blob: 904d95914ea0cc42df21443a6e265ca4d394e382 [file] [log] [blame]
// Copyright 2011 Google Inc. All Rights Reserved.
#include "runtime.h"
#include <signal.h>
#include <cstdio>
#include <cstdlib>
#include <limits>
#include <vector>
#include "class_linker.h"
#include "class_loader.h"
#include "debugger.h"
#include "dex_verifier.h"
#include "heap.h"
#include "image.h"
#include "intern_table.h"
#include "jni_internal.h"
#include "monitor.h"
#include "oat_file.h"
#include "ScopedLocalRef.h"
#include "signal_catcher.h"
#include "space.h"
#include "thread.h"
#include "thread_list.h"
#include "UniquePtr.h"
// TODO: this drags in cutil/log.h, which conflicts with our logging.h.
#include "JniConstants.h"
namespace art {
Runtime* Runtime::instance_ = NULL;
Runtime::Runtime()
: is_zygote_(false),
default_stack_size_(Thread::kDefaultStackSize),
monitor_list_(NULL),
thread_list_(NULL),
intern_table_(NULL),
class_linker_(NULL),
signal_catcher_(NULL),
java_vm_(NULL),
jni_stub_array_(NULL),
abstract_method_error_stub_array_(NULL),
shutting_down_(false),
started_(false),
vfprintf_(NULL),
exit_(NULL),
abort_(NULL),
stats_enabled_(false),
tracer_(NULL) {
for (int i = 0; i < Runtime::kLastTrampolineMethodType; i++) {
resolution_stub_array_[i] = NULL;
}
for (int i = 0; i < Runtime::kLastCalleeSaveType; i++) {
callee_save_method_[i] = NULL;
}
}
Runtime::~Runtime() {
shutting_down_ = true;
Dbg::StopJdwp();
// Make sure our internal threads are dead before we start tearing down things they're using.
delete signal_catcher_;
// TODO: GC thread.
// Make sure all other non-daemon threads have terminated, and all daemon threads are suspended.
delete thread_list_;
delete monitor_list_;
delete class_linker_;
Heap::Destroy();
verifier::DexVerifier::DeleteGcMaps();
delete intern_table_;
delete java_vm_;
Thread::Shutdown();
// TODO: acquire a static mutex on Runtime to avoid racing.
CHECK(instance_ == NULL || instance_ == this);
instance_ = NULL;
}
static bool gAborting = false;
struct AbortState {
void Dump(std::ostream& os) {
if (gAborting) {
os << "Runtime aborting --- recursively, so no thread-specific detail!\n";
return;
}
gAborting = true;
os << "Runtime aborting...\n";
Thread* self = Thread::Current();
if (self == NULL) {
os << "(Aborting thread was not attached to runtime!)\n";
} else {
self->Dump(os, true);
}
}
};
void Runtime::Abort(const char* file, int line) {
// Get any pending output out of the way.
fflush(NULL);
// Many people have difficulty distinguish aborts from crashes,
// so be explicit.
AbortState state;
LOG(ERROR) << Dumpable<AbortState>(state);
// Perform any platform-specific pre-abort actions.
PlatformAbort(file, line);
// use abort hook if we have one
if (Runtime::Current() != NULL && Runtime::Current()->abort_ != NULL) {
Runtime::Current()->abort_();
// notreached
}
// If we call abort(3) on a device, all threads in the process
// receive SIGABRT. debuggerd dumps the stack trace of the main
// thread, whether or not that was the thread that failed. By
// stuffing a value into a bogus address, we cause a segmentation
// fault in the current thread, and get a useful log from debuggerd.
// We can also trivially tell the difference between a VM crash and
// a deliberate abort by looking at the fault address.
*reinterpret_cast<char*>(0xdeadd00d) = 38;
abort();
// notreached
}
void Runtime::CallExitHook(jint status) {
if (exit_ != NULL) {
ScopedThreadStateChange tsc(Thread::Current(), Thread::kNative);
exit_(status);
LOG(WARNING) << "Exit hook returned instead of exiting!";
}
}
// 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.
//
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)) {
const char* s2;
size_t val = strtoul(s, (char**)&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;
}
size_t ParseIntegerOrDie(const StringPiece& s) {
StringPiece::size_type colon = s.find(':');
if (colon == StringPiece::npos) {
LOG(FATAL) << "Missing integer: " << s;
}
const char* begin = &s.data()[colon + 1];
char* end;
size_t result = strtoul(begin, &end, 10);
if (begin == end || *end != '\0') {
LOG(FATAL) << "Failed to parse integer in: " << s;
}
return result;
}
void LoadJniLibrary(JavaVMExt* vm, const char* name) {
// TODO: OS_SHARED_LIB_FORMAT_STR
std::string mapped_name(StringPrintf("lib%s.so", name));
std::string reason;
if (!vm->LoadNativeLibrary(mapped_name, NULL, reason)) {
LOG(FATAL) << "LoadNativeLibrary failed for \"" << mapped_name << "\": "
<< reason;
}
}
Runtime::ParsedOptions* Runtime::ParsedOptions::Create(const Options& options, bool ignore_unrecognized) {
UniquePtr<ParsedOptions> parsed(new ParsedOptions());
bool compiler = false;
const char* boot_class_path = getenv("BOOTCLASSPATH");
if (boot_class_path != NULL) {
parsed->boot_class_path_ = boot_class_path;
} else {
parsed->boot_class_path_ = ".";
}
const char* class_path = getenv("CLASSPATH");
if (class_path != NULL) {
parsed->class_path_ = class_path;
} else {
parsed->class_path_ = ".";
}
#ifdef NDEBUG
// -Xcheck:jni is off by default for regular builds...
parsed->check_jni_ = false;
#else
// ...but on by default in debug builds.
parsed->check_jni_ = true;
#endif
parsed->heap_initial_size_ = Heap::kInitialSize;
parsed->heap_maximum_size_ = Heap::kMaximumSize;
parsed->heap_growth_limit_ = 0; // 0 means no growth limit
parsed->stack_size_ = Thread::kDefaultStackSize;
parsed->is_zygote_ = false;
parsed->jni_globals_max_ = 0;
parsed->lock_profiling_threshold_ = 0;
parsed->hook_is_sensitive_thread_ = NULL;
parsed->hook_vfprintf_ = vfprintf;
parsed->hook_exit_ = exit;
parsed->hook_abort_ = abort;
for (size_t i = 0; i < options.size(); ++i) {
const StringPiece& option = options[i].first;
if (true && options[0].first == "-Xzygote") {
LOG(INFO) << "option[" << i << "]=" << option;
}
if (option.starts_with("-Xbootclasspath:")) {
parsed->boot_class_path_ = option.substr(strlen("-Xbootclasspath:")).data();
} else if (option == "-classpath" || option == "-cp") {
// TODO: support -Djava.class.path
i++;
if (i == options.size()) {
// TODO: usage
LOG(FATAL) << "Missing required class path value for " << option;
return NULL;
}
const StringPiece& value = options[i].first;
parsed->class_path_ = value.data();
} else if (option.starts_with("-Ximage:")) {
parsed->images_.push_back(option.substr(strlen("-Ximage:")).data());
} else if (option.starts_with("-Xcheck:jni")) {
parsed->check_jni_ = true;
} else if (option.starts_with("-Xrunjdwp:") || option.starts_with("-agentlib:jdwp=")) {
std::string tail(option.substr(option[1] == 'X' ? 10 : 15).ToString());
if (tail == "help" || !Dbg::ParseJdwpOptions(tail)) {
LOG(FATAL) << "Example: -Xrunjdwp:transport=dt_socket,address=8000,server=y\n"
<< "Example: -Xrunjdwp:transport=dt_socket,address=localhost:6500,server=n";
return NULL;
}
} else if (option.starts_with("-Xms")) {
size_t size = ParseMemoryOption(option.substr(strlen("-Xms")).data(), 1024);
if (size == 0) {
if (ignore_unrecognized) {
continue;
}
// TODO: usage
LOG(FATAL) << "Failed to parse " << option;
return NULL;
}
parsed->heap_initial_size_ = size;
} else if (option.starts_with("-Xmx")) {
size_t size = ParseMemoryOption(option.substr(strlen("-Xmx")).data(), 1024);
if (size == 0) {
if (ignore_unrecognized) {
continue;
}
// TODO: usage
LOG(FATAL) << "Failed to parse " << option;
return NULL;
}
parsed->heap_maximum_size_ = size;
} else if (option.starts_with("-XX:HeapGrowthLimit=")) {
size_t size = ParseMemoryOption(option.substr(strlen("-XX:HeapGrowthLimit=")).data(), 1024);
if (size == 0) {
if (ignore_unrecognized) {
continue;
}
// TODO: usage
LOG(FATAL) << "Failed to parse " << option;
return NULL;
}
parsed->heap_growth_limit_ = size;
} else if (option.starts_with("-Xss")) {
size_t size = ParseMemoryOption(option.substr(strlen("-Xss")).data(), 1);
if (size == 0) {
if (ignore_unrecognized) {
continue;
}
// TODO: usage
LOG(FATAL) << "Failed to parse " << option;
return NULL;
}
parsed->stack_size_ = size;
} else if (option.starts_with("-D")) {
parsed->properties_.push_back(option.substr(strlen("-D")).data());
} else if (option.starts_with("-Xjnitrace:")) {
parsed->jni_trace_ = option.substr(strlen("-Xjnitrace:")).data();
} else if (option == "compiler") {
compiler = true;
} else if (option == "-Xzygote") {
parsed->is_zygote_ = true;
} else if (option.starts_with("-verbose:")) {
std::vector<std::string> verbose_options;
Split(option.substr(strlen("-verbose:")).data(), ',', verbose_options);
for (size_t i = 0; i < verbose_options.size(); ++i) {
if (verbose_options[i] == "class") {
gLogVerbosity.class_linker = true;
} else if (verbose_options[i] == "compiler") {
gLogVerbosity.compiler = true;
} else if (verbose_options[i] == "heap") {
gLogVerbosity.heap = true;
} else if (verbose_options[i] == "gc") {
gLogVerbosity.gc = true;
} else if (verbose_options[i] == "jdwp") {
gLogVerbosity.jdwp = true;
} else if (verbose_options[i] == "jni") {
gLogVerbosity.jni = true;
} else if (verbose_options[i] == "monitor") {
gLogVerbosity.monitor = true;
} else if (verbose_options[i] == "startup") {
gLogVerbosity.startup = true;
} else if (verbose_options[i] == "third-party-jni") {
gLogVerbosity.third_party_jni = true;
} else if (verbose_options[i] == "threads") {
gLogVerbosity.threads = true;
} else {
LOG(WARNING) << "Ignoring unknown -verbose option: " << verbose_options[i];
}
}
} else if (option.starts_with("-Xjnigreflimit:")) {
parsed->jni_globals_max_ = ParseIntegerOrDie(option);
} else if (option.starts_with("-Xlockprofthreshold:")) {
parsed->lock_profiling_threshold_ = ParseIntegerOrDie(option);
} else if (option.starts_with("-Xstacktracefile:")) {
// always show stack traces in debug builds
#ifdef NDEBUG
parsed->stack_trace_file_ = option.substr(strlen("-Xstacktracefile:")).data();
#endif
} else if (option == "sensitiveThread") {
parsed->hook_is_sensitive_thread_ = reinterpret_cast<bool (*)()>(options[i].second);
} else if (option == "vfprintf") {
parsed->hook_vfprintf_ = reinterpret_cast<int (*)(FILE *, const char*, va_list)>(options[i].second);
} else if (option == "exit") {
parsed->hook_exit_ = reinterpret_cast<void(*)(jint)>(options[i].second);
} else if (option == "abort") {
parsed->hook_abort_ = reinterpret_cast<void(*)()>(options[i].second);
} else if (option == "host-prefix") {
parsed->host_prefix_ = reinterpret_cast<const char*>(options[i].second);
} else if (option == "-Xgenregmap" || option == "-Xgc:precise") {
// We silently ignore these for backwards compatibility.
} else {
if (!ignore_unrecognized) {
// TODO: print usage via vfprintf
LOG(ERROR) << "Unrecognized option " << option;
// TODO: this should exit, but for now tolerate unknown options
//return NULL;
}
}
}
if (!compiler && parsed->images_.empty()) {
parsed->images_.push_back("/system/framework/boot.art");
}
if (parsed->heap_growth_limit_ == 0) {
parsed->heap_growth_limit_ = parsed->heap_maximum_size_;
}
LOG(INFO) << "Build type: "
#ifndef NDEBUG
<< "debug"
#else
<< "optimized"
#endif
<< "; CheckJNI: " << (parsed->check_jni_ ? "on" : "off");
return parsed.release();
}
Runtime* Runtime::Create(const Options& options, bool ignore_unrecognized) {
// TODO: acquire a static mutex on Runtime to avoid racing.
if (Runtime::instance_ != NULL) {
return NULL;
}
instance_ = new Runtime;
if (!instance_->Init(options, ignore_unrecognized)) {
delete instance_;
instance_ = NULL;
}
return instance_;
}
void CreateSystemClassLoader() {
if (ClassLoader::UseCompileTimeClassPath()) {
return;
}
Thread* self = Thread::Current();
// Must be in the kNative state for calling native methods.
CHECK_EQ(self->GetState(), Thread::kNative);
JNIEnv* env = self->GetJniEnv();
ScopedLocalRef<jclass> ClassLoader_class(env, env->FindClass("java/lang/ClassLoader"));
CHECK(ClassLoader_class.get() != NULL);
jmethodID getSystemClassLoader = env->GetStaticMethodID(ClassLoader_class.get(),
"getSystemClassLoader",
"()Ljava/lang/ClassLoader;");
CHECK(getSystemClassLoader != NULL);
ScopedLocalRef<jobject> class_loader(env, env->CallStaticObjectMethod(ClassLoader_class.get(),
getSystemClassLoader));
CHECK(class_loader.get() != NULL);
Thread::Current()->SetClassLoaderOverride(Decode<ClassLoader*>(env, class_loader.get()));
ScopedLocalRef<jclass> Thread_class(env, env->FindClass("java/lang/Thread"));
CHECK(Thread_class.get() != NULL);
jfieldID contextClassLoader = env->GetFieldID(Thread_class.get(),
"contextClassLoader",
"Ljava/lang/ClassLoader;");
CHECK(contextClassLoader != NULL);
ScopedLocalRef<jobject> self_jobject(env, AddLocalReference<jobject>(env, self->GetPeer()));
env->SetObjectField(self_jobject.get(), contextClassLoader, class_loader.get());
}
void Runtime::Start() {
VLOG(startup) << "Runtime::Start entering";
CHECK(host_prefix_.empty()) << host_prefix_;
// Restore main thread state to kNative as expected by native code
Thread::Current()->SetState(Thread::kNative);
started_ = true;
// InitNativeMethods needs to be after started_ so that the classes
// it touches will have methods linked to the oat file if necessary.
InitNativeMethods();
Thread::FinishStartup();
if (!is_zygote_) {
DidForkFromZygote();
}
StartDaemonThreads();
CreateSystemClassLoader();
Thread::Current()->GetJniEnv()->locals.AssertEmpty();
VLOG(startup) << "Runtime::Start exiting";
}
void Runtime::DidForkFromZygote() {
is_zygote_ = false;
StartSignalCatcher();
// Start the JDWP thread. If the command-line debugger flags specified "suspend=y",
// this will pause the runtime, so we probably want this to come last.
Dbg::StartJdwp();
}
void Runtime::StartSignalCatcher() {
if (!is_zygote_) {
signal_catcher_ = new SignalCatcher(stack_trace_file_);
}
}
void Runtime::StartDaemonThreads() {
VLOG(startup) << "Runtime::StartDaemonThreads entering";
Thread* self = Thread::Current();
// Must be in the kNative state for calling native methods.
CHECK_EQ(self->GetState(), Thread::kNative);
JNIEnv* env = self->GetJniEnv();
ScopedLocalRef<jclass> c(env, env->FindClass("java/lang/Daemons"));
CHECK(c.get() != NULL);
jmethodID mid = env->GetStaticMethodID(c.get(), "start", "()V");
CHECK(mid != NULL);
env->CallStaticVoidMethod(c.get(), mid);
VLOG(startup) << "Runtime::StartDaemonThreads exiting";
}
bool Runtime::IsShuttingDown() const {
return shutting_down_;
}
bool Runtime::IsStarted() const {
return started_;
}
bool Runtime::Init(const Options& raw_options, bool ignore_unrecognized) {
CHECK_EQ(sysconf(_SC_PAGE_SIZE), kPageSize);
UniquePtr<ParsedOptions> options(ParsedOptions::Create(raw_options, ignore_unrecognized));
if (options.get() == NULL) {
LOG(ERROR) << "Failed to parse options";
return false;
}
VLOG(startup) << "Runtime::Init -verbose:startup enabled";
SetJniGlobalsMax(options->jni_globals_max_);
Monitor::Init(options->lock_profiling_threshold_, options->hook_is_sensitive_thread_);
host_prefix_ = options->host_prefix_;
boot_class_path_ = options->boot_class_path_;
class_path_ = options->class_path_;
properties_ = options->properties_;
is_zygote_ = options->is_zygote_;
vfprintf_ = options->hook_vfprintf_;
exit_ = options->hook_exit_;
abort_ = options->hook_abort_;
default_stack_size_ = options->stack_size_;
stack_trace_file_ = options->stack_trace_file_;
monitor_list_ = new MonitorList;
thread_list_ = new ThreadList;
intern_table_ = new InternTable;
Heap::Init(options->heap_initial_size_,
options->heap_maximum_size_,
options->heap_growth_limit_,
options->images_);
BlockSignals();
java_vm_ = new JavaVMExt(this, options.get());
Thread::Startup();
// ClassLinker needs an attached thread, but we can't fully attach a thread
// without creating objects.
Thread::Attach(this, "main", false);
// Set us to runnable so tools using a runtime can allocate and GC by default
Thread::Current()->SetState(Thread::kRunnable);
CHECK_GE(Heap::GetSpaces().size(), 1U);
class_linker_ = ((Heap::GetSpaces()[0]->IsImageSpace())
? ClassLinker::Create(intern_table_)
: ClassLinker::Create(options->boot_class_path_, intern_table_));
VLOG(startup) << "Runtime::Init exiting";
return true;
}
void Runtime::InitNativeMethods() {
VLOG(startup) << "Runtime::InitNativeMethods entering";
Thread* self = Thread::Current();
JNIEnv* env = self->GetJniEnv();
// Must be in the kNative state for calling native methods (JNI_OnLoad code).
CHECK_EQ(self->GetState(), Thread::kNative);
// First set up JniConstants, which is used by both the runtime's built-in native
// methods and libcore.
JniConstants::init(env);
// Then set up the native methods provided by the runtime itself.
RegisterRuntimeNativeMethods(env);
// Then set up libcore, which is just a regular JNI library with a regular JNI_OnLoad.
// Most JNI libraries can just use System.loadLibrary, but libcore can't because it's
// the library that implements System.loadLibrary!
LoadJniLibrary(instance_->GetJavaVM(), "javacore");
VLOG(startup) << "Runtime::InitNativeMethods exiting";
}
void Runtime::RegisterRuntimeNativeMethods(JNIEnv* env) {
#define REGISTER(FN) extern void FN(JNIEnv*); FN(env)
REGISTER(register_dalvik_system_DexFile);
REGISTER(register_dalvik_system_VMDebug);
REGISTER(register_dalvik_system_VMRuntime);
REGISTER(register_dalvik_system_VMStack);
REGISTER(register_dalvik_system_Zygote);
REGISTER(register_java_lang_Class);
REGISTER(register_java_lang_Object);
REGISTER(register_java_lang_Runtime);
REGISTER(register_java_lang_String);
REGISTER(register_java_lang_System);
REGISTER(register_java_lang_Thread);
REGISTER(register_java_lang_Throwable);
REGISTER(register_java_lang_VMClassLoader);
REGISTER(register_java_lang_reflect_Array);
REGISTER(register_java_lang_reflect_Constructor);
REGISTER(register_java_lang_reflect_Field);
REGISTER(register_java_lang_reflect_Method);
REGISTER(register_java_lang_reflect_Proxy);
REGISTER(register_java_util_concurrent_atomic_AtomicLong);
REGISTER(register_org_apache_harmony_dalvik_ddmc_DdmServer);
REGISTER(register_org_apache_harmony_dalvik_ddmc_DdmVmInternal);
REGISTER(register_sun_misc_Unsafe);
#undef REGISTER
}
void Runtime::Dump(std::ostream& os) {
// TODO: dump other runtime statistics?
GetClassLinker()->DumpForSigQuit(os);
GetInternTable()->DumpForSigQuit(os);
os << "\n";
thread_list_->Dump(os);
}
void Runtime::DumpLockHolders(std::ostream& os) {
pid_t heap_lock_owner = Heap::GetLockOwner();
pid_t thread_list_lock_owner = GetThreadList()->GetLockOwner();
pid_t classes_lock_owner = GetClassLinker()->GetClassesLockOwner();
pid_t dex_lock_owner = GetClassLinker()->GetDexLockOwner();
if ((heap_lock_owner | thread_list_lock_owner | classes_lock_owner | dex_lock_owner) != 0) {
os << "Heap lock owner tid: " << heap_lock_owner << "\n"
<< "ThreadList lock owner tid: " << thread_list_lock_owner << "\n"
<< "ClassLinker classes lock owner tid: " << classes_lock_owner << "\n"
<< "ClassLinker dex lock owner tid: " << dex_lock_owner << "\n";
}
}
void Runtime::SetStatsEnabled(bool new_state) {
if (new_state == true) {
GetStats()->Clear(~0);
// TODO: wouldn't it make more sense to clear _all_ threads' stats?
Thread::Current()->GetStats()->Clear(~0);
}
stats_enabled_ = new_state;
}
void Runtime::ResetStats(int kinds) {
GetStats()->Clear(kinds & 0xffff);
// TODO: wouldn't it make more sense to clear _all_ threads' stats?
Thread::Current()->GetStats()->Clear(kinds >> 16);
}
RuntimeStats* Runtime::GetStats() {
return &stats_;
}
int32_t Runtime::GetStat(int kind) {
RuntimeStats* stats;
if (kind < (1<<16)) {
stats = GetStats();
} else {
stats = Thread::Current()->GetStats();
kind >>= 16;
}
switch (kind) {
case KIND_ALLOCATED_OBJECTS:
return stats->allocated_objects;
case KIND_ALLOCATED_BYTES:
return stats->allocated_bytes;
case KIND_FREED_OBJECTS:
return stats->freed_objects;
case KIND_FREED_BYTES:
return stats->freed_bytes;
case KIND_GC_INVOCATIONS:
return stats->gc_for_alloc_count;
case KIND_CLASS_INIT_COUNT:
return stats->class_init_count;
case KIND_CLASS_INIT_TIME:
// Convert ns to us, reduce to 32 bits.
return (int) (stats->class_init_time_ns / 1000);
case KIND_EXT_ALLOCATED_OBJECTS:
case KIND_EXT_ALLOCATED_BYTES:
case KIND_EXT_FREED_OBJECTS:
case KIND_EXT_FREED_BYTES:
return 0; // backward compatibility
default:
CHECK(false);
return -1; // unreachable
}
}
void Runtime::BlockSignals() {
sigset_t sigset;
if (sigemptyset(&sigset) == -1) {
PLOG(FATAL) << "sigemptyset failed";
}
if (sigaddset(&sigset, SIGPIPE) == -1) {
PLOG(ERROR) << "sigaddset SIGPIPE failed";
}
// SIGQUIT is used to dump the runtime's state (including stack traces).
if (sigaddset(&sigset, SIGQUIT) == -1) {
PLOG(ERROR) << "sigaddset SIGQUIT failed";
}
// SIGUSR1 is used to initiate a heap dump.
if (sigaddset(&sigset, SIGUSR1) == -1) {
PLOG(ERROR) << "sigaddset SIGUSR1 failed";
}
CHECK_EQ(sigprocmask(SIG_BLOCK, &sigset, NULL), 0);
}
void Runtime::AttachCurrentThread(const char* name, bool as_daemon) {
Thread::Attach(instance_, name, as_daemon);
}
void Runtime::DetachCurrentThread() {
// TODO: check we're not calling DetachCurrentThread from a call stack that
// includes managed frames. (It's only valid if the stack is all-native.)
thread_list_->Unregister();
}
void Runtime::VisitRoots(Heap::RootVisitor* visitor, void* arg) const {
Dbg::VisitRoots(visitor, arg);
class_linker_->VisitRoots(visitor, arg);
intern_table_->VisitRoots(visitor, arg);
java_vm_->VisitRoots(visitor, arg);
thread_list_->VisitRoots(visitor, arg);
visitor(jni_stub_array_, arg);
visitor(abstract_method_error_stub_array_, arg);
for (int i = 0; i < Runtime::kLastTrampolineMethodType; i++) {
visitor(resolution_stub_array_[i], arg);
}
for (int i = 0; i < Runtime::kLastCalleeSaveType; i++) {
visitor(callee_save_method_[i], arg);
}
}
bool Runtime::HasJniDlsymLookupStub() const {
return jni_stub_array_ != NULL;
}
ByteArray* Runtime::GetJniDlsymLookupStub() const {
CHECK(jni_stub_array_ != NULL);
return jni_stub_array_;
}
void Runtime::SetJniDlsymLookupStub(ByteArray* jni_stub_array) {
CHECK(jni_stub_array != NULL) << " jni_stub_array=" << jni_stub_array;
CHECK(jni_stub_array_ == NULL || jni_stub_array_ == jni_stub_array)
<< "jni_stub_array_=" << jni_stub_array_ << " jni_stub_array=" << jni_stub_array;
jni_stub_array_ = jni_stub_array;
}
bool Runtime::HasAbstractMethodErrorStubArray() const {
return abstract_method_error_stub_array_ != NULL;
}
ByteArray* Runtime::GetAbstractMethodErrorStubArray() const {
CHECK(abstract_method_error_stub_array_ != NULL);
return abstract_method_error_stub_array_;
}
void Runtime::SetAbstractMethodErrorStubArray(ByteArray* abstract_method_error_stub_array) {
CHECK(abstract_method_error_stub_array != NULL);
CHECK(abstract_method_error_stub_array_ == NULL || abstract_method_error_stub_array_ == abstract_method_error_stub_array);
abstract_method_error_stub_array_ = abstract_method_error_stub_array;
}
Runtime::TrampolineType Runtime::GetTrampolineType(Method* method) {
if (method == NULL) {
return Runtime::kUnknownMethod;
} else if (method->IsStatic()) {
return Runtime::kStaticMethod;
} else {
return Runtime::kInstanceMethod;
}
}
bool Runtime::HasResolutionStubArray(TrampolineType type) const {
return resolution_stub_array_[type] != NULL;
}
ByteArray* Runtime::GetResolutionStubArray(TrampolineType type) const {
CHECK(HasResolutionStubArray(type));
DCHECK_LT(static_cast<int>(type), static_cast<int>(kLastTrampolineMethodType));
return resolution_stub_array_[type];
}
void Runtime::SetResolutionStubArray(ByteArray* resolution_stub_array, TrampolineType type) {
CHECK(resolution_stub_array != NULL);
CHECK(!HasResolutionStubArray(type) || resolution_stub_array_[type] == resolution_stub_array);
resolution_stub_array_[type] = resolution_stub_array;
}
Method* Runtime::CreateCalleeSaveMethod(InstructionSet instruction_set, CalleeSaveType type) {
Class* method_class = Method::GetMethodClass();
SirtRef<Method> method(down_cast<Method*>(method_class->AllocObject()));
method->SetDeclaringClass(method_class);
// TODO: use a special method for callee saves
method->SetMethodIndex(DexFile::kDexNoIndex16);
method->SetCode(NULL);
if ((instruction_set == kThumb2) || (instruction_set == kArm)) {
uint32_t ref_spills = (1 << art::arm::R5) | (1 << art::arm::R6) | (1 << art::arm::R7) |
(1 << art::arm::R8) | (1 << art::arm::R10) | (1 << art::arm::R11);
uint32_t arg_spills = (1 << art::arm::R1) | (1 << art::arm::R2) | (1 << art::arm::R3);
uint32_t all_spills = (1 << art::arm::R4) | (1 << art::arm::R9);
uint32_t core_spills = ref_spills | (type == kRefsAndArgs ? arg_spills :0) |
(type == kSaveAll ? all_spills :0) | (1 << art::arm::LR);
uint32_t fp_all_spills = (1 << art::arm::S0) | (1 << art::arm::S1) | (1 << art::arm::S2) |
(1 << art::arm::S3) | (1 << art::arm::S4) | (1 << art::arm::S5) |
(1 << art::arm::S6) | (1 << art::arm::S7) | (1 << art::arm::S8) |
(1 << art::arm::S9) | (1 << art::arm::S10) | (1 << art::arm::S11) |
(1 << art::arm::S12) | (1 << art::arm::S13) | (1 << art::arm::S14) |
(1 << art::arm::S15) | (1 << art::arm::S16) | (1 << art::arm::S17) |
(1 << art::arm::S18) | (1 << art::arm::S19) | (1 << art::arm::S20) |
(1 << art::arm::S21) | (1 << art::arm::S22) | (1 << art::arm::S23) |
(1 << art::arm::S24) | (1 << art::arm::S25) | (1 << art::arm::S26) |
(1 << art::arm::S27) | (1 << art::arm::S28) | (1 << art::arm::S29) |
(1 << art::arm::S30) | (1 << art::arm::S31);
uint32_t fp_spills = type == kSaveAll ? fp_all_spills : 0;
size_t frame_size = RoundUp((__builtin_popcount(core_spills) /* gprs */ +
__builtin_popcount(fp_spills) /* fprs */ +
1 /* Method* */) * kPointerSize, kStackAlignment);
method->SetFrameSizeInBytes(frame_size);
method->SetCoreSpillMask(core_spills);
method->SetFpSpillMask(fp_spills);
} else if (instruction_set == kX86) {
method->SetFrameSizeInBytes(32);
method->SetCoreSpillMask((1 << art::x86::EBX) | (1 << art::x86::EBP) | (1 << art::x86::ESI) |
(1 << art::x86::EDI));
method->SetFpSpillMask(0);
} else {
UNIMPLEMENTED(FATAL);
}
return method.get();
}
bool Runtime::HasCalleeSaveMethod(CalleeSaveType type) const {
return callee_save_method_[type] != NULL;
}
// Returns a special method that describes all callee saves being spilled to the stack.
Method* Runtime::GetCalleeSaveMethod(CalleeSaveType type) const {
CHECK(HasCalleeSaveMethod(type));
return callee_save_method_[type];
}
void Runtime::SetCalleeSaveMethod(Method* method, CalleeSaveType type) {
DCHECK_LT(static_cast<int>(type), static_cast<int>(kLastCalleeSaveType));
callee_save_method_[type] = method;
}
void Runtime::EnableMethodTracing(Trace* tracer) {
CHECK(!IsMethodTracingActive());
tracer_ = tracer;
}
void Runtime::DisableMethodTracing() {
CHECK(IsMethodTracingActive());
delete tracer_;
tracer_ = NULL;
}
bool Runtime::IsMethodTracingActive() const {
return (tracer_ != NULL);
}
Trace* Runtime::GetTracer() const {
CHECK(IsMethodTracingActive());
return tracer_;
}
} // namespace art