/* * Copyright (C) 2015 The Android Open Source Project * * 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. */ #ifndef ART_CMDLINE_CMDLINE_TYPES_H_ #define ART_CMDLINE_CMDLINE_TYPES_H_ #define CMDLINE_NDEBUG 1 // Do not output any debugging information for parsing. #include "memory_representation.h" #include "detail/cmdline_debug_detail.h" #include "cmdline_type_parser.h" // Includes for the types that are being specialized #include <string> #include "unit.h" #include "jdwp/jdwp.h" #include "base/logging.h" #include "base/time_utils.h" #include "experimental_flags.h" #include "gc/collector_type.h" #include "gc/space/large_object_space.h" #include "profiler_options.h" namespace art { // The default specialization will always fail parsing the type from a string. // Provide your own specialization that inherits from CmdlineTypeParser<T> // and implements either Parse or ParseAndAppend // (only if the argument was defined with ::AppendValues()) but not both. template <typename T> struct CmdlineType : CmdlineTypeParser<T> { }; // Specializations for CmdlineType<T> follow: // Parse argument definitions for Unit-typed arguments. template <> struct CmdlineType<Unit> : CmdlineTypeParser<Unit> { Result Parse(const std::string& args) { if (args == "") { return Result::Success(Unit{}); // NOLINT [whitespace/braces] [5] } return Result::Failure("Unexpected extra characters " + args); } }; template <> struct CmdlineType<JDWP::JdwpOptions> : CmdlineTypeParser<JDWP::JdwpOptions> { /* * Handle one of the JDWP name/value pairs. * * JDWP options are: * help: if specified, show help message and bail * transport: may be dt_socket or dt_shmem * address: for dt_socket, "host:port", or just "port" when listening * server: if "y", wait for debugger to attach; if "n", attach to debugger * timeout: how long to wait for debugger to connect / listen * * Useful with server=n (these aren't supported yet): * onthrow=<exception-name>: connect to debugger when exception thrown * onuncaught=y|n: connect to debugger when uncaught exception thrown * launch=<command-line>: launch the debugger itself * * The "transport" option is required, as is "address" if server=n. */ Result Parse(const std::string& options) { VLOG(jdwp) << "ParseJdwpOptions: " << options; if (options == "help") { return Result::Usage( "Example: -Xrunjdwp:transport=dt_socket,address=8000,server=y\n" "Example: -Xrunjdwp:transport=dt_socket,address=localhost:6500,server=n\n"); } const std::string s; std::vector<std::string> pairs; Split(options, ',', &pairs); JDWP::JdwpOptions jdwp_options; for (const std::string& jdwp_option : pairs) { std::string::size_type equals_pos = jdwp_option.find('='); if (equals_pos == std::string::npos) { return Result::Failure(s + "Can't parse JDWP option '" + jdwp_option + "' in '" + options + "'"); } Result parse_attempt = ParseJdwpOption(jdwp_option.substr(0, equals_pos), jdwp_option.substr(equals_pos + 1), &jdwp_options); if (parse_attempt.IsError()) { // We fail to parse this JDWP option. return parse_attempt; } } if (jdwp_options.transport == JDWP::kJdwpTransportUnknown) { return Result::Failure(s + "Must specify JDWP transport: " + options); } if (!jdwp_options.server && (jdwp_options.host.empty() || jdwp_options.port == 0)) { return Result::Failure(s + "Must specify JDWP host and port when server=n: " + options); } return Result::Success(std::move(jdwp_options)); } Result ParseJdwpOption(const std::string& name, const std::string& value, JDWP::JdwpOptions* jdwp_options) { if (name == "transport") { if (value == "dt_socket") { jdwp_options->transport = JDWP::kJdwpTransportSocket; } else if (value == "dt_android_adb") { jdwp_options->transport = JDWP::kJdwpTransportAndroidAdb; } else { return Result::Failure("JDWP transport not supported: " + value); } } else if (name == "server") { if (value == "n") { jdwp_options->server = false; } else if (value == "y") { jdwp_options->server = true; } else { return Result::Failure("JDWP option 'server' must be 'y' or 'n'"); } } else if (name == "suspend") { if (value == "n") { jdwp_options->suspend = false; } else if (value == "y") { jdwp_options->suspend = true; } else { return Result::Failure("JDWP option 'suspend' must be 'y' or 'n'"); } } else if (name == "address") { /* this is either <port> or <host>:<port> */ std::string port_string; jdwp_options->host.clear(); std::string::size_type colon = value.find(':'); if (colon != std::string::npos) { jdwp_options->host = value.substr(0, colon); port_string = value.substr(colon + 1); } else { port_string = value; } if (port_string.empty()) { return Result::Failure("JDWP address missing port: " + value); } char* end; uint64_t port = strtoul(port_string.c_str(), &end, 10); if (*end != '\0' || port > 0xffff) { return Result::Failure("JDWP address has junk in port field: " + value); } jdwp_options->port = port; } else if (name == "launch" || name == "onthrow" || name == "oncaught" || name == "timeout") { /* valid but unsupported */ LOG(INFO) << "Ignoring JDWP option '" << name << "'='" << value << "'"; } else { LOG(INFO) << "Ignoring unrecognized JDWP option '" << name << "'='" << value << "'"; } return Result::SuccessNoValue(); } static const char* Name() { return "JdwpOptions"; } }; template <size_t Divisor> struct CmdlineType<Memory<Divisor>> : CmdlineTypeParser<Memory<Divisor>> { using typename CmdlineTypeParser<Memory<Divisor>>::Result; Result Parse(const std::string arg) { CMDLINE_DEBUG_LOG << "Parsing memory: " << arg << std::endl; size_t val = ParseMemoryOption(arg.c_str(), Divisor); CMDLINE_DEBUG_LOG << "Memory parsed to size_t value: " << val << std::endl; if (val == 0) { return Result::Failure(std::string("not a valid memory value, or not divisible by ") + std::to_string(Divisor)); } return Result::Success(Memory<Divisor>(val)); } // Parse a string of the form /[0-9]+[kKmMgG]?/, which is used to specify // memory sizes. [kK] indicates kilobytes, [mM] megabytes, and // [gG] gigabytes. // // "s" should point just past the "-Xm?" part of the string. // "div" specifies a divisor, e.g. 1024 if the value must be a multiple // of 1024. // // The spec says the -Xmx and -Xms options must be multiples of 1024. It // doesn't say anything about -Xss. // // Returns 0 (a useless size) if "s" is malformed or specifies a low or // non-evenly-divisible value. // static size_t ParseMemoryOption(const char* s, size_t div) { // strtoul accepts a leading [+-], which we don't want, // so make sure our string starts with a decimal digit. if (isdigit(*s)) { char* s2; size_t val = strtoul(s, &s2, 10); if (s2 != s) { // s2 should be pointing just after the number. // If this is the end of the string, the user // has specified a number of bytes. Otherwise, // there should be exactly one more character // that specifies a multiplier. if (*s2 != '\0') { // The remainder of the string is either a single multiplier // character, or nothing to indicate that the value is in // bytes. char c = *s2++; if (*s2 == '\0') { size_t mul; if (c == '\0') { mul = 1; } else if (c == 'k' || c == 'K') { mul = KB; } else if (c == 'm' || c == 'M') { mul = MB; } else if (c == 'g' || c == 'G') { mul = GB; } else { // Unknown multiplier character. return 0; } if (val <= std::numeric_limits<size_t>::max() / mul) { val *= mul; } else { // Clamp to a multiple of 1024. val = std::numeric_limits<size_t>::max() & ~(1024-1); } } else { // There's more than one character after the numeric part. return 0; } } // The man page says that a -Xm value must be a multiple of 1024. if (val % div == 0) { return val; } } } return 0; } static const char* Name() { return Memory<Divisor>::Name(); } }; template <> struct CmdlineType<double> : CmdlineTypeParser<double> { Result Parse(const std::string& str) { char* end = nullptr; errno = 0; double value = strtod(str.c_str(), &end); if (*end != '\0') { return Result::Failure("Failed to parse double from " + str); } if (errno == ERANGE) { return Result::OutOfRange( "Failed to parse double from " + str + "; overflow/underflow occurred"); } return Result::Success(value); } static const char* Name() { return "double"; } }; template <> struct CmdlineType<unsigned int> : CmdlineTypeParser<unsigned int> { Result Parse(const std::string& str) { const char* begin = str.c_str(); char* end; // Parse into a larger type (long long) because we can't use strtoul // since it silently converts negative values into unsigned long and doesn't set errno. errno = 0; long long int result = strtoll(begin, &end, 10); // NOLINT [runtime/int] [4] if (begin == end || *end != '\0' || errno == EINVAL) { return Result::Failure("Failed to parse integer from " + str); } else if ((errno == ERANGE) || // NOLINT [runtime/int] [4] result < std::numeric_limits<int>::min() || result > std::numeric_limits<unsigned int>::max() || result < 0) { return Result::OutOfRange( "Failed to parse integer from " + str + "; out of unsigned int range"); } return Result::Success(static_cast<unsigned int>(result)); } static const char* Name() { return "unsigned integer"; } }; // Lightweight nanosecond value type. Allows parser to convert user-input from milliseconds // to nanoseconds automatically after parsing. // // All implicit conversion from uint64_t uses nanoseconds. struct MillisecondsToNanoseconds { // Create from nanoseconds. MillisecondsToNanoseconds(uint64_t nanoseconds) : nanoseconds_(nanoseconds) { // NOLINT [runtime/explicit] [5] } // Create from milliseconds. static MillisecondsToNanoseconds FromMilliseconds(unsigned int milliseconds) { return MillisecondsToNanoseconds(MsToNs(milliseconds)); } // Get the underlying nanoseconds value. uint64_t GetNanoseconds() const { return nanoseconds_; } // Get the milliseconds value [via a conversion]. Loss of precision will occur. uint64_t GetMilliseconds() const { return NsToMs(nanoseconds_); } // Get the underlying nanoseconds value. operator uint64_t() const { return GetNanoseconds(); } // Default constructors/copy-constructors. MillisecondsToNanoseconds() : nanoseconds_(0ul) {} MillisecondsToNanoseconds(const MillisecondsToNanoseconds&) = default; MillisecondsToNanoseconds(MillisecondsToNanoseconds&&) = default; private: uint64_t nanoseconds_; }; template <> struct CmdlineType<MillisecondsToNanoseconds> : CmdlineTypeParser<MillisecondsToNanoseconds> { Result Parse(const std::string& str) { CmdlineType<unsigned int> uint_parser; CmdlineParseResult<unsigned int> res = uint_parser.Parse(str); if (res.IsSuccess()) { return Result::Success(MillisecondsToNanoseconds::FromMilliseconds(res.GetValue())); } else { return Result::CastError(res); } } static const char* Name() { return "MillisecondsToNanoseconds"; } }; template <> struct CmdlineType<std::string> : CmdlineTypeParser<std::string> { Result Parse(const std::string& args) { return Result::Success(args); } Result ParseAndAppend(const std::string& args, std::string& existing_value) { if (existing_value.empty()) { existing_value = args; } else { existing_value += ' '; existing_value += args; } return Result::SuccessNoValue(); } }; template <> struct CmdlineType<std::vector<std::string>> : CmdlineTypeParser<std::vector<std::string>> { Result Parse(const std::string& args) { assert(false && "Use AppendValues() for a string vector type"); return Result::Failure("Unconditional failure: string vector must be appended: " + args); } Result ParseAndAppend(const std::string& args, std::vector<std::string>& existing_value) { existing_value.push_back(args); return Result::SuccessNoValue(); } static const char* Name() { return "std::vector<std::string>"; } }; template <char Separator> struct ParseStringList { explicit ParseStringList(std::vector<std::string>&& list) : list_(list) {} operator std::vector<std::string>() const { return list_; } operator std::vector<std::string>&&() && { return std::move(list_); } size_t Size() const { return list_.size(); } std::string Join() const { return art::Join(list_, Separator); } static ParseStringList<Separator> Split(const std::string& str) { std::vector<std::string> list; art::Split(str, Separator, &list); return ParseStringList<Separator>(std::move(list)); } ParseStringList() = default; ParseStringList(const ParseStringList&) = default; ParseStringList(ParseStringList&&) = default; private: std::vector<std::string> list_; }; template <char Separator> struct CmdlineType<ParseStringList<Separator>> : CmdlineTypeParser<ParseStringList<Separator>> { using Result = CmdlineParseResult<ParseStringList<Separator>>; Result Parse(const std::string& args) { return Result::Success(ParseStringList<Separator>::Split(args)); } static const char* Name() { return "ParseStringList<Separator>"; } }; static gc::CollectorType ParseCollectorType(const std::string& option) { if (option == "MS" || option == "nonconcurrent") { return gc::kCollectorTypeMS; } else if (option == "CMS" || option == "concurrent") { return gc::kCollectorTypeCMS; } else if (option == "SS") { return gc::kCollectorTypeSS; } else if (option == "GSS") { return gc::kCollectorTypeGSS; } else if (option == "CC") { return gc::kCollectorTypeCC; } else if (option == "MC") { return gc::kCollectorTypeMC; } else { return gc::kCollectorTypeNone; } } struct XGcOption { // These defaults are used when the command line arguments for -Xgc: // are either omitted completely or partially. gc::CollectorType collector_type_ = kUseReadBarrier ? // If RB is enabled (currently a build-time decision), // use CC as the default GC. gc::kCollectorTypeCC : gc::kCollectorTypeDefault; bool verify_pre_gc_heap_ = false; bool verify_pre_sweeping_heap_ = kIsDebugBuild; bool verify_post_gc_heap_ = false; bool verify_pre_gc_rosalloc_ = kIsDebugBuild; bool verify_pre_sweeping_rosalloc_ = false; bool verify_post_gc_rosalloc_ = false; bool gcstress_ = false; }; template <> struct CmdlineType<XGcOption> : CmdlineTypeParser<XGcOption> { Result Parse(const std::string& option) { // -Xgc: already stripped XGcOption xgc{}; // NOLINT [readability/braces] [4] std::vector<std::string> gc_options; Split(option, ',', &gc_options); for (const std::string& gc_option : gc_options) { gc::CollectorType collector_type = ParseCollectorType(gc_option); if (collector_type != gc::kCollectorTypeNone) { xgc.collector_type_ = collector_type; } else if (gc_option == "preverify") { xgc.verify_pre_gc_heap_ = true; } else if (gc_option == "nopreverify") { xgc.verify_pre_gc_heap_ = false; } else if (gc_option == "presweepingverify") { xgc.verify_pre_sweeping_heap_ = true; } else if (gc_option == "nopresweepingverify") { xgc.verify_pre_sweeping_heap_ = false; } else if (gc_option == "postverify") { xgc.verify_post_gc_heap_ = true; } else if (gc_option == "nopostverify") { xgc.verify_post_gc_heap_ = false; } else if (gc_option == "preverify_rosalloc") { xgc.verify_pre_gc_rosalloc_ = true; } else if (gc_option == "nopreverify_rosalloc") { xgc.verify_pre_gc_rosalloc_ = false; } else if (gc_option == "presweepingverify_rosalloc") { xgc.verify_pre_sweeping_rosalloc_ = true; } else if (gc_option == "nopresweepingverify_rosalloc") { xgc.verify_pre_sweeping_rosalloc_ = false; } else if (gc_option == "postverify_rosalloc") { xgc.verify_post_gc_rosalloc_ = true; } else if (gc_option == "nopostverify_rosalloc") { xgc.verify_post_gc_rosalloc_ = false; } else if (gc_option == "gcstress") { xgc.gcstress_ = true; } else if (gc_option == "nogcstress") { xgc.gcstress_ = false; } else if ((gc_option == "precise") || (gc_option == "noprecise") || (gc_option == "verifycardtable") || (gc_option == "noverifycardtable")) { // Ignored for backwards compatibility. } else { return Result::Usage(std::string("Unknown -Xgc option ") + gc_option); } } return Result::Success(std::move(xgc)); } static const char* Name() { return "XgcOption"; } }; struct BackgroundGcOption { // If background_collector_type_ is kCollectorTypeNone, it defaults to the // XGcOption::collector_type_ after parsing options. If you set this to // kCollectorTypeHSpaceCompact then we will do an hspace compaction when // we transition to background instead of a normal collector transition. gc::CollectorType background_collector_type_; BackgroundGcOption(gc::CollectorType background_collector_type) // NOLINT [runtime/explicit] [5] : background_collector_type_(background_collector_type) {} BackgroundGcOption() : background_collector_type_(gc::kCollectorTypeNone) { if (kUseReadBarrier) { background_collector_type_ = gc::kCollectorTypeCC; // Disable background compaction for CC. } } operator gc::CollectorType() const { return background_collector_type_; } }; template<> struct CmdlineType<BackgroundGcOption> : CmdlineTypeParser<BackgroundGcOption>, private BackgroundGcOption { Result Parse(const std::string& substring) { // Special handling for HSpaceCompact since this is only valid as a background GC type. if (substring == "HSpaceCompact") { background_collector_type_ = gc::kCollectorTypeHomogeneousSpaceCompact; } else { gc::CollectorType collector_type = ParseCollectorType(substring); if (collector_type != gc::kCollectorTypeNone) { background_collector_type_ = collector_type; } else { return Result::Failure(); } } BackgroundGcOption res = *this; return Result::Success(res); } static const char* Name() { return "BackgroundGcOption"; } }; template <> struct CmdlineType<LogVerbosity> : CmdlineTypeParser<LogVerbosity> { Result Parse(const std::string& options) { LogVerbosity log_verbosity = LogVerbosity(); std::vector<std::string> verbose_options; Split(options, ',', &verbose_options); for (size_t j = 0; j < verbose_options.size(); ++j) { if (verbose_options[j] == "class") { log_verbosity.class_linker = true; } else if (verbose_options[j] == "collector") { log_verbosity.collector = true; } else if (verbose_options[j] == "compiler") { log_verbosity.compiler = true; } else if (verbose_options[j] == "deopt") { log_verbosity.deopt = true; } else if (verbose_options[j] == "gc") { log_verbosity.gc = true; } else if (verbose_options[j] == "heap") { log_verbosity.heap = true; } else if (verbose_options[j] == "jdwp") { log_verbosity.jdwp = true; } else if (verbose_options[j] == "jit") { log_verbosity.jit = true; } else if (verbose_options[j] == "jni") { log_verbosity.jni = true; } else if (verbose_options[j] == "monitor") { log_verbosity.monitor = true; } else if (verbose_options[j] == "oat") { log_verbosity.oat = true; } else if (verbose_options[j] == "profiler") { log_verbosity.profiler = true; } else if (verbose_options[j] == "signals") { log_verbosity.signals = true; } else if (verbose_options[j] == "simulator") { log_verbosity.simulator = true; } else if (verbose_options[j] == "startup") { log_verbosity.startup = true; } else if (verbose_options[j] == "third-party-jni") { log_verbosity.third_party_jni = true; } else if (verbose_options[j] == "threads") { log_verbosity.threads = true; } else if (verbose_options[j] == "verifier") { log_verbosity.verifier = true; } else if (verbose_options[j] == "image") { log_verbosity.image = true; } else if (verbose_options[j] == "systrace-locks") { log_verbosity.systrace_lock_logging = true; } else { return Result::Usage(std::string("Unknown -verbose option ") + verbose_options[j]); } } return Result::Success(log_verbosity); } static const char* Name() { return "LogVerbosity"; } }; // TODO: Replace with art::ProfilerOptions for the real thing. struct TestProfilerOptions { // Whether or not the applications should be profiled. bool enabled_; // Destination file name where the profiling data will be saved into. std::string output_file_name_; // Generate profile every n seconds. uint32_t period_s_; // Run profile for n seconds. uint32_t duration_s_; // Microseconds between samples. uint32_t interval_us_; // Coefficient to exponential backoff. double backoff_coefficient_; // Whether the profile should start upon app startup or be delayed by some random offset. bool start_immediately_; // Top K% of samples that are considered relevant when deciding if the app should be recompiled. double top_k_threshold_; // How much the top K% samples needs to change in order for the app to be recompiled. double top_k_change_threshold_; // The type of profile data dumped to the disk. ProfileDataType profile_type_; // The max depth of the stack collected by the profiler uint32_t max_stack_depth_; TestProfilerOptions() : enabled_(false), output_file_name_(), period_s_(0), duration_s_(0), interval_us_(0), backoff_coefficient_(0), start_immediately_(0), top_k_threshold_(0), top_k_change_threshold_(0), profile_type_(ProfileDataType::kProfilerMethod), max_stack_depth_(0) { } TestProfilerOptions(const TestProfilerOptions&) = default; TestProfilerOptions(TestProfilerOptions&&) = default; }; static inline std::ostream& operator<<(std::ostream& stream, const TestProfilerOptions& options) { stream << "TestProfilerOptions {" << std::endl; #define PRINT_TO_STREAM(field) \ stream << #field << ": '" << options.field << "'" << std::endl; PRINT_TO_STREAM(enabled_); PRINT_TO_STREAM(output_file_name_); PRINT_TO_STREAM(period_s_); PRINT_TO_STREAM(duration_s_); PRINT_TO_STREAM(interval_us_); PRINT_TO_STREAM(backoff_coefficient_); PRINT_TO_STREAM(start_immediately_); PRINT_TO_STREAM(top_k_threshold_); PRINT_TO_STREAM(top_k_change_threshold_); PRINT_TO_STREAM(profile_type_); PRINT_TO_STREAM(max_stack_depth_); stream << "}"; return stream; #undef PRINT_TO_STREAM } template <> struct CmdlineType<TestProfilerOptions> : CmdlineTypeParser<TestProfilerOptions> { using Result = CmdlineParseResult<TestProfilerOptions>; private: using StringResult = CmdlineParseResult<std::string>; using DoubleResult = CmdlineParseResult<double>; template <typename T> static Result ParseInto(TestProfilerOptions& options, T TestProfilerOptions::*pField, CmdlineParseResult<T>&& result) { assert(pField != nullptr); if (result.IsSuccess()) { options.*pField = result.ReleaseValue(); return Result::SuccessNoValue(); } return Result::CastError(result); } template <typename T> static Result ParseIntoRangeCheck(TestProfilerOptions& options, T TestProfilerOptions::*pField, CmdlineParseResult<T>&& result, T min, T max) { if (result.IsSuccess()) { const T& value = result.GetValue(); if (value < min || value > max) { CmdlineParseResult<T> out_of_range = CmdlineParseResult<T>::OutOfRange(value, min, max); return Result::CastError(out_of_range); } } return ParseInto(options, pField, std::forward<CmdlineParseResult<T>>(result)); } static StringResult ParseStringAfterChar(const std::string& s, char c) { std::string parsed_value; std::string::size_type colon = s.find(c); if (colon == std::string::npos) { return StringResult::Usage(std::string() + "Missing char " + c + " in option " + s); } // Add one to remove the char we were trimming until. parsed_value = s.substr(colon + 1); return StringResult::Success(parsed_value); } static std::string RemovePrefix(const std::string& source) { size_t prefix_idx = source.find(":"); if (prefix_idx == std::string::npos) { return ""; } return source.substr(prefix_idx + 1); } public: Result ParseAndAppend(const std::string& option, TestProfilerOptions& existing) { // Special case which doesn't include a wildcard argument definition. // We pass-it through as-is. if (option == "-Xenable-profiler") { existing.enabled_ = true; return Result::SuccessNoValue(); } // The rest of these options are always the wildcard from '-Xprofile-*' std::string suffix = RemovePrefix(option); if (StartsWith(option, "filename:")) { CmdlineType<std::string> type_parser; return ParseInto(existing, &TestProfilerOptions::output_file_name_, type_parser.Parse(suffix)); } else if (StartsWith(option, "period:")) { CmdlineType<unsigned int> type_parser; return ParseInto(existing, &TestProfilerOptions::period_s_, type_parser.Parse(suffix)); } else if (StartsWith(option, "duration:")) { CmdlineType<unsigned int> type_parser; return ParseInto(existing, &TestProfilerOptions::duration_s_, type_parser.Parse(suffix)); } else if (StartsWith(option, "interval:")) { CmdlineType<unsigned int> type_parser; return ParseInto(existing, &TestProfilerOptions::interval_us_, type_parser.Parse(suffix)); } else if (StartsWith(option, "backoff:")) { CmdlineType<double> type_parser; return ParseIntoRangeCheck(existing, &TestProfilerOptions::backoff_coefficient_, type_parser.Parse(suffix), 1.0, 10.0); } else if (option == "start-immediately") { existing.start_immediately_ = true; return Result::SuccessNoValue(); } else if (StartsWith(option, "top-k-threshold:")) { CmdlineType<double> type_parser; return ParseIntoRangeCheck(existing, &TestProfilerOptions::top_k_threshold_, type_parser.Parse(suffix), 0.0, 100.0); } else if (StartsWith(option, "top-k-change-threshold:")) { CmdlineType<double> type_parser; return ParseIntoRangeCheck(existing, &TestProfilerOptions::top_k_change_threshold_, type_parser.Parse(suffix), 0.0, 100.0); } else if (option == "type:method") { existing.profile_type_ = kProfilerMethod; return Result::SuccessNoValue(); } else if (option == "type:stack") { existing.profile_type_ = kProfilerBoundedStack; return Result::SuccessNoValue(); } else if (StartsWith(option, "max-stack-depth:")) { CmdlineType<unsigned int> type_parser; return ParseInto(existing, &TestProfilerOptions::max_stack_depth_, type_parser.Parse(suffix)); } else { return Result::Failure(std::string("Invalid suboption '") + option + "'"); } } static const char* Name() { return "TestProfilerOptions"; } static constexpr bool kCanParseBlankless = true; }; template<> struct CmdlineType<ExperimentalFlags> : CmdlineTypeParser<ExperimentalFlags> { Result ParseAndAppend(const std::string& option, ExperimentalFlags& existing) { if (option == "none") { existing = ExperimentalFlags::kNone; } else if (option == "lambdas") { existing = existing | ExperimentalFlags::kLambdas; } else { return Result::Failure(std::string("Unknown option '") + option + "'"); } return Result::SuccessNoValue(); } static const char* Name() { return "ExperimentalFlags"; } }; } // namespace art #endif // ART_CMDLINE_CMDLINE_TYPES_H_