blob: 313190c84db48ab1f9996963171f2fcb210517a0 [file] [log] [blame]
/*
* Copyright (C) 2011 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.
*/
#include "utils.h"
#include <inttypes.h>
#include <pthread.h>
#include <sys/stat.h>
#include <sys/syscall.h>
#include <sys/types.h>
#include <sys/wait.h>
#include <unistd.h>
#include <memory>
#include "art_field-inl.h"
#include "art_method-inl.h"
#include "base/stl_util.h"
#include "base/unix_file/fd_file.h"
#include "dex_file-inl.h"
#include "dex_instruction.h"
#include "mirror/class-inl.h"
#include "mirror/class_loader.h"
#include "mirror/object-inl.h"
#include "mirror/object_array-inl.h"
#include "mirror/string.h"
#include "oat_quick_method_header.h"
#include "os.h"
#include "scoped_thread_state_change.h"
#include "utf-inl.h"
#if defined(__APPLE__)
#include "AvailabilityMacros.h" // For MAC_OS_X_VERSION_MAX_ALLOWED
#include <sys/syscall.h>
#endif
#if defined(__linux__)
#include <linux/unistd.h>
#endif
namespace art {
pid_t GetTid() {
#if defined(__APPLE__)
uint64_t owner;
CHECK_PTHREAD_CALL(pthread_threadid_np, (nullptr, &owner), __FUNCTION__); // Requires Mac OS 10.6
return owner;
#elif defined(__BIONIC__)
return gettid();
#else
return syscall(__NR_gettid);
#endif
}
std::string GetThreadName(pid_t tid) {
std::string result;
if (ReadFileToString(StringPrintf("/proc/self/task/%d/comm", tid), &result)) {
result.resize(result.size() - 1); // Lose the trailing '\n'.
} else {
result = "<unknown>";
}
return result;
}
void GetThreadStack(pthread_t thread, void** stack_base, size_t* stack_size, size_t* guard_size) {
#if defined(__APPLE__)
*stack_size = pthread_get_stacksize_np(thread);
void* stack_addr = pthread_get_stackaddr_np(thread);
// Check whether stack_addr is the base or end of the stack.
// (On Mac OS 10.7, it's the end.)
int stack_variable;
if (stack_addr > &stack_variable) {
*stack_base = reinterpret_cast<uint8_t*>(stack_addr) - *stack_size;
} else {
*stack_base = stack_addr;
}
// This is wrong, but there doesn't seem to be a way to get the actual value on the Mac.
pthread_attr_t attributes;
CHECK_PTHREAD_CALL(pthread_attr_init, (&attributes), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_getguardsize, (&attributes, guard_size), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_destroy, (&attributes), __FUNCTION__);
#else
pthread_attr_t attributes;
CHECK_PTHREAD_CALL(pthread_getattr_np, (thread, &attributes), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_getstack, (&attributes, stack_base, stack_size), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_getguardsize, (&attributes, guard_size), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_destroy, (&attributes), __FUNCTION__);
#if defined(__GLIBC__)
// If we're the main thread, check whether we were run with an unlimited stack. In that case,
// glibc will have reported a 2GB stack for our 32-bit process, and our stack overflow detection
// will be broken because we'll die long before we get close to 2GB.
bool is_main_thread = (::art::GetTid() == getpid());
if (is_main_thread) {
rlimit stack_limit;
if (getrlimit(RLIMIT_STACK, &stack_limit) == -1) {
PLOG(FATAL) << "getrlimit(RLIMIT_STACK) failed";
}
if (stack_limit.rlim_cur == RLIM_INFINITY) {
size_t old_stack_size = *stack_size;
// Use the kernel default limit as our size, and adjust the base to match.
*stack_size = 8 * MB;
*stack_base = reinterpret_cast<uint8_t*>(*stack_base) + (old_stack_size - *stack_size);
VLOG(threads) << "Limiting unlimited stack (reported as " << PrettySize(old_stack_size) << ")"
<< " to " << PrettySize(*stack_size)
<< " with base " << *stack_base;
}
}
#endif
#endif
}
bool ReadFileToString(const std::string& file_name, std::string* result) {
File file(file_name, O_RDONLY, false);
if (!file.IsOpened()) {
return false;
}
std::vector<char> buf(8 * KB);
while (true) {
int64_t n = TEMP_FAILURE_RETRY(read(file.Fd(), &buf[0], buf.size()));
if (n == -1) {
return false;
}
if (n == 0) {
return true;
}
result->append(&buf[0], n);
}
}
bool PrintFileToLog(const std::string& file_name, LogSeverity level) {
File file(file_name, O_RDONLY, false);
if (!file.IsOpened()) {
return false;
}
constexpr size_t kBufSize = 256; // Small buffer. Avoid stack overflow and stack size warnings.
char buf[kBufSize + 1]; // +1 for terminator.
size_t filled_to = 0;
while (true) {
DCHECK_LT(filled_to, kBufSize);
int64_t n = TEMP_FAILURE_RETRY(read(file.Fd(), &buf[filled_to], kBufSize - filled_to));
if (n <= 0) {
// Print the rest of the buffer, if it exists.
if (filled_to > 0) {
buf[filled_to] = 0;
LOG(level) << buf;
}
return n == 0;
}
// Scan for '\n'.
size_t i = filled_to;
bool found_newline = false;
for (; i < filled_to + n; ++i) {
if (buf[i] == '\n') {
// Found a line break, that's something to print now.
buf[i] = 0;
LOG(level) << buf;
// Copy the rest to the front.
if (i + 1 < filled_to + n) {
memmove(&buf[0], &buf[i + 1], filled_to + n - i - 1);
filled_to = filled_to + n - i - 1;
} else {
filled_to = 0;
}
found_newline = true;
break;
}
}
if (found_newline) {
continue;
} else {
filled_to += n;
// Check if we must flush now.
if (filled_to == kBufSize) {
buf[kBufSize] = 0;
LOG(level) << buf;
filled_to = 0;
}
}
}
}
std::string PrettyDescriptor(mirror::String* java_descriptor) {
if (java_descriptor == nullptr) {
return "null";
}
return PrettyDescriptor(java_descriptor->ToModifiedUtf8().c_str());
}
std::string PrettyDescriptor(mirror::Class* klass) {
if (klass == nullptr) {
return "null";
}
std::string temp;
return PrettyDescriptor(klass->GetDescriptor(&temp));
}
std::string PrettyDescriptor(const char* descriptor) {
// Count the number of '['s to get the dimensionality.
const char* c = descriptor;
size_t dim = 0;
while (*c == '[') {
dim++;
c++;
}
// Reference or primitive?
if (*c == 'L') {
// "[[La/b/C;" -> "a.b.C[][]".
c++; // Skip the 'L'.
} else {
// "[[B" -> "byte[][]".
// To make life easier, we make primitives look like unqualified
// reference types.
switch (*c) {
case 'B': c = "byte;"; break;
case 'C': c = "char;"; break;
case 'D': c = "double;"; break;
case 'F': c = "float;"; break;
case 'I': c = "int;"; break;
case 'J': c = "long;"; break;
case 'S': c = "short;"; break;
case 'Z': c = "boolean;"; break;
case 'V': c = "void;"; break; // Used when decoding return types.
default: return descriptor;
}
}
// At this point, 'c' is a string of the form "fully/qualified/Type;"
// or "primitive;". Rewrite the type with '.' instead of '/':
std::string result;
const char* p = c;
while (*p != ';') {
char ch = *p++;
if (ch == '/') {
ch = '.';
}
result.push_back(ch);
}
// ...and replace the semicolon with 'dim' "[]" pairs:
for (size_t i = 0; i < dim; ++i) {
result += "[]";
}
return result;
}
std::string PrettyField(ArtField* f, bool with_type) {
if (f == nullptr) {
return "null";
}
std::string result;
if (with_type) {
result += PrettyDescriptor(f->GetTypeDescriptor());
result += ' ';
}
std::string temp;
result += PrettyDescriptor(f->GetDeclaringClass()->GetDescriptor(&temp));
result += '.';
result += f->GetName();
return result;
}
std::string PrettyField(uint32_t field_idx, const DexFile& dex_file, bool with_type) {
if (field_idx >= dex_file.NumFieldIds()) {
return StringPrintf("<<invalid-field-idx-%d>>", field_idx);
}
const DexFile::FieldId& field_id = dex_file.GetFieldId(field_idx);
std::string result;
if (with_type) {
result += dex_file.GetFieldTypeDescriptor(field_id);
result += ' ';
}
result += PrettyDescriptor(dex_file.GetFieldDeclaringClassDescriptor(field_id));
result += '.';
result += dex_file.GetFieldName(field_id);
return result;
}
std::string PrettyType(uint32_t type_idx, const DexFile& dex_file) {
if (type_idx >= dex_file.NumTypeIds()) {
return StringPrintf("<<invalid-type-idx-%d>>", type_idx);
}
const DexFile::TypeId& type_id = dex_file.GetTypeId(type_idx);
return PrettyDescriptor(dex_file.GetTypeDescriptor(type_id));
}
std::string PrettyArguments(const char* signature) {
std::string result;
result += '(';
CHECK_EQ(*signature, '(');
++signature; // Skip the '('.
while (*signature != ')') {
size_t argument_length = 0;
while (signature[argument_length] == '[') {
++argument_length;
}
if (signature[argument_length] == 'L') {
argument_length = (strchr(signature, ';') - signature + 1);
} else {
++argument_length;
}
{
std::string argument_descriptor(signature, argument_length);
result += PrettyDescriptor(argument_descriptor.c_str());
}
if (signature[argument_length] != ')') {
result += ", ";
}
signature += argument_length;
}
CHECK_EQ(*signature, ')');
++signature; // Skip the ')'.
result += ')';
return result;
}
std::string PrettyReturnType(const char* signature) {
const char* return_type = strchr(signature, ')');
CHECK(return_type != nullptr);
++return_type; // Skip ')'.
return PrettyDescriptor(return_type);
}
std::string PrettyMethod(ArtMethod* m, bool with_signature) {
if (m == nullptr) {
return "null";
}
if (!m->IsRuntimeMethod()) {
m = m->GetInterfaceMethodIfProxy(Runtime::Current()->GetClassLinker()->GetImagePointerSize());
}
std::string result(PrettyDescriptor(m->GetDeclaringClassDescriptor()));
result += '.';
result += m->GetName();
if (UNLIKELY(m->IsFastNative())) {
result += "!";
}
if (with_signature) {
const Signature signature = m->GetSignature();
std::string sig_as_string(signature.ToString());
if (signature == Signature::NoSignature()) {
return result + sig_as_string;
}
result = PrettyReturnType(sig_as_string.c_str()) + " " + result +
PrettyArguments(sig_as_string.c_str());
}
return result;
}
std::string PrettyMethod(uint32_t method_idx, const DexFile& dex_file, bool with_signature) {
if (method_idx >= dex_file.NumMethodIds()) {
return StringPrintf("<<invalid-method-idx-%d>>", method_idx);
}
const DexFile::MethodId& method_id = dex_file.GetMethodId(method_idx);
std::string result(PrettyDescriptor(dex_file.GetMethodDeclaringClassDescriptor(method_id)));
result += '.';
result += dex_file.GetMethodName(method_id);
if (with_signature) {
const Signature signature = dex_file.GetMethodSignature(method_id);
std::string sig_as_string(signature.ToString());
if (signature == Signature::NoSignature()) {
return result + sig_as_string;
}
result = PrettyReturnType(sig_as_string.c_str()) + " " + result +
PrettyArguments(sig_as_string.c_str());
}
return result;
}
std::string PrettyTypeOf(mirror::Object* obj) {
if (obj == nullptr) {
return "null";
}
if (obj->GetClass() == nullptr) {
return "(raw)";
}
std::string temp;
std::string result(PrettyDescriptor(obj->GetClass()->GetDescriptor(&temp)));
if (obj->IsClass()) {
result += "<" + PrettyDescriptor(obj->AsClass()->GetDescriptor(&temp)) + ">";
}
return result;
}
std::string PrettyClass(mirror::Class* c) {
if (c == nullptr) {
return "null";
}
std::string result;
result += "java.lang.Class<";
result += PrettyDescriptor(c);
result += ">";
return result;
}
std::string PrettyClassAndClassLoader(mirror::Class* c) {
if (c == nullptr) {
return "null";
}
std::string result;
result += "java.lang.Class<";
result += PrettyDescriptor(c);
result += ",";
result += PrettyTypeOf(c->GetClassLoader());
// TODO: add an identifying hash value for the loader
result += ">";
return result;
}
std::string PrettyJavaAccessFlags(uint32_t access_flags) {
std::string result;
if ((access_flags & kAccPublic) != 0) {
result += "public ";
}
if ((access_flags & kAccProtected) != 0) {
result += "protected ";
}
if ((access_flags & kAccPrivate) != 0) {
result += "private ";
}
if ((access_flags & kAccFinal) != 0) {
result += "final ";
}
if ((access_flags & kAccStatic) != 0) {
result += "static ";
}
if ((access_flags & kAccTransient) != 0) {
result += "transient ";
}
if ((access_flags & kAccVolatile) != 0) {
result += "volatile ";
}
if ((access_flags & kAccSynchronized) != 0) {
result += "synchronized ";
}
return result;
}
std::string PrettySize(int64_t byte_count) {
// The byte thresholds at which we display amounts. A byte count is displayed
// in unit U when kUnitThresholds[U] <= bytes < kUnitThresholds[U+1].
static const int64_t kUnitThresholds[] = {
0, // B up to...
3*1024, // KB up to...
2*1024*1024, // MB up to...
1024*1024*1024 // GB from here.
};
static const int64_t kBytesPerUnit[] = { 1, KB, MB, GB };
static const char* const kUnitStrings[] = { "B", "KB", "MB", "GB" };
const char* negative_str = "";
if (byte_count < 0) {
negative_str = "-";
byte_count = -byte_count;
}
int i = arraysize(kUnitThresholds);
while (--i > 0) {
if (byte_count >= kUnitThresholds[i]) {
break;
}
}
return StringPrintf("%s%" PRId64 "%s",
negative_str, byte_count / kBytesPerUnit[i], kUnitStrings[i]);
}
std::string PrintableChar(uint16_t ch) {
std::string result;
result += '\'';
if (NeedsEscaping(ch)) {
StringAppendF(&result, "\\u%04x", ch);
} else {
result += ch;
}
result += '\'';
return result;
}
std::string PrintableString(const char* utf) {
std::string result;
result += '"';
const char* p = utf;
size_t char_count = CountModifiedUtf8Chars(p);
for (size_t i = 0; i < char_count; ++i) {
uint32_t ch = GetUtf16FromUtf8(&p);
if (ch == '\\') {
result += "\\\\";
} else if (ch == '\n') {
result += "\\n";
} else if (ch == '\r') {
result += "\\r";
} else if (ch == '\t') {
result += "\\t";
} else {
const uint16_t leading = GetLeadingUtf16Char(ch);
if (NeedsEscaping(leading)) {
StringAppendF(&result, "\\u%04x", leading);
} else {
result += leading;
}
const uint32_t trailing = GetTrailingUtf16Char(ch);
if (trailing != 0) {
// All high surrogates will need escaping.
StringAppendF(&result, "\\u%04x", trailing);
}
}
}
result += '"';
return result;
}
// See http://java.sun.com/j2se/1.5.0/docs/guide/jni/spec/design.html#wp615 for the full rules.
std::string MangleForJni(const std::string& s) {
std::string result;
size_t char_count = CountModifiedUtf8Chars(s.c_str());
const char* cp = &s[0];
for (size_t i = 0; i < char_count; ++i) {
uint32_t ch = GetUtf16FromUtf8(&cp);
if ((ch >= 'A' && ch <= 'Z') || (ch >= 'a' && ch <= 'z') || (ch >= '0' && ch <= '9')) {
result.push_back(ch);
} else if (ch == '.' || ch == '/') {
result += "_";
} else if (ch == '_') {
result += "_1";
} else if (ch == ';') {
result += "_2";
} else if (ch == '[') {
result += "_3";
} else {
const uint16_t leading = GetLeadingUtf16Char(ch);
const uint32_t trailing = GetTrailingUtf16Char(ch);
StringAppendF(&result, "_0%04x", leading);
if (trailing != 0) {
StringAppendF(&result, "_0%04x", trailing);
}
}
}
return result;
}
std::string DotToDescriptor(const char* class_name) {
std::string descriptor(class_name);
std::replace(descriptor.begin(), descriptor.end(), '.', '/');
if (descriptor.length() > 0 && descriptor[0] != '[') {
descriptor = "L" + descriptor + ";";
}
return descriptor;
}
std::string DescriptorToDot(const char* descriptor) {
size_t length = strlen(descriptor);
if (length > 1) {
if (descriptor[0] == 'L' && descriptor[length - 1] == ';') {
// Descriptors have the leading 'L' and trailing ';' stripped.
std::string result(descriptor + 1, length - 2);
std::replace(result.begin(), result.end(), '/', '.');
return result;
} else {
// For arrays the 'L' and ';' remain intact.
std::string result(descriptor);
std::replace(result.begin(), result.end(), '/', '.');
return result;
}
}
// Do nothing for non-class/array descriptors.
return descriptor;
}
std::string DescriptorToName(const char* descriptor) {
size_t length = strlen(descriptor);
if (descriptor[0] == 'L' && descriptor[length - 1] == ';') {
std::string result(descriptor + 1, length - 2);
return result;
}
return descriptor;
}
std::string JniShortName(ArtMethod* m) {
std::string class_name(m->GetDeclaringClassDescriptor());
// Remove the leading 'L' and trailing ';'...
CHECK_EQ(class_name[0], 'L') << class_name;
CHECK_EQ(class_name[class_name.size() - 1], ';') << class_name;
class_name.erase(0, 1);
class_name.erase(class_name.size() - 1, 1);
std::string method_name(m->GetName());
std::string short_name;
short_name += "Java_";
short_name += MangleForJni(class_name);
short_name += "_";
short_name += MangleForJni(method_name);
return short_name;
}
std::string JniLongName(ArtMethod* m) {
std::string long_name;
long_name += JniShortName(m);
long_name += "__";
std::string signature(m->GetSignature().ToString());
signature.erase(0, 1);
signature.erase(signature.begin() + signature.find(')'), signature.end());
long_name += MangleForJni(signature);
return long_name;
}
// Helper for IsValidPartOfMemberNameUtf8(), a bit vector indicating valid low ascii.
uint32_t DEX_MEMBER_VALID_LOW_ASCII[4] = {
0x00000000, // 00..1f low control characters; nothing valid
0x03ff2010, // 20..3f digits and symbols; valid: '0'..'9', '$', '-'
0x87fffffe, // 40..5f uppercase etc.; valid: 'A'..'Z', '_'
0x07fffffe // 60..7f lowercase etc.; valid: 'a'..'z'
};
// Helper for IsValidPartOfMemberNameUtf8(); do not call directly.
bool IsValidPartOfMemberNameUtf8Slow(const char** pUtf8Ptr) {
/*
* It's a multibyte encoded character. Decode it and analyze. We
* accept anything that isn't (a) an improperly encoded low value,
* (b) an improper surrogate pair, (c) an encoded '\0', (d) a high
* control character, or (e) a high space, layout, or special
* character (U+00a0, U+2000..U+200f, U+2028..U+202f,
* U+fff0..U+ffff). This is all specified in the dex format
* document.
*/
const uint32_t pair = GetUtf16FromUtf8(pUtf8Ptr);
const uint16_t leading = GetLeadingUtf16Char(pair);
// We have a surrogate pair resulting from a valid 4 byte UTF sequence.
// No further checks are necessary because 4 byte sequences span code
// points [U+10000, U+1FFFFF], which are valid codepoints in a dex
// identifier. Furthermore, GetUtf16FromUtf8 guarantees that each of
// the surrogate halves are valid and well formed in this instance.
if (GetTrailingUtf16Char(pair) != 0) {
return true;
}
// We've encountered a one, two or three byte UTF-8 sequence. The
// three byte UTF-8 sequence could be one half of a surrogate pair.
switch (leading >> 8) {
case 0x00:
// It's only valid if it's above the ISO-8859-1 high space (0xa0).
return (leading > 0x00a0);
case 0xd8:
case 0xd9:
case 0xda:
case 0xdb:
{
// We found a three byte sequence encoding one half of a surrogate.
// Look for the other half.
const uint32_t pair2 = GetUtf16FromUtf8(pUtf8Ptr);
const uint16_t trailing = GetLeadingUtf16Char(pair2);
return (GetTrailingUtf16Char(pair2) == 0) && (0xdc00 <= trailing && trailing <= 0xdfff);
}
case 0xdc:
case 0xdd:
case 0xde:
case 0xdf:
// It's a trailing surrogate, which is not valid at this point.
return false;
case 0x20:
case 0xff:
// It's in the range that has spaces, controls, and specials.
switch (leading & 0xfff8) {
case 0x2000:
case 0x2008:
case 0x2028:
case 0xfff0:
case 0xfff8:
return false;
}
return true;
default:
return true;
}
UNREACHABLE();
}
/* Return whether the pointed-at modified-UTF-8 encoded character is
* valid as part of a member name, updating the pointer to point past
* the consumed character. This will consume two encoded UTF-16 code
* points if the character is encoded as a surrogate pair. Also, if
* this function returns false, then the given pointer may only have
* been partially advanced.
*/
static bool IsValidPartOfMemberNameUtf8(const char** pUtf8Ptr) {
uint8_t c = (uint8_t) **pUtf8Ptr;
if (LIKELY(c <= 0x7f)) {
// It's low-ascii, so check the table.
uint32_t wordIdx = c >> 5;
uint32_t bitIdx = c & 0x1f;
(*pUtf8Ptr)++;
return (DEX_MEMBER_VALID_LOW_ASCII[wordIdx] & (1 << bitIdx)) != 0;
}
// It's a multibyte encoded character. Call a non-inline function
// for the heavy lifting.
return IsValidPartOfMemberNameUtf8Slow(pUtf8Ptr);
}
bool IsValidMemberName(const char* s) {
bool angle_name = false;
switch (*s) {
case '\0':
// The empty string is not a valid name.
return false;
case '<':
angle_name = true;
s++;
break;
}
while (true) {
switch (*s) {
case '\0':
return !angle_name;
case '>':
return angle_name && s[1] == '\0';
}
if (!IsValidPartOfMemberNameUtf8(&s)) {
return false;
}
}
}
enum ClassNameType { kName, kDescriptor };
template<ClassNameType kType, char kSeparator>
static bool IsValidClassName(const char* s) {
int arrayCount = 0;
while (*s == '[') {
arrayCount++;
s++;
}
if (arrayCount > 255) {
// Arrays may have no more than 255 dimensions.
return false;
}
ClassNameType type = kType;
if (type != kDescriptor && arrayCount != 0) {
/*
* If we're looking at an array of some sort, then it doesn't
* matter if what is being asked for is a class name; the
* format looks the same as a type descriptor in that case, so
* treat it as such.
*/
type = kDescriptor;
}
if (type == kDescriptor) {
/*
* We are looking for a descriptor. Either validate it as a
* single-character primitive type, or continue on to check the
* embedded class name (bracketed by "L" and ";").
*/
switch (*(s++)) {
case 'B':
case 'C':
case 'D':
case 'F':
case 'I':
case 'J':
case 'S':
case 'Z':
// These are all single-character descriptors for primitive types.
return (*s == '\0');
case 'V':
// Non-array void is valid, but you can't have an array of void.
return (arrayCount == 0) && (*s == '\0');
case 'L':
// Class name: Break out and continue below.
break;
default:
// Oddball descriptor character.
return false;
}
}
/*
* We just consumed the 'L' that introduces a class name as part
* of a type descriptor, or we are looking for an unadorned class
* name.
*/
bool sepOrFirst = true; // first character or just encountered a separator.
for (;;) {
uint8_t c = (uint8_t) *s;
switch (c) {
case '\0':
/*
* Premature end for a type descriptor, but valid for
* a class name as long as we haven't encountered an
* empty component (including the degenerate case of
* the empty string "").
*/
return (type == kName) && !sepOrFirst;
case ';':
/*
* Invalid character for a class name, but the
* legitimate end of a type descriptor. In the latter
* case, make sure that this is the end of the string
* and that it doesn't end with an empty component
* (including the degenerate case of "L;").
*/
return (type == kDescriptor) && !sepOrFirst && (s[1] == '\0');
case '/':
case '.':
if (c != kSeparator) {
// The wrong separator character.
return false;
}
if (sepOrFirst) {
// Separator at start or two separators in a row.
return false;
}
sepOrFirst = true;
s++;
break;
default:
if (!IsValidPartOfMemberNameUtf8(&s)) {
return false;
}
sepOrFirst = false;
break;
}
}
}
bool IsValidBinaryClassName(const char* s) {
return IsValidClassName<kName, '.'>(s);
}
bool IsValidJniClassName(const char* s) {
return IsValidClassName<kName, '/'>(s);
}
bool IsValidDescriptor(const char* s) {
return IsValidClassName<kDescriptor, '/'>(s);
}
void Split(const std::string& s, char separator, std::vector<std::string>* result) {
const char* p = s.data();
const char* end = p + s.size();
while (p != end) {
if (*p == separator) {
++p;
} else {
const char* start = p;
while (++p != end && *p != separator) {
// Skip to the next occurrence of the separator.
}
result->push_back(std::string(start, p - start));
}
}
}
std::string Trim(const std::string& s) {
std::string result;
unsigned int start_index = 0;
unsigned int end_index = s.size() - 1;
// Skip initial whitespace.
while (start_index < s.size()) {
if (!isspace(s[start_index])) {
break;
}
start_index++;
}
// Skip terminating whitespace.
while (end_index >= start_index) {
if (!isspace(s[end_index])) {
break;
}
end_index--;
}
// All spaces, no beef.
if (end_index < start_index) {
return "";
}
// Start_index is the first non-space, end_index is the last one.
return s.substr(start_index, end_index - start_index + 1);
}
template <typename StringT>
std::string Join(const std::vector<StringT>& strings, char separator) {
if (strings.empty()) {
return "";
}
std::string result(strings[0]);
for (size_t i = 1; i < strings.size(); ++i) {
result += separator;
result += strings[i];
}
return result;
}
// Explicit instantiations.
template std::string Join<std::string>(const std::vector<std::string>& strings, char separator);
template std::string Join<const char*>(const std::vector<const char*>& strings, char separator);
bool StartsWith(const std::string& s, const char* prefix) {
return s.compare(0, strlen(prefix), prefix) == 0;
}
bool EndsWith(const std::string& s, const char* suffix) {
size_t suffix_length = strlen(suffix);
size_t string_length = s.size();
if (suffix_length > string_length) {
return false;
}
size_t offset = string_length - suffix_length;
return s.compare(offset, suffix_length, suffix) == 0;
}
void SetThreadName(const char* thread_name) {
int hasAt = 0;
int hasDot = 0;
const char* s = thread_name;
while (*s) {
if (*s == '.') {
hasDot = 1;
} else if (*s == '@') {
hasAt = 1;
}
s++;
}
int len = s - thread_name;
if (len < 15 || hasAt || !hasDot) {
s = thread_name;
} else {
s = thread_name + len - 15;
}
#if defined(__linux__)
// pthread_setname_np fails rather than truncating long strings.
char buf[16]; // MAX_TASK_COMM_LEN=16 is hard-coded in the kernel.
strncpy(buf, s, sizeof(buf)-1);
buf[sizeof(buf)-1] = '\0';
errno = pthread_setname_np(pthread_self(), buf);
if (errno != 0) {
PLOG(WARNING) << "Unable to set the name of current thread to '" << buf << "'";
}
#else // __APPLE__
pthread_setname_np(thread_name);
#endif
}
void GetTaskStats(pid_t tid, char* state, int* utime, int* stime, int* task_cpu) {
*utime = *stime = *task_cpu = 0;
std::string stats;
if (!ReadFileToString(StringPrintf("/proc/self/task/%d/stat", tid), &stats)) {
return;
}
// Skip the command, which may contain spaces.
stats = stats.substr(stats.find(')') + 2);
// Extract the three fields we care about.
std::vector<std::string> fields;
Split(stats, ' ', &fields);
*state = fields[0][0];
*utime = strtoull(fields[11].c_str(), nullptr, 10);
*stime = strtoull(fields[12].c_str(), nullptr, 10);
*task_cpu = strtoull(fields[36].c_str(), nullptr, 10);
}
std::string GetSchedulerGroupName(pid_t tid) {
// /proc/<pid>/cgroup looks like this:
// 2:devices:/
// 1:cpuacct,cpu:/
// We want the third field from the line whose second field contains the "cpu" token.
std::string cgroup_file;
if (!ReadFileToString(StringPrintf("/proc/self/task/%d/cgroup", tid), &cgroup_file)) {
return "";
}
std::vector<std::string> cgroup_lines;
Split(cgroup_file, '\n', &cgroup_lines);
for (size_t i = 0; i < cgroup_lines.size(); ++i) {
std::vector<std::string> cgroup_fields;
Split(cgroup_lines[i], ':', &cgroup_fields);
std::vector<std::string> cgroups;
Split(cgroup_fields[1], ',', &cgroups);
for (size_t j = 0; j < cgroups.size(); ++j) {
if (cgroups[j] == "cpu") {
return cgroup_fields[2].substr(1); // Skip the leading slash.
}
}
}
return "";
}
const char* GetAndroidRoot() {
const char* android_root = getenv("ANDROID_ROOT");
if (android_root == nullptr) {
if (OS::DirectoryExists("/system")) {
android_root = "/system";
} else {
LOG(FATAL) << "ANDROID_ROOT not set and /system does not exist";
return "";
}
}
if (!OS::DirectoryExists(android_root)) {
LOG(FATAL) << "Failed to find ANDROID_ROOT directory " << android_root;
return "";
}
return android_root;
}
const char* GetAndroidData() {
std::string error_msg;
const char* dir = GetAndroidDataSafe(&error_msg);
if (dir != nullptr) {
return dir;
} else {
LOG(FATAL) << error_msg;
return "";
}
}
const char* GetAndroidDataSafe(std::string* error_msg) {
const char* android_data = getenv("ANDROID_DATA");
if (android_data == nullptr) {
if (OS::DirectoryExists("/data")) {
android_data = "/data";
} else {
*error_msg = "ANDROID_DATA not set and /data does not exist";
return nullptr;
}
}
if (!OS::DirectoryExists(android_data)) {
*error_msg = StringPrintf("Failed to find ANDROID_DATA directory %s", android_data);
return nullptr;
}
return android_data;
}
void GetDalvikCache(const char* subdir, const bool create_if_absent, std::string* dalvik_cache,
bool* have_android_data, bool* dalvik_cache_exists, bool* is_global_cache) {
CHECK(subdir != nullptr);
std::string error_msg;
const char* android_data = GetAndroidDataSafe(&error_msg);
if (android_data == nullptr) {
*have_android_data = false;
*dalvik_cache_exists = false;
*is_global_cache = false;
return;
} else {
*have_android_data = true;
}
const std::string dalvik_cache_root(StringPrintf("%s/dalvik-cache/", android_data));
*dalvik_cache = dalvik_cache_root + subdir;
*dalvik_cache_exists = OS::DirectoryExists(dalvik_cache->c_str());
*is_global_cache = strcmp(android_data, "/data") == 0;
if (create_if_absent && !*dalvik_cache_exists && !*is_global_cache) {
// Don't create the system's /data/dalvik-cache/... because it needs special permissions.
*dalvik_cache_exists = ((mkdir(dalvik_cache_root.c_str(), 0700) == 0 || errno == EEXIST) &&
(mkdir(dalvik_cache->c_str(), 0700) == 0 || errno == EEXIST));
}
}
std::string GetDalvikCache(const char* subdir) {
CHECK(subdir != nullptr);
const char* android_data = GetAndroidData();
const std::string dalvik_cache_root(StringPrintf("%s/dalvik-cache/", android_data));
const std::string dalvik_cache = dalvik_cache_root + subdir;
if (!OS::DirectoryExists(dalvik_cache.c_str())) {
// TODO: Check callers. Traditional behavior is to not abort.
return "";
}
return dalvik_cache;
}
bool GetDalvikCacheFilename(const char* location, const char* cache_location,
std::string* filename, std::string* error_msg) {
if (location[0] != '/') {
*error_msg = StringPrintf("Expected path in location to be absolute: %s", location);
return false;
}
std::string cache_file(&location[1]); // skip leading slash
if (!EndsWith(location, ".dex") && !EndsWith(location, ".art") && !EndsWith(location, ".oat")) {
cache_file += "/";
cache_file += DexFile::kClassesDex;
}
std::replace(cache_file.begin(), cache_file.end(), '/', '@');
*filename = StringPrintf("%s/%s", cache_location, cache_file.c_str());
return true;
}
static void InsertIsaDirectory(const InstructionSet isa, std::string* filename) {
// in = /foo/bar/baz
// out = /foo/bar/<isa>/baz
size_t pos = filename->rfind('/');
CHECK_NE(pos, std::string::npos) << *filename << " " << isa;
filename->insert(pos, "/", 1);
filename->insert(pos + 1, GetInstructionSetString(isa));
}
std::string GetSystemImageFilename(const char* location, const InstructionSet isa) {
// location = /system/framework/boot.art
// filename = /system/framework/<isa>/boot.art
std::string filename(location);
InsertIsaDirectory(isa, &filename);
return filename;
}
int ExecAndReturnCode(std::vector<std::string>& arg_vector, std::string* error_msg) {
const std::string command_line(Join(arg_vector, ' '));
CHECK_GE(arg_vector.size(), 1U) << command_line;
// Convert the args to char pointers.
const char* program = arg_vector[0].c_str();
std::vector<char*> args;
for (size_t i = 0; i < arg_vector.size(); ++i) {
const std::string& arg = arg_vector[i];
char* arg_str = const_cast<char*>(arg.c_str());
CHECK(arg_str != nullptr) << i;
args.push_back(arg_str);
}
args.push_back(nullptr);
// fork and exec
pid_t pid = fork();
if (pid == 0) {
// no allocation allowed between fork and exec
// change process groups, so we don't get reaped by ProcessManager
setpgid(0, 0);
// (b/30160149): protect subprocesses from modifications to LD_LIBRARY_PATH, etc.
// Use the snapshot of the environment from the time the runtime was created.
char** envp = (Runtime::Current() == nullptr) ? nullptr : Runtime::Current()->GetEnvSnapshot();
if (envp == nullptr) {
execv(program, &args[0]);
} else {
execve(program, &args[0], envp);
}
PLOG(ERROR) << "Failed to execve(" << command_line << ")";
// _exit to avoid atexit handlers in child.
_exit(1);
} else {
if (pid == -1) {
*error_msg = StringPrintf("Failed to execv(%s) because fork failed: %s",
command_line.c_str(), strerror(errno));
return -1;
}
// wait for subprocess to finish
int status = -1;
pid_t got_pid = TEMP_FAILURE_RETRY(waitpid(pid, &status, 0));
if (got_pid != pid) {
*error_msg = StringPrintf("Failed after fork for execv(%s) because waitpid failed: "
"wanted %d, got %d: %s",
command_line.c_str(), pid, got_pid, strerror(errno));
return -1;
}
if (WIFEXITED(status)) {
return WEXITSTATUS(status);
}
return -1;
}
}
bool Exec(std::vector<std::string>& arg_vector, std::string* error_msg) {
int status = ExecAndReturnCode(arg_vector, error_msg);
if (status != 0) {
const std::string command_line(Join(arg_vector, ' '));
*error_msg = StringPrintf("Failed execv(%s) because non-0 exit status",
command_line.c_str());
return false;
}
return true;
}
bool FileExists(const std::string& filename) {
struct stat buffer;
return stat(filename.c_str(), &buffer) == 0;
}
bool FileExistsAndNotEmpty(const std::string& filename) {
struct stat buffer;
if (stat(filename.c_str(), &buffer) != 0) {
return false;
}
return buffer.st_size > 0;
}
std::string PrettyDescriptor(Primitive::Type type) {
return PrettyDescriptor(Primitive::Descriptor(type));
}
static void DumpMethodCFGImpl(const DexFile* dex_file,
uint32_t dex_method_idx,
const DexFile::CodeItem* code_item,
std::ostream& os) {
os << "digraph {\n";
os << " # /* " << PrettyMethod(dex_method_idx, *dex_file, true) << " */\n";
std::set<uint32_t> dex_pc_is_branch_target;
{
// Go and populate.
const Instruction* inst = Instruction::At(code_item->insns_);
for (uint32_t dex_pc = 0;
dex_pc < code_item->insns_size_in_code_units_;
dex_pc += inst->SizeInCodeUnits(), inst = inst->Next()) {
if (inst->IsBranch()) {
dex_pc_is_branch_target.insert(dex_pc + inst->GetTargetOffset());
} else if (inst->IsSwitch()) {
const uint16_t* insns = code_item->insns_ + dex_pc;
int32_t switch_offset = insns[1] | (static_cast<int32_t>(insns[2]) << 16);
const uint16_t* switch_insns = insns + switch_offset;
uint32_t switch_count = switch_insns[1];
int32_t targets_offset;
if ((*insns & 0xff) == Instruction::PACKED_SWITCH) {
/* 0=sig, 1=count, 2/3=firstKey */
targets_offset = 4;
} else {
/* 0=sig, 1=count, 2..count*2 = keys */
targets_offset = 2 + 2 * switch_count;
}
for (uint32_t targ = 0; targ < switch_count; targ++) {
int32_t offset =
static_cast<int32_t>(switch_insns[targets_offset + targ * 2]) |
static_cast<int32_t>(switch_insns[targets_offset + targ * 2 + 1] << 16);
dex_pc_is_branch_target.insert(dex_pc + offset);
}
}
}
}
// Create nodes for "basic blocks."
std::map<uint32_t, uint32_t> dex_pc_to_node_id; // This only has entries for block starts.
std::map<uint32_t, uint32_t> dex_pc_to_incl_id; // This has entries for all dex pcs.
{
const Instruction* inst = Instruction::At(code_item->insns_);
bool first_in_block = true;
bool force_new_block = false;
for (uint32_t dex_pc = 0;
dex_pc < code_item->insns_size_in_code_units_;
dex_pc += inst->SizeInCodeUnits(), inst = inst->Next()) {
if (dex_pc == 0 ||
(dex_pc_is_branch_target.find(dex_pc) != dex_pc_is_branch_target.end()) ||
force_new_block) {
uint32_t id = dex_pc_to_node_id.size();
if (id > 0) {
// End last node.
os << "}\"];\n";
}
// Start next node.
os << " node" << id << " [shape=record,label=\"{";
dex_pc_to_node_id.insert(std::make_pair(dex_pc, id));
first_in_block = true;
force_new_block = false;
}
// Register instruction.
dex_pc_to_incl_id.insert(std::make_pair(dex_pc, dex_pc_to_node_id.size() - 1));
// Print instruction.
if (!first_in_block) {
os << " | ";
} else {
first_in_block = false;
}
// Dump the instruction. Need to escape '"', '<', '>', '{' and '}'.
os << "<" << "p" << dex_pc << ">";
os << " 0x" << std::hex << dex_pc << std::dec << ": ";
std::string inst_str = inst->DumpString(dex_file);
size_t cur_start = 0; // It's OK to start at zero, instruction dumps don't start with chars
// we need to escape.
while (cur_start != std::string::npos) {
size_t next_escape = inst_str.find_first_of("\"{}<>", cur_start + 1);
if (next_escape == std::string::npos) {
os << inst_str.substr(cur_start, inst_str.size() - cur_start);
break;
} else {
os << inst_str.substr(cur_start, next_escape - cur_start);
// Escape all necessary characters.
while (next_escape < inst_str.size()) {
char c = inst_str.at(next_escape);
if (c == '"' || c == '{' || c == '}' || c == '<' || c == '>') {
os << '\\' << c;
} else {
break;
}
next_escape++;
}
if (next_escape >= inst_str.size()) {
next_escape = std::string::npos;
}
cur_start = next_escape;
}
}
// Force a new block for some fall-throughs and some instructions that terminate the "local"
// control flow.
force_new_block = inst->IsSwitch() || inst->IsBasicBlockEnd();
}
// Close last node.
if (dex_pc_to_node_id.size() > 0) {
os << "}\"];\n";
}
}
// Create edges between them.
{
std::ostringstream regular_edges;
std::ostringstream taken_edges;
std::ostringstream exception_edges;
// Common set of exception edges.
std::set<uint32_t> exception_targets;
// These blocks (given by the first dex pc) need exception per dex-pc handling in a second
// pass. In the first pass we try and see whether we can use a common set of edges.
std::set<uint32_t> blocks_with_detailed_exceptions;
{
uint32_t last_node_id = std::numeric_limits<uint32_t>::max();
uint32_t old_dex_pc = 0;
uint32_t block_start_dex_pc = std::numeric_limits<uint32_t>::max();
const Instruction* inst = Instruction::At(code_item->insns_);
for (uint32_t dex_pc = 0;
dex_pc < code_item->insns_size_in_code_units_;
old_dex_pc = dex_pc, dex_pc += inst->SizeInCodeUnits(), inst = inst->Next()) {
{
auto it = dex_pc_to_node_id.find(dex_pc);
if (it != dex_pc_to_node_id.end()) {
if (!exception_targets.empty()) {
// It seems the last block had common exception handlers. Add the exception edges now.
uint32_t node_id = dex_pc_to_node_id.find(block_start_dex_pc)->second;
for (uint32_t handler_pc : exception_targets) {
auto node_id_it = dex_pc_to_incl_id.find(handler_pc);
if (node_id_it != dex_pc_to_incl_id.end()) {
exception_edges << " node" << node_id
<< " -> node" << node_id_it->second << ":p" << handler_pc
<< ";\n";
}
}
exception_targets.clear();
}
block_start_dex_pc = dex_pc;
// Seems to be a fall-through, connect to last_node_id. May be spurious edges for things
// like switch data.
uint32_t old_last = last_node_id;
last_node_id = it->second;
if (old_last != std::numeric_limits<uint32_t>::max()) {
regular_edges << " node" << old_last << ":p" << old_dex_pc
<< " -> node" << last_node_id << ":p" << dex_pc
<< ";\n";
}
}
// Look at the exceptions of the first entry.
CatchHandlerIterator catch_it(*code_item, dex_pc);
for (; catch_it.HasNext(); catch_it.Next()) {
exception_targets.insert(catch_it.GetHandlerAddress());
}
}
// Handle instruction.
// Branch: something with at most two targets.
if (inst->IsBranch()) {
const int32_t offset = inst->GetTargetOffset();
const bool conditional = !inst->IsUnconditional();
auto target_it = dex_pc_to_node_id.find(dex_pc + offset);
if (target_it != dex_pc_to_node_id.end()) {
taken_edges << " node" << last_node_id << ":p" << dex_pc
<< " -> node" << target_it->second << ":p" << (dex_pc + offset)
<< ";\n";
}
if (!conditional) {
// No fall-through.
last_node_id = std::numeric_limits<uint32_t>::max();
}
} else if (inst->IsSwitch()) {
// TODO: Iterate through all switch targets.
const uint16_t* insns = code_item->insns_ + dex_pc;
/* make sure the start of the switch is in range */
int32_t switch_offset = insns[1] | (static_cast<int32_t>(insns[2]) << 16);
/* offset to switch table is a relative branch-style offset */
const uint16_t* switch_insns = insns + switch_offset;
uint32_t switch_count = switch_insns[1];
int32_t targets_offset;
if ((*insns & 0xff) == Instruction::PACKED_SWITCH) {
/* 0=sig, 1=count, 2/3=firstKey */
targets_offset = 4;
} else {
/* 0=sig, 1=count, 2..count*2 = keys */
targets_offset = 2 + 2 * switch_count;
}
/* make sure the end of the switch is in range */
/* verify each switch target */
for (uint32_t targ = 0; targ < switch_count; targ++) {
int32_t offset =
static_cast<int32_t>(switch_insns[targets_offset + targ * 2]) |
static_cast<int32_t>(switch_insns[targets_offset + targ * 2 + 1] << 16);
int32_t abs_offset = dex_pc + offset;
auto target_it = dex_pc_to_node_id.find(abs_offset);
if (target_it != dex_pc_to_node_id.end()) {
// TODO: value label.
taken_edges << " node" << last_node_id << ":p" << dex_pc
<< " -> node" << target_it->second << ":p" << (abs_offset)
<< ";\n";
}
}
}
// Exception edges. If this is not the first instruction in the block
if (block_start_dex_pc != dex_pc) {
std::set<uint32_t> current_handler_pcs;
CatchHandlerIterator catch_it(*code_item, dex_pc);
for (; catch_it.HasNext(); catch_it.Next()) {
current_handler_pcs.insert(catch_it.GetHandlerAddress());
}
if (current_handler_pcs != exception_targets) {
exception_targets.clear(); // Clear so we don't do something at the end.
blocks_with_detailed_exceptions.insert(block_start_dex_pc);
}
}
if (inst->IsReturn() ||
(inst->Opcode() == Instruction::THROW) ||
(inst->IsBranch() && inst->IsUnconditional())) {
// No fall-through.
last_node_id = std::numeric_limits<uint32_t>::max();
}
}
// Finish up the last block, if it had common exceptions.
if (!exception_targets.empty()) {
// It seems the last block had common exception handlers. Add the exception edges now.
uint32_t node_id = dex_pc_to_node_id.find(block_start_dex_pc)->second;
for (uint32_t handler_pc : exception_targets) {
auto node_id_it = dex_pc_to_incl_id.find(handler_pc);
if (node_id_it != dex_pc_to_incl_id.end()) {
exception_edges << " node" << node_id
<< " -> node" << node_id_it->second << ":p" << handler_pc
<< ";\n";
}
}
exception_targets.clear();
}
}
// Second pass for detailed exception blocks.
// TODO
// Exception edges. If this is not the first instruction in the block
for (uint32_t dex_pc : blocks_with_detailed_exceptions) {
const Instruction* inst = Instruction::At(&code_item->insns_[dex_pc]);
uint32_t this_node_id = dex_pc_to_incl_id.find(dex_pc)->second;
while (true) {
CatchHandlerIterator catch_it(*code_item, dex_pc);
if (catch_it.HasNext()) {
std::set<uint32_t> handled_targets;
for (; catch_it.HasNext(); catch_it.Next()) {
uint32_t handler_pc = catch_it.GetHandlerAddress();
auto it = handled_targets.find(handler_pc);
if (it == handled_targets.end()) {
auto node_id_it = dex_pc_to_incl_id.find(handler_pc);
if (node_id_it != dex_pc_to_incl_id.end()) {
exception_edges << " node" << this_node_id << ":p" << dex_pc
<< " -> node" << node_id_it->second << ":p" << handler_pc
<< ";\n";
}
// Mark as done.
handled_targets.insert(handler_pc);
}
}
}
if (inst->IsBasicBlockEnd()) {
break;
}
// Loop update. Have a break-out if the next instruction is a branch target and thus in
// another block.
dex_pc += inst->SizeInCodeUnits();
if (dex_pc >= code_item->insns_size_in_code_units_) {
break;
}
if (dex_pc_to_node_id.find(dex_pc) != dex_pc_to_node_id.end()) {
break;
}
inst = inst->Next();
}
}
// Write out the sub-graphs to make edges styled.
os << "\n";
os << " subgraph regular_edges {\n";
os << " edge [color=\"#000000\",weight=.3,len=3];\n\n";
os << " " << regular_edges.str() << "\n";
os << " }\n\n";
os << " subgraph taken_edges {\n";
os << " edge [color=\"#00FF00\",weight=.3,len=3];\n\n";
os << " " << taken_edges.str() << "\n";
os << " }\n\n";
os << " subgraph exception_edges {\n";
os << " edge [color=\"#FF0000\",weight=.3,len=3];\n\n";
os << " " << exception_edges.str() << "\n";
os << " }\n\n";
}
os << "}\n";
}
void DumpMethodCFG(ArtMethod* method, std::ostream& os) {
const DexFile* dex_file = method->GetDexFile();
const DexFile::CodeItem* code_item = dex_file->GetCodeItem(method->GetCodeItemOffset());
DumpMethodCFGImpl(dex_file, method->GetDexMethodIndex(), code_item, os);
}
void DumpMethodCFG(const DexFile* dex_file, uint32_t dex_method_idx, std::ostream& os) {
// This is painful, we need to find the code item. That means finding the class, and then
// iterating the table.
if (dex_method_idx >= dex_file->NumMethodIds()) {
os << "Could not find method-idx.";
return;
}
const DexFile::MethodId& method_id = dex_file->GetMethodId(dex_method_idx);
const DexFile::ClassDef* class_def = dex_file->FindClassDef(method_id.class_idx_);
if (class_def == nullptr) {
os << "Could not find class-def.";
return;
}
const uint8_t* class_data = dex_file->GetClassData(*class_def);
if (class_data == nullptr) {
os << "No class data.";
return;
}
ClassDataItemIterator it(*dex_file, class_data);
// Skip fields
while (it.HasNextStaticField() || it.HasNextInstanceField()) {
it.Next();
}
// Find method, and dump it.
while (it.HasNextDirectMethod() || it.HasNextVirtualMethod()) {
uint32_t method_idx = it.GetMemberIndex();
if (method_idx == dex_method_idx) {
DumpMethodCFGImpl(dex_file, dex_method_idx, it.GetMethodCodeItem(), os);
return;
}
it.Next();
}
// Otherwise complain.
os << "Something went wrong, didn't find the method in the class data.";
}
static void ParseStringAfterChar(const std::string& s,
char c,
std::string* parsed_value,
UsageFn Usage) {
std::string::size_type colon = s.find(c);
if (colon == std::string::npos) {
Usage("Missing char %c in option %s\n", c, s.c_str());
}
// Add one to remove the char we were trimming until.
*parsed_value = s.substr(colon + 1);
}
void ParseDouble(const std::string& option,
char after_char,
double min,
double max,
double* parsed_value,
UsageFn Usage) {
std::string substring;
ParseStringAfterChar(option, after_char, &substring, Usage);
bool sane_val = true;
double value;
if ((false)) {
// TODO: this doesn't seem to work on the emulator. b/15114595
std::stringstream iss(substring);
iss >> value;
// Ensure that we have a value, there was no cruft after it and it satisfies a sensible range.
sane_val = iss.eof() && (value >= min) && (value <= max);
} else {
char* end = nullptr;
value = strtod(substring.c_str(), &end);
sane_val = *end == '\0' && value >= min && value <= max;
}
if (!sane_val) {
Usage("Invalid double value %s for option %s\n", substring.c_str(), option.c_str());
}
*parsed_value = value;
}
int64_t GetFileSizeBytes(const std::string& filename) {
struct stat stat_buf;
int rc = stat(filename.c_str(), &stat_buf);
return rc == 0 ? stat_buf.st_size : -1;
}
void SleepForever() {
while (true) {
usleep(1000000);
}
}
} // namespace art