/*
* Copyright (C) 2007 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.
*/
#define LOG_TAG "android.os.Debug"
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <malloc.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/time.h>
#include <time.h>
#include <unistd.h>
#include <atomic>
#include <iomanip>
#include <string>
#include <android-base/stringprintf.h>
#include <android-base/unique_fd.h>
#include <debuggerd/client.h>
#include <log/log.h>
#include <utils/misc.h>
#include <utils/String8.h>
#include <nativehelper/JNIHelp.h>
#include <nativehelper/ScopedUtfChars.h>
#include "jni.h"
#include <memtrack/memtrack.h>
#include <memunreachable/memunreachable.h>
#include "android_os_Debug.h"
namespace android
{
static inline UniqueFile MakeUniqueFile(const char* path, const char* mode) {
return UniqueFile(fopen(path, mode), safeFclose);
}
enum {
HEAP_UNKNOWN,
HEAP_DALVIK,
HEAP_NATIVE,
HEAP_DALVIK_OTHER,
HEAP_STACK,
HEAP_CURSOR,
HEAP_ASHMEM,
HEAP_GL_DEV,
HEAP_UNKNOWN_DEV,
HEAP_SO,
HEAP_JAR,
HEAP_APK,
HEAP_TTF,
HEAP_DEX,
HEAP_OAT,
HEAP_ART,
HEAP_UNKNOWN_MAP,
HEAP_GRAPHICS,
HEAP_GL,
HEAP_OTHER_MEMTRACK,
// Dalvik extra sections (heap).
HEAP_DALVIK_NORMAL,
HEAP_DALVIK_LARGE,
HEAP_DALVIK_ZYGOTE,
HEAP_DALVIK_NON_MOVING,
// Dalvik other extra sections.
HEAP_DALVIK_OTHER_LINEARALLOC,
HEAP_DALVIK_OTHER_ACCOUNTING,
HEAP_DALVIK_OTHER_CODE_CACHE,
HEAP_DALVIK_OTHER_COMPILER_METADATA,
HEAP_DALVIK_OTHER_INDIRECT_REFERENCE_TABLE,
// Boot vdex / app dex / app vdex
HEAP_DEX_BOOT_VDEX,
HEAP_DEX_APP_DEX,
HEAP_DEX_APP_VDEX,
// App art, boot art.
HEAP_ART_APP,
HEAP_ART_BOOT,
_NUM_HEAP,
_NUM_EXCLUSIVE_HEAP = HEAP_OTHER_MEMTRACK+1,
_NUM_CORE_HEAP = HEAP_NATIVE+1
};
struct stat_fields {
jfieldID pss_field;
jfieldID pssSwappable_field;
jfieldID rss_field;
jfieldID privateDirty_field;
jfieldID sharedDirty_field;
jfieldID privateClean_field;
jfieldID sharedClean_field;
jfieldID swappedOut_field;
jfieldID swappedOutPss_field;
};
struct stat_field_names {
const char* pss_name;
const char* pssSwappable_name;
const char* rss_name;
const char* privateDirty_name;
const char* sharedDirty_name;
const char* privateClean_name;
const char* sharedClean_name;
const char* swappedOut_name;
const char* swappedOutPss_name;
};
static stat_fields stat_fields[_NUM_CORE_HEAP];
static stat_field_names stat_field_names[_NUM_CORE_HEAP] = {
{ "otherPss", "otherSwappablePss", "otherRss", "otherPrivateDirty", "otherSharedDirty",
"otherPrivateClean", "otherSharedClean", "otherSwappedOut", "otherSwappedOutPss" },
{ "dalvikPss", "dalvikSwappablePss", "dalvikRss", "dalvikPrivateDirty", "dalvikSharedDirty",
"dalvikPrivateClean", "dalvikSharedClean", "dalvikSwappedOut", "dalvikSwappedOutPss" },
{ "nativePss", "nativeSwappablePss", "nativeRss", "nativePrivateDirty", "nativeSharedDirty",
"nativePrivateClean", "nativeSharedClean", "nativeSwappedOut", "nativeSwappedOutPss" }
};
jfieldID otherStats_field;
jfieldID hasSwappedOutPss_field;
struct stats_t {
int pss;
int swappablePss;
int rss;
int privateDirty;
int sharedDirty;
int privateClean;
int sharedClean;
int swappedOut;
int swappedOutPss;
};
enum pss_rollup_support {
PSS_ROLLUP_UNTRIED,
PSS_ROLLUP_SUPPORTED,
PSS_ROLLUP_UNSUPPORTED
};
static std::atomic<pss_rollup_support> g_pss_rollup_support;
#define BINDER_STATS "/proc/binder/stats"
static jlong android_os_Debug_getNativeHeapSize(JNIEnv *env, jobject clazz)
{
struct mallinfo info = mallinfo();
return (jlong) info.usmblks;
}
static jlong android_os_Debug_getNativeHeapAllocatedSize(JNIEnv *env, jobject clazz)
{
struct mallinfo info = mallinfo();
return (jlong) info.uordblks;
}
static jlong android_os_Debug_getNativeHeapFreeSize(JNIEnv *env, jobject clazz)
{
struct mallinfo info = mallinfo();
return (jlong) info.fordblks;
}
// Container used to retrieve graphics memory pss
struct graphics_memory_pss
{
int graphics;
int gl;
int other;
};
/*
* Uses libmemtrack to retrieve graphics memory that the process is using.
* Any graphics memory reported in /proc/pid/smaps is not included here.
*/
static int read_memtrack_memory(struct memtrack_proc* p, int pid,
struct graphics_memory_pss* graphics_mem)
{
int err = memtrack_proc_get(p, pid);
if (err != 0) {
ALOGW("failed to get memory consumption info: %d", err);
return err;
}
ssize_t pss = memtrack_proc_graphics_pss(p);
if (pss < 0) {
ALOGW("failed to get graphics pss: %zd", pss);
return pss;
}
graphics_mem->graphics = pss / 1024;
pss = memtrack_proc_gl_pss(p);
if (pss < 0) {
ALOGW("failed to get gl pss: %zd", pss);
return pss;
}
graphics_mem->gl = pss / 1024;
pss = memtrack_proc_other_pss(p);
if (pss < 0) {
ALOGW("failed to get other pss: %zd", pss);
return pss;
}
graphics_mem->other = pss / 1024;
return 0;
}
/*
* Retrieves the graphics memory that is unaccounted for in /proc/pid/smaps.
*/
static int read_memtrack_memory(int pid, struct graphics_memory_pss* graphics_mem)
{
struct memtrack_proc* p = memtrack_proc_new();
if (p == NULL) {
ALOGW("failed to create memtrack_proc");
return -1;
}
int err = read_memtrack_memory(p, pid, graphics_mem);
memtrack_proc_destroy(p);
return err;
}
static void read_mapinfo(FILE *fp, stats_t* stats, bool* foundSwapPss)
{
char line[1024];
int len, nameLen;
bool skip, done = false;
unsigned pss = 0, swappable_pss = 0, rss = 0;
float sharing_proportion = 0.0;
unsigned shared_clean = 0, shared_dirty = 0;
unsigned private_clean = 0, private_dirty = 0;
unsigned swapped_out = 0, swapped_out_pss = 0;
bool is_swappable = false;
unsigned temp;
uint64_t start;
uint64_t end = 0;
uint64_t prevEnd = 0;
char* name;
int name_pos;
int whichHeap = HEAP_UNKNOWN;
int subHeap = HEAP_UNKNOWN;
int prevHeap = HEAP_UNKNOWN;
*foundSwapPss = false;
if(fgets(line, sizeof(line), fp) == 0) return;
while (!done) {
prevHeap = whichHeap;
prevEnd = end;
whichHeap = HEAP_UNKNOWN;
subHeap = HEAP_UNKNOWN;
skip = false;
is_swappable = false;
len = strlen(line);
if (len < 1) return;
line[--len] = 0;
if (sscanf(line, "%" SCNx64 "-%" SCNx64 " %*s %*x %*x:%*x %*d%n", &start, &end, &name_pos) != 2) {
skip = true;
} else {
while (isspace(line[name_pos])) {
name_pos += 1;
}
name = line + name_pos;
nameLen = strlen(name);
// Trim the end of the line if it is " (deleted)".
const char* deleted_str = " (deleted)";
if (nameLen > (int)strlen(deleted_str) &&
strcmp(name+nameLen-strlen(deleted_str), deleted_str) == 0) {
nameLen -= strlen(deleted_str);
name[nameLen] = '\0';
}
if ((strstr(name, "[heap]") == name)) {
whichHeap = HEAP_NATIVE;
} else if (strncmp(name, "[anon:libc_malloc]", 18) == 0) {
whichHeap = HEAP_NATIVE;
} else if (strncmp(name, "[stack", 6) == 0) {
whichHeap = HEAP_STACK;
} else if (nameLen > 3 && strcmp(name+nameLen-3, ".so") == 0) {
whichHeap = HEAP_SO;
is_swappable = true;
} else if (nameLen > 4 && strcmp(name+nameLen-4, ".jar") == 0) {
whichHeap = HEAP_JAR;
is_swappable = true;
} else if (nameLen > 4 && strcmp(name+nameLen-4, ".apk") == 0) {
whichHeap = HEAP_APK;
is_swappable = true;
} else if (nameLen > 4 && strcmp(name+nameLen-4, ".ttf") == 0) {
whichHeap = HEAP_TTF;
is_swappable = true;
} else if ((nameLen > 4 && strstr(name, ".dex") != NULL) ||
(nameLen > 5 && strcmp(name+nameLen-5, ".odex") == 0)) {
whichHeap = HEAP_DEX;
subHeap = HEAP_DEX_APP_DEX;
is_swappable = true;
} else if (nameLen > 5 && strcmp(name+nameLen-5, ".vdex") == 0) {
whichHeap = HEAP_DEX;
// Handle system@framework@boot* and system/framework/boot*
if (strstr(name, "@boot") != NULL || strstr(name, "/boot") != NULL) {
subHeap = HEAP_DEX_BOOT_VDEX;
} else {
subHeap = HEAP_DEX_APP_VDEX;
}
is_swappable = true;
} else if (nameLen > 4 && strcmp(name+nameLen-4, ".oat") == 0) {
whichHeap = HEAP_OAT;
is_swappable = true;
} else if (nameLen > 4 && strcmp(name+nameLen-4, ".art") == 0) {
whichHeap = HEAP_ART;
// Handle system@framework@boot* and system/framework/boot*
if (strstr(name, "@boot") != NULL || strstr(name, "/boot") != NULL) {
subHeap = HEAP_ART_BOOT;
} else {
subHeap = HEAP_ART_APP;
}
is_swappable = true;
} else if (strncmp(name, "/dev/", 5) == 0) {
if (strncmp(name, "/dev/kgsl-3d0", 13) == 0) {
whichHeap = HEAP_GL_DEV;
} else if (strncmp(name, "/dev/ashmem", 11) == 0) {
if (strncmp(name, "/dev/ashmem/dalvik-", 19) == 0) {
whichHeap = HEAP_DALVIK_OTHER;
if (strstr(name, "/dev/ashmem/dalvik-LinearAlloc") == name) {
subHeap = HEAP_DALVIK_OTHER_LINEARALLOC;
} else if ((strstr(name, "/dev/ashmem/dalvik-alloc space") == name) ||
(strstr(name, "/dev/ashmem/dalvik-main space") == name)) {
// This is the regular Dalvik heap.
whichHeap = HEAP_DALVIK;
subHeap = HEAP_DALVIK_NORMAL;
} else if (strstr(name, "/dev/ashmem/dalvik-large object space") == name ||
strstr(name, "/dev/ashmem/dalvik-free list large object space")
== name) {
whichHeap = HEAP_DALVIK;
subHeap = HEAP_DALVIK_LARGE;
} else if (strstr(name, "/dev/ashmem/dalvik-non moving space") == name) {
whichHeap = HEAP_DALVIK;
subHeap = HEAP_DALVIK_NON_MOVING;
} else if (strstr(name, "/dev/ashmem/dalvik-zygote space") == name) {
whichHeap = HEAP_DALVIK;
subHeap = HEAP_DALVIK_ZYGOTE;
} else if (strstr(name, "/dev/ashmem/dalvik-indirect ref") == name) {
subHeap = HEAP_DALVIK_OTHER_INDIRECT_REFERENCE_TABLE;
} else if (strstr(name, "/dev/ashmem/dalvik-jit-code-cache") == name ||
strstr(name, "/dev/ashmem/dalvik-data-code-cache") == name) {
subHeap = HEAP_DALVIK_OTHER_CODE_CACHE;
} else if (strstr(name, "/dev/ashmem/dalvik-CompilerMetadata") == name) {
subHeap = HEAP_DALVIK_OTHER_COMPILER_METADATA;
} else {
subHeap = HEAP_DALVIK_OTHER_ACCOUNTING; // Default to accounting.
}
} else if (strncmp(name, "/dev/ashmem/CursorWindow", 24) == 0) {
whichHeap = HEAP_CURSOR;
} else if (strncmp(name, "/dev/ashmem/libc malloc", 23) == 0) {
whichHeap = HEAP_NATIVE;
} else {
whichHeap = HEAP_ASHMEM;
}
} else {
whichHeap = HEAP_UNKNOWN_DEV;
}
} else if (strncmp(name, "[anon:", 6) == 0) {
whichHeap = HEAP_UNKNOWN;
} else if (nameLen > 0) {
whichHeap = HEAP_UNKNOWN_MAP;
} else if (start == prevEnd && prevHeap == HEAP_SO) {
// bss section of a shared library.
whichHeap = HEAP_SO;
}
}
//ALOGI("native=%d dalvik=%d sqlite=%d: %s\n", isNativeHeap, isDalvikHeap,
// isSqliteHeap, line);
shared_clean = 0;
shared_dirty = 0;
private_clean = 0;
private_dirty = 0;
swapped_out = 0;
swapped_out_pss = 0;
while (true) {
if (fgets(line, 1024, fp) == 0) {
done = true;
break;
}
if (line[0] == 'S' && sscanf(line, "Size: %d kB", &temp) == 1) {
/* size = temp; */
} else if (line[0] == 'R' && sscanf(line, "Rss: %d kB", &temp) == 1) {
rss = temp;
} else if (line[0] == 'P' && sscanf(line, "Pss: %d kB", &temp) == 1) {
pss = temp;
} else if (line[0] == 'S' && sscanf(line, "Shared_Clean: %d kB", &temp) == 1) {
shared_clean = temp;
} else if (line[0] == 'S' && sscanf(line, "Shared_Dirty: %d kB", &temp) == 1) {
shared_dirty = temp;
} else if (line[0] == 'P' && sscanf(line, "Private_Clean: %d kB", &temp) == 1) {
private_clean = temp;
} else if (line[0] == 'P' && sscanf(line, "Private_Dirty: %d kB", &temp) == 1) {
private_dirty = temp;
} else if (line[0] == 'R' && sscanf(line, "Referenced: %d kB", &temp) == 1) {
/* referenced = temp; */
} else if (line[0] == 'S' && sscanf(line, "Swap: %d kB", &temp) == 1) {
swapped_out = temp;
} else if (line[0] == 'S' && sscanf(line, "SwapPss: %d kB", &temp) == 1) {
*foundSwapPss = true;
swapped_out_pss = temp;
} else if (sscanf(line, "%" SCNx64 "-%" SCNx64 " %*s %*x %*x:%*x %*d", &start, &end) == 2) {
// looks like a new mapping
// example: "10000000-10001000 ---p 10000000 00:00 0"
break;
}
}
if (!skip) {
if (is_swappable && (pss > 0)) {
sharing_proportion = 0.0;
if ((shared_clean > 0) || (shared_dirty > 0)) {
sharing_proportion = (pss - private_clean
- private_dirty)/(shared_clean+shared_dirty);
}
swappable_pss = (sharing_proportion*shared_clean) + private_clean;
} else
swappable_pss = 0;
stats[whichHeap].pss += pss;
stats[whichHeap].swappablePss += swappable_pss;
stats[whichHeap].rss += rss;
stats[whichHeap].privateDirty += private_dirty;
stats[whichHeap].sharedDirty += shared_dirty;
stats[whichHeap].privateClean += private_clean;
stats[whichHeap].sharedClean += shared_clean;
stats[whichHeap].swappedOut += swapped_out;
stats[whichHeap].swappedOutPss += swapped_out_pss;
if (whichHeap == HEAP_DALVIK || whichHeap == HEAP_DALVIK_OTHER ||
whichHeap == HEAP_DEX || whichHeap == HEAP_ART) {
stats[subHeap].pss += pss;
stats[subHeap].swappablePss += swappable_pss;
stats[subHeap].rss += rss;
stats[subHeap].privateDirty += private_dirty;
stats[subHeap].sharedDirty += shared_dirty;
stats[subHeap].privateClean += private_clean;
stats[subHeap].sharedClean += shared_clean;
stats[subHeap].swappedOut += swapped_out;
stats[subHeap].swappedOutPss += swapped_out_pss;
}
}
}
}
static void load_maps(int pid, stats_t* stats, bool* foundSwapPss)
{
*foundSwapPss = false;
std::string smaps_path = base::StringPrintf("/proc/%d/smaps", pid);
UniqueFile fp = MakeUniqueFile(smaps_path.c_str(), "re");
if (fp == nullptr) return;
read_mapinfo(fp.get(), stats, foundSwapPss);
}
static void android_os_Debug_getDirtyPagesPid(JNIEnv *env, jobject clazz,
jint pid, jobject object)
{
bool foundSwapPss;
stats_t stats[_NUM_HEAP];
memset(&stats, 0, sizeof(stats));
load_maps(pid, stats, &foundSwapPss);
struct graphics_memory_pss graphics_mem;
if (read_memtrack_memory(pid, &graphics_mem) == 0) {
stats[HEAP_GRAPHICS].pss = graphics_mem.graphics;
stats[HEAP_GRAPHICS].privateDirty = graphics_mem.graphics;
stats[HEAP_GRAPHICS].rss = graphics_mem.graphics;
stats[HEAP_GL].pss = graphics_mem.gl;
stats[HEAP_GL].privateDirty = graphics_mem.gl;
stats[HEAP_GL].rss = graphics_mem.gl;
stats[HEAP_OTHER_MEMTRACK].pss = graphics_mem.other;
stats[HEAP_OTHER_MEMTRACK].privateDirty = graphics_mem.other;
stats[HEAP_OTHER_MEMTRACK].rss = graphics_mem.other;
}
for (int i=_NUM_CORE_HEAP; i<_NUM_EXCLUSIVE_HEAP; i++) {
stats[HEAP_UNKNOWN].pss += stats[i].pss;
stats[HEAP_UNKNOWN].swappablePss += stats[i].swappablePss;
stats[HEAP_UNKNOWN].rss += stats[i].rss;
stats[HEAP_UNKNOWN].privateDirty += stats[i].privateDirty;
stats[HEAP_UNKNOWN].sharedDirty += stats[i].sharedDirty;
stats[HEAP_UNKNOWN].privateClean += stats[i].privateClean;
stats[HEAP_UNKNOWN].sharedClean += stats[i].sharedClean;
stats[HEAP_UNKNOWN].swappedOut += stats[i].swappedOut;
stats[HEAP_UNKNOWN].swappedOutPss += stats[i].swappedOutPss;
}
for (int i=0; i<_NUM_CORE_HEAP; i++) {
env->SetIntField(object, stat_fields[i].pss_field, stats[i].pss);
env->SetIntField(object, stat_fields[i].pssSwappable_field, stats[i].swappablePss);
env->SetIntField(object, stat_fields[i].rss_field, stats[i].rss);
env->SetIntField(object, stat_fields[i].privateDirty_field, stats[i].privateDirty);
env->SetIntField(object, stat_fields[i].sharedDirty_field, stats[i].sharedDirty);
env->SetIntField(object, stat_fields[i].privateClean_field, stats[i].privateClean);
env->SetIntField(object, stat_fields[i].sharedClean_field, stats[i].sharedClean);
env->SetIntField(object, stat_fields[i].swappedOut_field, stats[i].swappedOut);
env->SetIntField(object, stat_fields[i].swappedOutPss_field, stats[i].swappedOutPss);
}
env->SetBooleanField(object, hasSwappedOutPss_field, foundSwapPss);
jintArray otherIntArray = (jintArray)env->GetObjectField(object, otherStats_field);
jint* otherArray = (jint*)env->GetPrimitiveArrayCritical(otherIntArray, 0);
if (otherArray == NULL) {
return;
}
int j=0;
for (int i=_NUM_CORE_HEAP; i<_NUM_HEAP; i++) {
otherArray[j++] = stats[i].pss;
otherArray[j++] = stats[i].swappablePss;
otherArray[j++] = stats[i].rss;
otherArray[j++] = stats[i].privateDirty;
otherArray[j++] = stats[i].sharedDirty;
otherArray[j++] = stats[i].privateClean;
otherArray[j++] = stats[i].sharedClean;
otherArray[j++] = stats[i].swappedOut;
otherArray[j++] = stats[i].swappedOutPss;
}
env->ReleasePrimitiveArrayCritical(otherIntArray, otherArray, 0);
}
static void android_os_Debug_getDirtyPages(JNIEnv *env, jobject clazz, jobject object)
{
android_os_Debug_getDirtyPagesPid(env, clazz, getpid(), object);
}
UniqueFile OpenSmapsOrRollup(int pid)
{
enum pss_rollup_support rollup_support =
g_pss_rollup_support.load(std::memory_order_relaxed);
if (rollup_support != PSS_ROLLUP_UNSUPPORTED) {
std::string smaps_rollup_path =
base::StringPrintf("/proc/%d/smaps_rollup", pid);
UniqueFile fp_rollup = MakeUniqueFile(smaps_rollup_path.c_str(), "re");
if (fp_rollup == nullptr && errno != ENOENT) {
return fp_rollup; // Actual error, not just old kernel.
}
if (fp_rollup != nullptr) {
if (rollup_support == PSS_ROLLUP_UNTRIED) {
ALOGI("using rollup pss collection");
g_pss_rollup_support.store(PSS_ROLLUP_SUPPORTED,
std::memory_order_relaxed);
}
return fp_rollup;
}
g_pss_rollup_support.store(PSS_ROLLUP_UNSUPPORTED,
std::memory_order_relaxed);
}
std::string smaps_path = base::StringPrintf("/proc/%d/smaps", pid);
return MakeUniqueFile(smaps_path.c_str(), "re");
}
static jlong android_os_Debug_getPssPid(JNIEnv *env, jobject clazz, jint pid,
jlongArray outUssSwapPssRss, jlongArray outMemtrack)
{
char lineBuffer[1024];
jlong pss = 0;
jlong rss = 0;
jlong swapPss = 0;
jlong uss = 0;
jlong memtrack = 0;
struct graphics_memory_pss graphics_mem;
if (read_memtrack_memory(pid, &graphics_mem) == 0) {
pss = uss = memtrack = graphics_mem.graphics + graphics_mem.gl + graphics_mem.other;
}
{
UniqueFile fp = OpenSmapsOrRollup(pid);
if (fp != nullptr) {
char* line;
while (true) {
if (fgets(lineBuffer, sizeof (lineBuffer), fp.get()) == NULL) {
break;
}
line = lineBuffer;
switch (line[0]) {
case 'P':
if (strncmp(line, "Pss:", 4) == 0) {
char* c = line + 4;
while (*c != 0 && (*c < '0' || *c > '9')) {
c++;
}
pss += atoi(c);
} else if (strncmp(line, "Private_Clean:", 14) == 0
|| strncmp(line, "Private_Dirty:", 14) == 0) {
char* c = line + 14;
while (*c != 0 && (*c < '0' || *c > '9')) {
c++;
}
uss += atoi(c);
}
break;
case 'R':
if (strncmp(line, "Rss:", 4) == 0) {
char* c = line + 4;
while (*c != 0 && (*c < '0' || *c > '9')) {
c++;
}
rss += atoi(c);
}
break;
case 'S':
if (strncmp(line, "SwapPss:", 8) == 0) {
char* c = line + 8;
jlong lSwapPss;
while (*c != 0 && (*c < '0' || *c > '9')) {
c++;
}
lSwapPss = atoi(c);
swapPss += lSwapPss;
pss += lSwapPss; // Also in swap, those pages would be accounted as Pss without SWAP
}
break;
}
}
}
}
if (outUssSwapPssRss != NULL) {
if (env->GetArrayLength(outUssSwapPssRss) >= 1) {
jlong* outUssSwapPssRssArray = env->GetLongArrayElements(outUssSwapPssRss, 0);
if (outUssSwapPssRssArray != NULL) {
outUssSwapPssRssArray[0] = uss;
if (env->GetArrayLength(outUssSwapPssRss) >= 2) {
outUssSwapPssRssArray[1] = swapPss;
}
if (env->GetArrayLength(outUssSwapPssRss) >= 3) {
outUssSwapPssRssArray[2] = rss;
}
}
env->ReleaseLongArrayElements(outUssSwapPssRss, outUssSwapPssRssArray, 0);
}
}
if (outMemtrack != NULL) {
if (env->GetArrayLength(outMemtrack) >= 1) {
jlong* outMemtrackArray = env->GetLongArrayElements(outMemtrack, 0);
if (outMemtrackArray != NULL) {
outMemtrackArray[0] = memtrack;
}
env->ReleaseLongArrayElements(outMemtrack, outMemtrackArray, 0);
}
}
return pss;
}
static jlong android_os_Debug_getPss(JNIEnv *env, jobject clazz)
{
return android_os_Debug_getPssPid(env, clazz, getpid(), NULL, NULL);
}
static long get_allocated_vmalloc_memory() {
char line[1024];
// Ignored tags that don't actually consume memory (ie remappings)
static const char* const ignored_tags[] = {
"ioremap",
"map_lowmem",
"vm_map_ram",
NULL
};
long size, vmalloc_allocated_size = 0;
UniqueFile fp = MakeUniqueFile("/proc/vmallocinfo", "re");
if (fp == nullptr) {
return 0;
}
while (true) {
if (fgets(line, 1024, fp.get()) == NULL) {
break;
}
bool valid_line = true;
int i = 0;
while (ignored_tags[i]) {
if (strstr(line, ignored_tags[i]) != NULL) {
valid_line = false;
break;
}
i++;
}
if (valid_line && (sscanf(line, "%*x-%*x %ld", &size) == 1)) {
vmalloc_allocated_size += size;
}
}
return vmalloc_allocated_size;
}
enum {
MEMINFO_TOTAL,
MEMINFO_FREE,
MEMINFO_BUFFERS,
MEMINFO_CACHED,
MEMINFO_SHMEM,
MEMINFO_SLAB,
MEMINFO_SLAB_RECLAIMABLE,
MEMINFO_SLAB_UNRECLAIMABLE,
MEMINFO_SWAP_TOTAL,
MEMINFO_SWAP_FREE,
MEMINFO_ZRAM_TOTAL,
MEMINFO_MAPPED,
MEMINFO_VMALLOC_USED,
MEMINFO_PAGE_TABLES,
MEMINFO_KERNEL_STACK,
MEMINFO_COUNT
};
static long long get_zram_mem_used()
{
#define ZRAM_SYSFS "/sys/block/zram0/"
UniqueFile mm_stat_file = MakeUniqueFile(ZRAM_SYSFS "mm_stat", "re");
if (mm_stat_file) {
long long mem_used_total = 0;
int matched = fscanf(mm_stat_file.get(), "%*d %*d %lld %*d %*d %*d %*d", &mem_used_total);
if (matched != 1)
ALOGW("failed to parse " ZRAM_SYSFS "mm_stat");
return mem_used_total;
}
UniqueFile mem_used_total_file = MakeUniqueFile(ZRAM_SYSFS "mem_used_total", "re");
if (mem_used_total_file) {
long long mem_used_total = 0;
int matched = fscanf(mem_used_total_file.get(), "%lld", &mem_used_total);
if (matched != 1)
ALOGW("failed to parse " ZRAM_SYSFS "mem_used_total");
return mem_used_total;
}
return 0;
}
static void android_os_Debug_getMemInfo(JNIEnv *env, jobject clazz, jlongArray out)
{
char buffer[4096];
size_t numFound = 0;
if (out == NULL) {
jniThrowNullPointerException(env, "out == null");
return;
}
int fd = open("/proc/meminfo", O_RDONLY | O_CLOEXEC);
if (fd < 0) {
ALOGW("Unable to open /proc/meminfo: %s\n", strerror(errno));
return;
}
int len = read(fd, buffer, sizeof(buffer)-1);
close(fd);
if (len < 0) {
ALOGW("Empty /proc/meminfo");
return;
}
buffer[len] = 0;
static const char* const tags[] = {
"MemTotal:",
"MemFree:",
"Buffers:",
"Cached:",
"Shmem:",
"Slab:",
"SReclaimable:",
"SUnreclaim:",
"SwapTotal:",
"SwapFree:",
"ZRam:",
"Mapped:",
"VmallocUsed:",
"PageTables:",
"KernelStack:",
NULL
};
static const int tagsLen[] = {
9,
8,
8,
7,
6,
5,
13,
11,
10,
9,
5,
7,
12,
11,
12,
0
};
long mem[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
char* p = buffer;
while (*p && numFound < (sizeof(tagsLen) / sizeof(tagsLen[0]))) {
int i = 0;
while (tags[i]) {
if (strncmp(p, tags[i], tagsLen[i]) == 0) {
p += tagsLen[i];
while (*p == ' ') p++;
char* num = p;
while (*p >= '0' && *p <= '9') p++;
if (*p != 0) {
*p = 0;
p++;
}
mem[i] = atoll(num);
numFound++;
break;
}
i++;
}
while (*p && *p != '\n') {
p++;
}
if (*p) p++;
}
mem[MEMINFO_ZRAM_TOTAL] = get_zram_mem_used() / 1024;
// Recompute Vmalloc Used since the value in meminfo
// doesn't account for I/O remapping which doesn't use RAM.
mem[MEMINFO_VMALLOC_USED] = get_allocated_vmalloc_memory() / 1024;
int maxNum = env->GetArrayLength(out);
if (maxNum > MEMINFO_COUNT) {
maxNum = MEMINFO_COUNT;
}
jlong* outArray = env->GetLongArrayElements(out, 0);
if (outArray != NULL) {
for (int i=0; i<maxNum; i++) {
outArray[i] = mem[i];
}
}
env->ReleaseLongArrayElements(out, outArray, 0);
}
static jint read_binder_stat(const char* stat)
{
UniqueFile fp = MakeUniqueFile(BINDER_STATS, "re");
if (fp == nullptr) {
return -1;
}
char line[1024];
char compare[128];
int len = snprintf(compare, 128, "proc %d", getpid());
// loop until we have the block that represents this process
do {
if (fgets(line, 1024, fp.get()) == 0) {
return -1;
}
} while (strncmp(compare, line, len));
// now that we have this process, read until we find the stat that we are looking for
len = snprintf(compare, 128, " %s: ", stat);
do {
if (fgets(line, 1024, fp.get()) == 0) {
return -1;
}
} while (strncmp(compare, line, len));
// we have the line, now increment the line ptr to the value
char* ptr = line + len;
jint result = atoi(ptr);
return result;
}
static jint android_os_Debug_getBinderSentTransactions(JNIEnv *env, jobject clazz)
{
return read_binder_stat("bcTRANSACTION");
}
static jint android_os_getBinderReceivedTransactions(JNIEnv *env, jobject clazz)
{
return read_binder_stat("brTRANSACTION");
}
// these are implemented in android_util_Binder.cpp
jint android_os_Debug_getLocalObjectCount(JNIEnv* env, jobject clazz);
jint android_os_Debug_getProxyObjectCount(JNIEnv* env, jobject clazz);
jint android_os_Debug_getDeathObjectCount(JNIEnv* env, jobject clazz);
/* pulled out of bionic */
extern "C" void get_malloc_leak_info(uint8_t** info, size_t* overallSize,
size_t* infoSize, size_t* totalMemory, size_t* backtraceSize);
extern "C" void free_malloc_leak_info(uint8_t* info);
#define SIZE_FLAG_ZYGOTE_CHILD (1<<31)
static size_t gNumBacktraceElements;
/*
* This is a qsort() callback.
*
* See dumpNativeHeap() for comments about the data format and sort order.
*/
static int compareHeapRecords(const void* vrec1, const void* vrec2)
{
const size_t* rec1 = (const size_t*) vrec1;
const size_t* rec2 = (const size_t*) vrec2;
size_t size1 = *rec1;
size_t size2 = *rec2;
if (size1 < size2) {
return 1;
} else if (size1 > size2) {
return -1;
}
uintptr_t* bt1 = (uintptr_t*)(rec1 + 2);
uintptr_t* bt2 = (uintptr_t*)(rec2 + 2);
for (size_t idx = 0; idx < gNumBacktraceElements; idx++) {
uintptr_t addr1 = bt1[idx];
uintptr_t addr2 = bt2[idx];
if (addr1 == addr2) {
if (addr1 == 0)
break;
continue;
}
if (addr1 < addr2) {
return -1;
} else if (addr1 > addr2) {
return 1;
}
}
return 0;
}
/*
* The get_malloc_leak_info() call returns an array of structs that
* look like this:
*
* size_t size
* size_t allocations
* intptr_t backtrace[32]
*
* "size" is the size of the allocation, "backtrace" is a fixed-size
* array of function pointers, and "allocations" is the number of
* allocations with the exact same size and backtrace.
*
* The entries are sorted by descending total size (i.e. size*allocations)
* then allocation count. For best results with "diff" we'd like to sort
* primarily by individual size then stack trace. Since the entries are
* fixed-size, and we're allowed (by the current implementation) to mangle
* them, we can do this in place.
*/
static void dumpNativeHeap(FILE* fp)
{
uint8_t* info = NULL;
size_t overallSize, infoSize, totalMemory, backtraceSize;
get_malloc_leak_info(&info, &overallSize, &infoSize, &totalMemory,
&backtraceSize);
if (info == NULL) {
fprintf(fp, "Native heap dump not available. To enable, run these"
" commands (requires root):\n");
fprintf(fp, "# adb shell stop\n");
fprintf(fp, "# adb shell setprop libc.debug.malloc.options "
"backtrace\n");
fprintf(fp, "# adb shell start\n");
return;
}
assert(infoSize != 0);
assert(overallSize % infoSize == 0);
fprintf(fp, "Android Native Heap Dump v1.0\n\n");
size_t recordCount = overallSize / infoSize;
fprintf(fp, "Total memory: %zu\n", totalMemory);
fprintf(fp, "Allocation records: %zd\n", recordCount);
fprintf(fp, "Backtrace size: %zd\n", backtraceSize);
fprintf(fp, "\n");
/* re-sort the entries */
gNumBacktraceElements = backtraceSize;
qsort(info, recordCount, infoSize, compareHeapRecords);
/* dump the entries to the file */
const uint8_t* ptr = info;
for (size_t idx = 0; idx < recordCount; idx++) {
size_t size = *(size_t*) ptr;
size_t allocations = *(size_t*) (ptr + sizeof(size_t));
uintptr_t* backtrace = (uintptr_t*) (ptr + sizeof(size_t) * 2);
fprintf(fp, "z %d sz %8zu num %4zu bt",
(size & SIZE_FLAG_ZYGOTE_CHILD) != 0,
size & ~SIZE_FLAG_ZYGOTE_CHILD,
allocations);
for (size_t bt = 0; bt < backtraceSize; bt++) {
if (backtrace[bt] == 0) {
break;
} else {
#ifdef __LP64__
fprintf(fp, " %016" PRIxPTR, backtrace[bt]);
#else
fprintf(fp, " %08" PRIxPTR, backtrace[bt]);
#endif
}
}
fprintf(fp, "\n");
ptr += infoSize;
}
free_malloc_leak_info(info);
fprintf(fp, "MAPS\n");
const char* maps = "/proc/self/maps";
UniqueFile in = MakeUniqueFile(maps, "re");
if (in == nullptr) {
fprintf(fp, "Could not open %s\n", maps);
return;
}
char buf[BUFSIZ];
while (size_t n = fread(buf, sizeof(char), BUFSIZ, in.get())) {
fwrite(buf, sizeof(char), n, fp);
}
fprintf(fp, "END\n");
}
static bool openFile(JNIEnv* env, jobject fileDescriptor, UniqueFile& fp)
{
if (fileDescriptor == NULL) {
jniThrowNullPointerException(env, "fd == null");
return false;
}
int origFd = jniGetFDFromFileDescriptor(env, fileDescriptor);
if (origFd < 0) {
jniThrowRuntimeException(env, "Invalid file descriptor");
return false;
}
/* dup() the descriptor so we don't close the original with fclose() */
int fd = dup(origFd);
if (fd < 0) {
ALOGW("dup(%d) failed: %s\n", origFd, strerror(errno));
jniThrowRuntimeException(env, "dup() failed");
return false;
}
fp.reset(fdopen(fd, "w"));
if (fp == nullptr) {
ALOGW("fdopen(%d) failed: %s\n", fd, strerror(errno));
close(fd);
jniThrowRuntimeException(env, "fdopen() failed");
return false;
}
return true;
}
/*
* Dump the native heap, writing human-readable output to the specified
* file descriptor.
*/
static void android_os_Debug_dumpNativeHeap(JNIEnv* env, jobject,
jobject fileDescriptor)
{
UniqueFile fp(nullptr, safeFclose);
if (!openFile(env, fileDescriptor, fp)) {
return;
}
ALOGD("Native heap dump starting...\n");
dumpNativeHeap(fp.get());
ALOGD("Native heap dump complete.\n");
}
/*
* Dump the native malloc info, writing xml output to the specified
* file descriptor.
*/
static void android_os_Debug_dumpNativeMallocInfo(JNIEnv* env, jobject,
jobject fileDescriptor)
{
UniqueFile fp(nullptr, safeFclose);
if (!openFile(env, fileDescriptor, fp)) {
return;
}
malloc_info(0, fp.get());
}
static bool dumpTraces(JNIEnv* env, jint pid, jstring fileName, jint timeoutSecs,
DebuggerdDumpType dumpType) {
const ScopedUtfChars fileNameChars(env, fileName);
if (fileNameChars.c_str() == nullptr) {
return false;
}
android::base::unique_fd fd(open(fileNameChars.c_str(),
O_CREAT | O_WRONLY | O_NOFOLLOW | O_CLOEXEC | O_APPEND,
0666));
if (fd < 0) {
fprintf(stderr, "Can't open %s: %s\n", fileNameChars.c_str(), strerror(errno));
return false;
}
return (dump_backtrace_to_file_timeout(pid, dumpType, timeoutSecs, fd) == 0);
}
static jboolean android_os_Debug_dumpJavaBacktraceToFileTimeout(JNIEnv* env, jobject clazz,
jint pid, jstring fileName, jint timeoutSecs) {
const bool ret = dumpTraces(env, pid, fileName, timeoutSecs, kDebuggerdJavaBacktrace);
return ret ? JNI_TRUE : JNI_FALSE;
}
static jboolean android_os_Debug_dumpNativeBacktraceToFileTimeout(JNIEnv* env, jobject clazz,
jint pid, jstring fileName, jint timeoutSecs) {
const bool ret = dumpTraces(env, pid, fileName, timeoutSecs, kDebuggerdNativeBacktrace);
return ret ? JNI_TRUE : JNI_FALSE;
}
static jstring android_os_Debug_getUnreachableMemory(JNIEnv* env, jobject clazz,
jint limit, jboolean contents)
{
std::string s = GetUnreachableMemoryString(contents, limit);
return env->NewStringUTF(s.c_str());
}
/*
* JNI registration.
*/
static const JNINativeMethod gMethods[] = {
{ "getNativeHeapSize", "()J",
(void*) android_os_Debug_getNativeHeapSize },
{ "getNativeHeapAllocatedSize", "()J",
(void*) android_os_Debug_getNativeHeapAllocatedSize },
{ "getNativeHeapFreeSize", "()J",
(void*) android_os_Debug_getNativeHeapFreeSize },
{ "getMemoryInfo", "(Landroid/os/Debug$MemoryInfo;)V",
(void*) android_os_Debug_getDirtyPages },
{ "getMemoryInfo", "(ILandroid/os/Debug$MemoryInfo;)V",
(void*) android_os_Debug_getDirtyPagesPid },
{ "getPss", "()J",
(void*) android_os_Debug_getPss },
{ "getPss", "(I[J[J)J",
(void*) android_os_Debug_getPssPid },
{ "getMemInfo", "([J)V",
(void*) android_os_Debug_getMemInfo },
{ "dumpNativeHeap", "(Ljava/io/FileDescriptor;)V",
(void*) android_os_Debug_dumpNativeHeap },
{ "dumpNativeMallocInfo", "(Ljava/io/FileDescriptor;)V",
(void*) android_os_Debug_dumpNativeMallocInfo },
{ "getBinderSentTransactions", "()I",
(void*) android_os_Debug_getBinderSentTransactions },
{ "getBinderReceivedTransactions", "()I",
(void*) android_os_getBinderReceivedTransactions },
{ "getBinderLocalObjectCount", "()I",
(void*)android_os_Debug_getLocalObjectCount },
{ "getBinderProxyObjectCount", "()I",
(void*)android_os_Debug_getProxyObjectCount },
{ "getBinderDeathObjectCount", "()I",
(void*)android_os_Debug_getDeathObjectCount },
{ "dumpJavaBacktraceToFileTimeout", "(ILjava/lang/String;I)Z",
(void*)android_os_Debug_dumpJavaBacktraceToFileTimeout },
{ "dumpNativeBacktraceToFileTimeout", "(ILjava/lang/String;I)Z",
(void*)android_os_Debug_dumpNativeBacktraceToFileTimeout },
{ "getUnreachableMemory", "(IZ)Ljava/lang/String;",
(void*)android_os_Debug_getUnreachableMemory },
};
int register_android_os_Debug(JNIEnv *env)
{
jclass clazz = env->FindClass("android/os/Debug$MemoryInfo");
// Sanity check the number of other statistics expected in Java matches here.
jfieldID numOtherStats_field = env->GetStaticFieldID(clazz, "NUM_OTHER_STATS", "I");
jint numOtherStats = env->GetStaticIntField(clazz, numOtherStats_field);
jfieldID numDvkStats_field = env->GetStaticFieldID(clazz, "NUM_DVK_STATS", "I");
jint numDvkStats = env->GetStaticIntField(clazz, numDvkStats_field);
int expectedNumOtherStats = _NUM_HEAP - _NUM_CORE_HEAP;
if ((numOtherStats + numDvkStats) != expectedNumOtherStats) {
jniThrowExceptionFmt(env, "java/lang/RuntimeException",
"android.os.Debug.Meminfo.NUM_OTHER_STATS+android.os.Debug.Meminfo.NUM_DVK_STATS=%d expected %d",
numOtherStats+numDvkStats, expectedNumOtherStats);
return JNI_ERR;
}
otherStats_field = env->GetFieldID(clazz, "otherStats", "[I");
hasSwappedOutPss_field = env->GetFieldID(clazz, "hasSwappedOutPss", "Z");
for (int i=0; i<_NUM_CORE_HEAP; i++) {
stat_fields[i].pss_field =
env->GetFieldID(clazz, stat_field_names[i].pss_name, "I");
stat_fields[i].pssSwappable_field =
env->GetFieldID(clazz, stat_field_names[i].pssSwappable_name, "I");
stat_fields[i].rss_field =
env->GetFieldID(clazz, stat_field_names[i].rss_name, "I");
stat_fields[i].privateDirty_field =
env->GetFieldID(clazz, stat_field_names[i].privateDirty_name, "I");
stat_fields[i].sharedDirty_field =
env->GetFieldID(clazz, stat_field_names[i].sharedDirty_name, "I");
stat_fields[i].privateClean_field =
env->GetFieldID(clazz, stat_field_names[i].privateClean_name, "I");
stat_fields[i].sharedClean_field =
env->GetFieldID(clazz, stat_field_names[i].sharedClean_name, "I");
stat_fields[i].swappedOut_field =
env->GetFieldID(clazz, stat_field_names[i].swappedOut_name, "I");
stat_fields[i].swappedOutPss_field =
env->GetFieldID(clazz, stat_field_names[i].swappedOutPss_name, "I");
}
return jniRegisterNativeMethods(env, "android/os/Debug", gMethods, NELEM(gMethods));
}
}; // namespace android