/*
* Copyright (C) 2008 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.
*/
/*
* Miscellaneous utility functions.
*/
#include "Dalvik.h"
#include <stdlib.h>
#include <stddef.h>
#include <string.h>
#include <strings.h>
#include <ctype.h>
#include <time.h>
#include <sys/time.h>
#include <fcntl.h>
#include <cutils/ashmem.h>
#include <sys/mman.h>
#define ALIGN_UP_TO_PAGE_SIZE(p) \
(((size_t)(p) + (SYSTEM_PAGE_SIZE - 1)) & ~(SYSTEM_PAGE_SIZE - 1))
/*
* Print a hex dump in this format:
*
01234567: 00 11 22 33 44 55 66 77 88 99 aa bb cc dd ee ff 0123456789abcdef\n
*
* If "mode" is kHexDumpLocal, we start at offset zero, and show a full
* 16 bytes on the first line. If it's kHexDumpMem, we make this look
* like a memory dump, using the actual address, outputting a partial line
* if "vaddr" isn't aligned on a 16-byte boundary.
*
* "priority" and "tag" determine the values passed to the log calls.
*
* Does not use printf() or other string-formatting calls.
*/
void dvmPrintHexDumpEx(int priority, const char* tag, const void* vaddr,
size_t length, HexDumpMode mode)
{
static const char gHexDigit[] = "0123456789abcdef";
const unsigned char* addr = vaddr;
char out[77]; /* exact fit */
unsigned int offset; /* offset to show while printing */
char* hex;
char* asc;
int gap;
//int trickle = 0;
if (mode == kHexDumpLocal)
offset = 0;
else
offset = (int) addr;
memset(out, ' ', sizeof(out)-1);
out[8] = ':';
out[sizeof(out)-2] = '\n';
out[sizeof(out)-1] = '\0';
gap = (int) offset & 0x0f;
while (length) {
unsigned int lineOffset = offset & ~0x0f;
int i, count;
hex = out;
asc = out + 59;
for (i = 0; i < 8; i++) {
*hex++ = gHexDigit[lineOffset >> 28];
lineOffset <<= 4;
}
hex++;
hex++;
count = ((int)length > 16-gap) ? 16-gap : (int)length; /* cap length */
assert(count != 0);
assert(count+gap <= 16);
if (gap) {
/* only on first line */
hex += gap * 3;
asc += gap;
}
for (i = gap ; i < count+gap; i++) {
*hex++ = gHexDigit[*addr >> 4];
*hex++ = gHexDigit[*addr & 0x0f];
hex++;
if (*addr >= 0x20 && *addr < 0x7f /*isprint(*addr)*/)
*asc++ = *addr;
else
*asc++ = '.';
addr++;
}
for ( ; i < 16; i++) {
/* erase extra stuff; only happens on last line */
*hex++ = ' ';
*hex++ = ' ';
hex++;
*asc++ = ' ';
}
LOG_PRI(priority, tag, "%s", out);
#if 0 //def HAVE_ANDROID_OS
/*
* We can overrun logcat easily by writing at full speed. On the
* other hand, we can make Eclipse time out if we're showing
* packet dumps while debugging JDWP.
*/
{
if (trickle++ == 8) {
trickle = 0;
usleep(20000);
}
}
#endif
gap = 0;
length -= count;
offset += count;
}
}
/*
* Fill out a DebugOutputTarget, suitable for printing to the log.
*/
void dvmCreateLogOutputTarget(DebugOutputTarget* target, int priority,
const char* tag)
{
assert(target != NULL);
assert(tag != NULL);
target->which = kDebugTargetLog;
target->data.log.priority = priority;
target->data.log.tag = tag;
}
/*
* Fill out a DebugOutputTarget suitable for printing to a file pointer.
*/
void dvmCreateFileOutputTarget(DebugOutputTarget* target, FILE* fp)
{
assert(target != NULL);
assert(fp != NULL);
target->which = kDebugTargetFile;
target->data.file.fp = fp;
}
/*
* Free "target" and any associated data.
*/
void dvmFreeOutputTarget(DebugOutputTarget* target)
{
free(target);
}
/*
* Print a debug message, to either a file or the log.
*/
void dvmPrintDebugMessage(const DebugOutputTarget* target, const char* format,
...)
{
va_list args;
va_start(args, format);
switch (target->which) {
case kDebugTargetLog:
LOG_PRI_VA(target->data.log.priority, target->data.log.tag,
format, args);
break;
case kDebugTargetFile:
vfprintf(target->data.file.fp, format, args);
break;
default:
LOGE("unexpected 'which' %d\n", target->which);
break;
}
va_end(args);
}
/*
* Allocate a bit vector with enough space to hold at least the specified
* number of bits.
*/
BitVector* dvmAllocBitVector(int startBits, bool expandable)
{
BitVector* bv;
int count;
assert(sizeof(bv->storage[0]) == 4); /* assuming 32-bit units */
assert(startBits >= 0);
bv = (BitVector*) malloc(sizeof(BitVector));
count = (startBits + 31) >> 5;
bv->storageSize = count;
bv->expandable = expandable;
bv->storage = (u4*) malloc(count * sizeof(u4));
memset(bv->storage, 0x00, count * sizeof(u4));
return bv;
}
/*
* Free a BitVector.
*/
void dvmFreeBitVector(BitVector* pBits)
{
if (pBits == NULL)
return;
free(pBits->storage);
free(pBits);
}
/*
* "Allocate" the first-available bit in the bitmap.
*
* This is not synchronized. The caller is expected to hold some sort of
* lock that prevents multiple threads from executing simultaneously in
* dvmAllocBit/dvmFreeBit.
*/
int dvmAllocBit(BitVector* pBits)
{
int word, bit;
retry:
for (word = 0; word < pBits->storageSize; word++) {
if (pBits->storage[word] != 0xffffffff) {
/*
* There are unallocated bits in this word. Return the first.
*/
bit = ffs(~(pBits->storage[word])) -1;
assert(bit >= 0 && bit < 32);
pBits->storage[word] |= 1 << bit;
return (word << 5) | bit;
}
}
/*
* Ran out of space, allocate more if we're allowed to.
*/
if (!pBits->expandable)
return -1;
pBits->storage = realloc(pBits->storage,
(pBits->storageSize + kBitVectorGrowth) * sizeof(u4));
memset(&pBits->storage[pBits->storageSize], 0x00,
kBitVectorGrowth * sizeof(u4));
pBits->storageSize += kBitVectorGrowth;
goto retry;
}
/*
* Mark the specified bit as "set".
*
* Returns "false" if the bit is outside the range of the vector and we're
* not allowed to expand.
*/
bool dvmSetBit(BitVector* pBits, int num)
{
assert(num >= 0);
if (num >= pBits->storageSize * (int)sizeof(u4) * 8) {
if (!pBits->expandable)
return false;
int newSize = (num + 31) >> 5;
assert(newSize > pBits->storageSize);
pBits->storage = realloc(pBits->storage, newSize * sizeof(u4));
memset(&pBits->storage[pBits->storageSize], 0x00,
(newSize - pBits->storageSize) * sizeof(u4));
pBits->storageSize = newSize;
}
pBits->storage[num >> 5] |= 1 << (num & 0x1f);
return true;
}
/*
* Mark the specified bit as "clear".
*/
void dvmClearBit(BitVector* pBits, int num)
{
assert(num >= 0 && num < (int) pBits->storageSize * (int)sizeof(u4) * 8);
pBits->storage[num >> 5] &= ~(1 << (num & 0x1f));
}
/*
* Mark all bits bit as "clear".
*/
void dvmClearAllBits(BitVector* pBits)
{
int count = pBits->storageSize;
memset(pBits->storage, 0, count * sizeof(u4));
}
/*
* Determine whether or not the specified bit is set.
*/
bool dvmIsBitSet(const BitVector* pBits, int num)
{
assert(num >= 0 && num < (int) pBits->storageSize * (int)sizeof(u4) * 8);
int val = pBits->storage[num >> 5] & (1 << (num & 0x1f));
return (val != 0);
}
/*
* Count the number of bits that are set.
*/
int dvmCountSetBits(const BitVector* pBits)
{
int word;
int count = 0;
for (word = 0; word < pBits->storageSize; word++) {
u4 val = pBits->storage[word];
if (val != 0) {
if (val == 0xffffffff) {
count += 32;
} else {
/* count the number of '1' bits */
while (val != 0) {
val &= val - 1;
count++;
}
}
}
}
return count;
}
/*
* Copy a whole vector to the other. Only do that when the both vectors have
* the same size and attribute.
*/
bool dvmCopyBitVector(BitVector *dest, const BitVector *src)
{
if (dest->storageSize != src->storageSize ||
dest->expandable != src->expandable)
return false;
memcpy(dest->storage, src->storage, sizeof(u4) * dest->storageSize);
return true;
}
/*
* Intersect two bit vectores and merge the result on top of the pre-existing
* value in the dest vector.
*/
bool dvmIntersectBitVectors(BitVector *dest, const BitVector *src1,
const BitVector *src2)
{
if (dest->storageSize != src1->storageSize ||
dest->storageSize != src2->storageSize ||
dest->expandable != src1->expandable ||
dest->expandable != src2->expandable)
return false;
int i;
for (i = 0; i < dest->storageSize; i++) {
dest->storage[i] |= src1->storage[i] & src2->storage[i];
}
return true;
}
/*
* Return a newly-allocated string in which all occurrences of '.' have
* been changed to '/'. If we find a '/' in the original string, NULL
* is returned to avoid ambiguity.
*/
char* dvmDotToSlash(const char* str)
{
char* newStr = strdup(str);
char* cp = newStr;
if (newStr == NULL)
return NULL;
while (*cp != '\0') {
if (*cp == '/') {
assert(false);
return NULL;
}
if (*cp == '.')
*cp = '/';
cp++;
}
return newStr;
}
/*
* Return a newly-allocated string for the "dot version" of the class
* name for the given type descriptor. That is, The initial "L" and
* final ";" (if any) have been removed and all occurrences of '/'
* have been changed to '.'.
*/
char* dvmDescriptorToDot(const char* str)
{
size_t at = strlen(str);
char* newStr;
if ((at >= 2) && (str[0] == 'L') && (str[at - 1] == ';')) {
at -= 2; /* Two fewer chars to copy. */
str++; /* Skip the 'L'. */
}
newStr = malloc(at + 1); /* Add one for the '\0'. */
if (newStr == NULL)
return NULL;
newStr[at] = '\0';
while (at > 0) {
at--;
newStr[at] = (str[at] == '/') ? '.' : str[at];
}
return newStr;
}
/*
* Return a newly-allocated string for the type descriptor
* corresponding to the "dot version" of the given class name. That
* is, non-array names are surrounded by "L" and ";", and all
* occurrences of '.' are changed to '/'.
*/
char* dvmDotToDescriptor(const char* str)
{
size_t length = strlen(str);
int wrapElSemi = 0;
char* newStr;
char* at;
if (str[0] != '[') {
length += 2; /* for "L" and ";" */
wrapElSemi = 1;
}
newStr = at = malloc(length + 1); /* + 1 for the '\0' */
if (newStr == NULL) {
return NULL;
}
if (wrapElSemi) {
*(at++) = 'L';
}
while (*str) {
char c = *(str++);
if (c == '.') {
c = '/';
}
*(at++) = c;
}
if (wrapElSemi) {
*(at++) = ';';
}
*at = '\0';
return newStr;
}
/*
* Return a newly-allocated string for the internal-form class name for
* the given type descriptor. That is, the initial "L" and final ";" (if
* any) have been removed.
*/
char* dvmDescriptorToName(const char* str)
{
if (str[0] == 'L') {
size_t length = strlen(str) - 1;
char* newStr = malloc(length);
if (newStr == NULL) {
return NULL;
}
strlcpy(newStr, str + 1, length);
return newStr;
}
return strdup(str);
}
/*
* Return a newly-allocated string for the type descriptor for the given
* internal-form class name. That is, a non-array class name will get
* surrounded by "L" and ";", while array names are left as-is.
*/
char* dvmNameToDescriptor(const char* str)
{
if (str[0] != '[') {
size_t length = strlen(str);
char* descriptor = malloc(length + 3);
if (descriptor == NULL) {
return NULL;
}
descriptor[0] = 'L';
strcpy(descriptor + 1, str);
descriptor[length + 1] = ';';
descriptor[length + 2] = '\0';
return descriptor;
}
return strdup(str);
}
/*
* Get a notion of the current time, in nanoseconds. This is meant for
* computing durations (e.g. "operation X took 52nsec"), so the result
* should not be used to get the current date/time.
*/
u8 dvmGetRelativeTimeNsec(void)
{
#ifdef HAVE_POSIX_CLOCKS
struct timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
return (u8)now.tv_sec*1000000000LL + now.tv_nsec;
#else
struct timeval now;
gettimeofday(&now, NULL);
return (u8)now.tv_sec*1000000000LL + now.tv_usec * 1000LL;
#endif
}
/*
* Get the per-thread CPU time, in nanoseconds.
*
* Only useful for time deltas.
*/
u8 dvmGetThreadCpuTimeNsec(void)
{
#ifdef HAVE_POSIX_CLOCKS
struct timespec now;
clock_gettime(CLOCK_THREAD_CPUTIME_ID, &now);
return (u8)now.tv_sec*1000000000LL + now.tv_nsec;
#else
return (u8) -1;
#endif
}
/*
* Get the per-thread CPU time, in nanoseconds, for the specified thread.
*/
u8 dvmGetOtherThreadCpuTimeNsec(pthread_t thread)
{
#if 0 /*def HAVE_POSIX_CLOCKS*/
int clockId;
if (pthread_getcpuclockid(thread, &clockId) != 0)
return (u8) -1;
struct timespec now;
clock_gettime(clockId, &now);
return (u8)now.tv_sec*1000000000LL + now.tv_nsec;
#else
return (u8) -1;
#endif
}
/*
* Call this repeatedly, with successively higher values for "iteration",
* to sleep for a period of time not to exceed "maxTotalSleep".
*
* For example, when called with iteration==0 we will sleep for a very
* brief time. On the next call we will sleep for a longer time. When
* the sum total of all sleeps reaches "maxTotalSleep", this returns false.
*
* The initial start time value for "relStartTime" MUST come from the
* dvmGetRelativeTimeUsec call. On the device this must come from the
* monotonic clock source, not the wall clock.
*
* This should be used wherever you might be tempted to call sched_yield()
* in a loop. The problem with sched_yield is that, for a high-priority
* thread, the kernel might not actually transfer control elsewhere.
*
* Returns "false" if we were unable to sleep because our time was up.
*/
bool dvmIterativeSleep(int iteration, int maxTotalSleep, u8 relStartTime)
{
const int minSleep = 10000;
u8 curTime;
int curDelay;
/*
* Get current time, and see if we've already exceeded the limit.
*/
curTime = dvmGetRelativeTimeUsec();
if (curTime >= relStartTime + maxTotalSleep) {
LOGVV("exsl: sleep exceeded (start=%llu max=%d now=%llu)\n",
relStartTime, maxTotalSleep, curTime);
return false;
}
/*
* Compute current delay. We're bounded by "maxTotalSleep", so no
* real risk of overflow assuming "usleep" isn't returning early.
* (Besides, 2^30 usec is about 18 minutes by itself.)
*
* For iteration==0 we just call sched_yield(), so the first sleep
* at iteration==1 is actually (minSleep * 2).
*/
curDelay = minSleep;
while (iteration-- > 0)
curDelay *= 2;
assert(curDelay > 0);
if (curTime + curDelay >= relStartTime + maxTotalSleep) {
LOGVV("exsl: reduced delay from %d to %d\n",
curDelay, (int) ((relStartTime + maxTotalSleep) - curTime));
curDelay = (int) ((relStartTime + maxTotalSleep) - curTime);
}
if (iteration == 0) {
LOGVV("exsl: yield\n");
sched_yield();
} else {
LOGVV("exsl: sleep for %d\n", curDelay);
usleep(curDelay);
}
return true;
}
/*
* Set the "close on exec" flag so we don't expose our file descriptors
* to processes launched by us.
*/
bool dvmSetCloseOnExec(int fd)
{
int flags;
/*
* There's presently only one flag defined, so getting the previous
* value of the fd flags is probably unnecessary.
*/
flags = fcntl(fd, F_GETFD);
if (flags < 0) {
LOGW("Unable to get fd flags for fd %d\n", fd);
return false;
}
if (fcntl(fd, F_SETFD, flags | FD_CLOEXEC) < 0) {
LOGW("Unable to set close-on-exec for fd %d\n", fd);
return false;
}
return true;
}
#if (!HAVE_STRLCPY)
/* Implementation of strlcpy() for platforms that don't already have it. */
size_t strlcpy(char *dst, const char *src, size_t size) {
size_t srcLength = strlen(src);
size_t copyLength = srcLength;
if (srcLength > (size - 1)) {
copyLength = size - 1;
}
if (size != 0) {
strncpy(dst, src, copyLength);
dst[copyLength] = '\0';
}
return srcLength;
}
#endif
/*
* Allocates a memory region using ashmem and mmap, initialized to
* zero. Actual allocation rounded up to page multiple. Returns
* NULL on failure.
*/
void *dvmAllocRegion(size_t size, int prot, const char *name) {
void *base;
int fd, ret;
size = ALIGN_UP_TO_PAGE_SIZE(size);
fd = ashmem_create_region(name, size);
if (fd == -1) {
return NULL;
}
base = mmap(NULL, size, prot, MAP_PRIVATE, fd, 0);
ret = close(fd);
if (base == MAP_FAILED) {
return NULL;
}
if (ret == -1) {
return NULL;
}
return base;
}
/* documented in header file */
const char* dvmPathToAbsolutePortion(const char* path) {
if (path == NULL) {
return NULL;
}
if (path[0] == '/') {
/* It's a regular absolute path. Return it. */
return path;
}
const char* sentinel = strstr(path, "/./");
if (sentinel != NULL) {
/* It's got the sentinel. Return a pointer to the second slash. */
return sentinel + 2;
}
return NULL;
}