) } else if *useCallgrind { cmd = callgrindOf(prog, args...) } else if *useGDB { cmd = gdbOf(prog, args...) } else if *useSDE { cmd = sdeOf(test.cpu, prog, args...) } else { cmd = exec.Command(prog, args...) } var outBuf bytes.Buffer cmd.Stdout = &outBuf cmd.Stderr = &outBuf if mallocNumToFail >= 0 { cmd.Env = os.Environ() cmd.Env = append(cmd.Env, "MALLOC_NUMBER_TO_FAIL="+strconv.FormatInt(mallocNumToFail, 10)) if *mallocTestDebug { cmd.Env = append(cmd.Env, "MALLOC_ABORT_ON_FAIL=1") } cmd.Env = append(cmd.Env, "_MALLOC_CHECK=1") } if err := cmd.Start(); err != nil { return false, err } if err := cmd.Wait(); err != nil { if exitError, ok := err.(*exec.ExitError); ok { switch exitError.Sys().(syscall.WaitStatus).ExitStatus() { case 88: return false, errMoreMallocs case 89: fmt.Print(string(outBuf.Bytes())) return false, errTestSkipped } } fmt.Print(string(outBuf.Bytes())) return false, err } // Account for Windows line-endings. stdout := bytes.Replace(outBuf.Bytes(), []byte("\r\n"), []byte("\n"), -1) if bytes.HasSuffix(stdout, []byte("PASS\n")) && (len(stdout) == 5 || stdout[len(stdout)-6] == '\n') { return true, nil } // Also accept a googletest-style pass line. This is left here in // transition until the tests are all converted and this script made // unnecessary. if bytes.Contains(stdout, []byte("\n[ PASSED ]")) { return true, nil } fmt.Print(string(outBuf.Bytes())) return false, nil } func runTest(test test) (bool, error) { if *mallocTest < 0 { return runTestOnce(test, -1) } for mallocNumToFail := int64(*mallocTest); ; mallocNumToFail++ { if passed, err := runTestOnce(test, mallocNumToFail); err != errMoreMallocs { if err != nil { err = fmt.Errorf("at malloc %d: %s", mallocNumToFail, err) } return passed, err } } } // setWorkingDirectory walks up directories as needed until the current working // directory is the top of a BoringSSL checkout. func setWorkingDirectory() { for i := 0; i < 64; i++ { if _, err := os.Stat("BUILDING.md"); err == nil { return } os.Chdir("..") } panic("Couldn't find BUILDING.md in a parent directory!") } func parseTestConfig(filename string) ([]test, error) { in, err := os.Open(filename) if err != nil { return nil, err } defer in.Close() decoder := json.NewDecoder(in) var testArgs [][]string if err := decoder.Decode(&testArgs); err != nil { return nil, err } var result []test for _, args := range testArgs { result = append(result, test{args: args}) } return result, nil } func worker(tests <-chan test, results chan<- result, done *sync.WaitGroup) { defer done.Done() for test := range tests { passed, err := runTest(test) results <- result{test, passed, err} } } func (t test) shortName() string { return t.args[0] + t.shardMsg() + t.cpuMsg() } func (t test) longName() string { return strings.Join(t.args, " ") + t.cpuMsg() } func (t test) shardMsg() string { if t.numShards == 0 { return "" } return fmt.Sprintf(" [shard %d/%d]", t.shard+1, t.numShards) } func (t test) cpuMsg() string { if len(t.cpu) == 0 { return "" } return fmt.Sprintf(" (for CPU %q)", t.cpu) } func (t test) getGTestShards() ([]test, error) { if *numWorkers == 1 || len(t.args) != 1 { return []test{t}, nil } // Only shard the three GTest-based tests. if t.args[0] != "crypto/crypto_test" && t.args[0] != "ssl/ssl_test" && t.args[0] != "decrepit/decrepit_test" { return []test{t}, nil } prog := path.Join(*buildDir, t.args[0]) cmd := exec.Command(prog, "--gtest_list_tests") var stdout bytes.Buffer cmd.Stdout = &stdout if err := cmd.Start(); err != nil { return nil, err } if err := cmd.Wait(); err != nil { return nil, err } var group string var tests []string scanner := bufio.NewScanner(&stdout) for scanner.Scan() { line := scanner.Text() // Remove the parameter comment and trailing space. if idx := strings.Index(line, "#"); idx >= 0 { line = line[:idx] } line = strings.TrimSpace(line) if len(line) == 0 { continue } if line[len(line)-1] == '.' { group = line continue } if len(group) == 0 { return nil, fmt.Errorf("found test case %q without group", line) } tests = append(tests, group+line) } const testsPerShard = 20 if len(tests) <= testsPerShard { return []test{t}, nil } // Slow tests which process large test vector files tend to be grouped // together, so shuffle the order. shuffled := make([]string, len(tests)) perm := rand.Perm(len(tests)) for i, j := range perm { shuffled[i] = tests[j] } var shards []test for i := 0; i < len(shuffled); i += testsPerShard { n := len(shuffled) - i if n > testsPerShard { n = testsPerShard } shard := t shard.args = []string{shard.args[0], "--gtest_filter=" + strings.Join(shuffled[i:i+n], ":")} shard.shard = len(shards) shards = append(shards, shard) } for i := range shards { shards[i].numShards = len(shards) } return shards, nil } func main() { flag.Parse() setWorkingDirectory() testCases, err := parseTestConfig("util/all_tests.json") if err != nil { fmt.Printf("Failed to parse input: %s\n", err) os.Exit(1) } var wg sync.WaitGroup tests := make(chan test, *numWorkers) results := make(chan result, *numWorkers) for i := 0; i < *numWorkers; i++ { wg.Add(1) go worker(tests, results, &wg) } go func() { for _, test := range testCases { if *useSDE { // SDE generates plenty of tasks and gets slower // with additional sharding. for _, cpu := range sdeCPUs { testForCPU := test testForCPU.cpu = cpu tests <- testForCPU } } else if *simulateARMCPUs { // This mode is run instead of the default path, // so also include the native flow. tests <- test for _, cpu := range armCPUs { testForCPU := test testForCPU.cpu = cpu tests <- testForCPU } } else { shards, err := test.getGTestShards() if err != nil { fmt.Printf("Error listing tests: %s\n", err) os.Exit(1) } for _, shard := range shards { tests <- shard } } } close(tests) wg.Wait() close(results) }() testOutput := testresult.NewResults() var failed, skipped []test for testResult := range results { test := testResult.Test args := test.args if testResult.Error == errTestSkipped { fmt.Printf("%s\n", test.longName()) fmt.Printf("%s was skipped\n", args[0]) skipped = append(skipped, test) testOutput.AddSkip(test.longName()) } else if testResult.Error != nil { fmt.Printf("%s\n", test.longName()) fmt.Printf("%s failed to complete: %s\n", args[0], testResult.Error) failed = append(failed, test) testOutput.AddResult(test.longName(), "CRASH") } else if !testResult.Passed { fmt.Printf("%s\n", test.longName()) fmt.Printf("%s failed to print PASS on the last line.\n", args[0]) failed = append(failed, test) testOutput.AddResult(test.longName(), "FAIL") } else { fmt.Printf("%s\n", test.shortName()) testOutput.AddResult(test.longName(), "PASS") } } if *jsonOutput != "" { if err := testOutput.WriteToFile(*jsonOutput); err != nil { fmt.Fprintf(os.Stderr, "Error: %s\n", err) } } if len(skipped) > 0 { fmt.Printf("\n%d of %d tests were skipped:\n", len(skipped), len(testCases)) for _, test := range skipped { fmt.Printf("\t%s%s\n", strings.Join(test.args, " "), test.cpuMsg()) } } if len(failed) > 0 { fmt.Printf("\n%d of %d tests failed:\n", len(failed), len(testCases)) for _, test := range failed { fmt.Printf("\t%s%s\n", strings.Join(test.args, " "), test.cpuMsg()) } os.Exit(1) } fmt.Printf("\nAll tests passed!\n") }