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android / platform / dalvik / 20aeca6e2b18c07d3840f4b09f09186511148d8c / . / vm / alloc / HeapSource.cpp
blob: f61724a408a31732a8b7a37e9491a61bee3746de [file] [log] [blame]
/*
* 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.
*/
#include <cutils/mspace.h>
#include <stdint.h>
#include <sys/mman.h>
#include <errno.h>
#define SIZE_MAX UINT_MAX // TODO: get SIZE_MAX from stdint.h
#include "Dalvik.h"
#include "alloc/Heap.h"
#include "alloc/HeapInternal.h"
#include "alloc/HeapSource.h"
#include "alloc/HeapBitmap.h"
#include "alloc/HeapBitmapInlines.h"
// TODO: find a real header file for these.
extern "C" int dlmalloc_trim(size_t);
extern "C" void dlmalloc_walk_free_pages(void(*)(void*, void*, void*), void*);
static void snapIdealFootprint();
static void setIdealFootprint(size_t max);
static size_t getMaximumSize(const HeapSource *hs);
static void trimHeaps();
#define HEAP_UTILIZATION_MAX 1024
#define DEFAULT_HEAP_UTILIZATION 512 // Range 1..HEAP_UTILIZATION_MAX
#define HEAP_IDEAL_FREE (2 * 1024 * 1024)
#define HEAP_MIN_FREE (HEAP_IDEAL_FREE / 4)
/* Number of seconds to wait after a GC before performing a heap trim
* operation to reclaim unused pages.
*/
#define HEAP_TRIM_IDLE_TIME_SECONDS 5
/* Start a concurrent collection when free memory falls under this
* many bytes.
*/
#define CONCURRENT_START (128 << 10)
/* The next GC will not be concurrent when free memory after a GC is
* under this many bytes.
*/
#define CONCURRENT_MIN_FREE (CONCURRENT_START + (128 << 10))
#define HS_BOILERPLATE() \
do { \
assert(gDvm.gcHeap != NULL); \
assert(gDvm.gcHeap->heapSource != NULL); \
assert(gHs == gDvm.gcHeap->heapSource); \
} while (0)
struct Heap {
/* The mspace to allocate from.
*/
mspace msp;
/* The largest size that this heap is allowed to grow to.
*/
size_t maximumSize;
/* Number of bytes allocated from this mspace for objects,
* including any overhead. This value is NOT exact, and
* should only be used as an input for certain heuristics.
*/
size_t bytesAllocated;
/* Number of bytes allocated from this mspace at which a
* concurrent garbage collection will be started.
*/
size_t concurrentStartBytes;
/* Number of objects currently allocated from this mspace.
*/
size_t objectsAllocated;
/*
* The lowest address of this heap, inclusive.
*/
char *base;
/*
* The highest address of this heap, exclusive.
*/
char *limit;
};
struct HeapSource {
/* Target ideal heap utilization ratio; range 1..HEAP_UTILIZATION_MAX
*/
size_t targetUtilization;
/* The starting heap size.
*/
size_t startSize;
/* The largest that the heap source as a whole is allowed to grow.
*/
size_t maximumSize;
/*
* The largest size we permit the heap to grow. This value allows
* the user to limit the heap growth below the maximum size. This
* is a work around until we can dynamically set the maximum size.
* This value can range between the starting size and the maximum
* size but should never be set below the current footprint of the
* heap.
*/
size_t growthLimit;
/* The desired max size of the heap source as a whole.
*/
size_t idealSize;
/* The maximum number of bytes allowed to be allocated from the
* active heap before a GC is forced. This is used to "shrink" the
* heap in lieu of actual compaction.
*/
size_t softLimit;
/* The heaps; heaps[0] is always the active heap,
* which new objects should be allocated from.
*/
Heap heaps[HEAP_SOURCE_MAX_HEAP_COUNT];
/* The current number of heaps.
*/
size_t numHeaps;
/* True if zygote mode was active when the HeapSource was created.
*/
bool sawZygote;
/*
* The base address of the virtual memory reservation.
*/
char *heapBase;
/*
* The length in bytes of the virtual memory reservation.
*/
size_t heapLength;
/*
* The live object bitmap.
*/
HeapBitmap liveBits;
/*
* The mark bitmap.
*/
HeapBitmap markBits;
/*
* State for the GC daemon.
*/
bool hasGcThread;
pthread_t gcThread;
bool gcThreadShutdown;
pthread_mutex_t gcThreadMutex;
pthread_cond_t gcThreadCond;
bool gcThreadTrimNeeded;
};
#define hs2heap(hs_) (&((hs_)->heaps[0]))
/*
* Returns true iff a soft limit is in effect for the active heap.
*/
static bool isSoftLimited(const HeapSource *hs)
{
/* softLimit will be either SIZE_MAX or the limit for the
* active mspace. idealSize can be greater than softLimit
* if there is more than one heap. If there is only one
* heap, a non-SIZE_MAX softLimit should always be the same
* as idealSize.
*/
return hs->softLimit <= hs->idealSize;
}
/*
* Returns approximately the maximum number of bytes allowed to be
* allocated from the active heap before a GC is forced.
*/
static size_t getAllocLimit(const HeapSource *hs)
{
if (isSoftLimited(hs)) {
return hs->softLimit;
} else {
return mspace_max_allowed_footprint(hs2heap(hs)->msp);
}
}
/*
* Returns the current footprint of all heaps. If includeActive
* is false, don't count the heap at index 0.
*/
static size_t oldHeapOverhead(const HeapSource *hs, bool includeActive)
{
size_t footprint = 0;
size_t i;
if (includeActive) {
i = 0;
} else {
i = 1;
}
for (/* i = i */; i < hs->numHeaps; i++) {
//TODO: include size of bitmaps? If so, don't use bitsLen, listen to .max
footprint += mspace_footprint(hs->heaps[i].msp);
}
return footprint;
}
/*
* Returns the heap that <ptr> could have come from, or NULL
* if it could not have come from any heap.
*/
static Heap *ptr2heap(const HeapSource *hs, const void *ptr)
{
const size_t numHeaps = hs->numHeaps;
if (ptr != NULL) {
for (size_t i = 0; i < numHeaps; i++) {
const Heap *const heap = &hs->heaps[i];
if ((const char *)ptr >= heap->base && (const char *)ptr < heap->limit) {
return (Heap *)heap;
}
}
}
return NULL;
}
/*
* Functions to update heapSource->bytesAllocated when an object
* is allocated or freed. mspace_usable_size() will give
* us a much more accurate picture of heap utilization than
* the requested byte sizes would.
*
* These aren't exact, and should not be treated as such.
*/
static void countAllocation(Heap *heap, const void *ptr)
{
assert(heap->bytesAllocated < mspace_footprint(heap->msp));
heap->bytesAllocated += mspace_usable_size(heap->msp, ptr) +
HEAP_SOURCE_CHUNK_OVERHEAD;
heap->objectsAllocated++;
HeapSource* hs = gDvm.gcHeap->heapSource;
dvmHeapBitmapSetObjectBit(&hs->liveBits, ptr);
assert(heap->bytesAllocated < mspace_footprint(heap->msp));
}
static void countFree(Heap *heap, const void *ptr, size_t *numBytes)
{
size_t delta = mspace_usable_size(heap->msp, ptr) + HEAP_SOURCE_CHUNK_OVERHEAD;
assert(delta > 0);
if (delta < heap->bytesAllocated) {
heap->bytesAllocated -= delta;
} else {
heap->bytesAllocated = 0;
}
HeapSource* hs = gDvm.gcHeap->heapSource;
dvmHeapBitmapClearObjectBit(&hs->liveBits, ptr);
if (heap->objectsAllocated > 0) {
heap->objectsAllocated--;
}
*numBytes += delta;
}
static HeapSource *gHs = NULL;
static mspace createMspace(void *base, size_t startSize, size_t maximumSize)
{
/* Create an unlocked dlmalloc mspace to use as
* a heap source.
*
* We start off reserving startSize / 2 bytes but
* letting the heap grow to startSize. This saves
* memory in the case where a process uses even less
* than the starting size.
*/
LOGV_HEAP("Creating VM heap of size %zu", startSize);
errno = 0;
mspace msp = create_contiguous_mspace_with_base(startSize/2,
maximumSize, /*locked=*/false, base);
if (msp != NULL) {
/* Don't let the heap grow past the starting size without
* our intervention.
*/
mspace_set_max_allowed_footprint(msp, startSize);
} else {
/* There's no guarantee that errno has meaning when the call
* fails, but it often does.
*/
LOGE_HEAP("Can't create VM heap of size (%zu,%zu): %s",
startSize/2, maximumSize, strerror(errno));
}
return msp;
}
/*
* Add the initial heap. Returns false if the initial heap was
* already added to the heap source.
*/
static bool addInitialHeap(HeapSource *hs, mspace msp, size_t maximumSize)
{
assert(hs != NULL);
assert(msp != NULL);
if (hs->numHeaps != 0) {
return false;
}
hs->heaps[0].msp = msp;
hs->heaps[0].maximumSize = maximumSize;
hs->heaps[0].concurrentStartBytes = SIZE_MAX;
hs->heaps[0].base = hs->heapBase;
hs->heaps[0].limit = hs->heapBase + hs->heaps[0].maximumSize;
hs->numHeaps = 1;
return true;
}
/*
* Adds an additional heap to the heap source. Returns false if there
* are too many heaps or insufficient free space to add another heap.
*/
static bool addNewHeap(HeapSource *hs)
{
Heap heap;
assert(hs != NULL);
if (hs->numHeaps >= HEAP_SOURCE_MAX_HEAP_COUNT) {
LOGE("Attempt to create too many heaps (%zd >= %zd)",
hs->numHeaps, HEAP_SOURCE_MAX_HEAP_COUNT);
dvmAbort();
return false;
}
memset(&heap, 0, sizeof(heap));
/*
* Heap storage comes from a common virtual memory reservation.
* The new heap will start on the page after the old heap.
*/
void *sbrk0 = contiguous_mspace_sbrk0(hs->heaps[0].msp);
char *base = (char *)ALIGN_UP_TO_PAGE_SIZE(sbrk0);
size_t overhead = base - hs->heaps[0].base;
assert(((size_t)hs->heaps[0].base & (SYSTEM_PAGE_SIZE - 1)) == 0);
if (overhead + HEAP_MIN_FREE >= hs->maximumSize) {
LOGE_HEAP("No room to create any more heaps "
"(%zd overhead, %zd max)",
overhead, hs->maximumSize);
return false;
}
heap.maximumSize = hs->growthLimit - overhead;
heap.concurrentStartBytes = HEAP_MIN_FREE - CONCURRENT_START;
heap.base = base;
heap.limit = heap.base + heap.maximumSize;
heap.msp = createMspace(base, HEAP_MIN_FREE, hs->maximumSize - overhead);
if (heap.msp == NULL) {
return false;
}
/* Don't let the soon-to-be-old heap grow any further.
*/
hs->heaps[0].maximumSize = overhead;
hs->heaps[0].limit = base;
mspace msp = hs->heaps[0].msp;
mspace_set_max_allowed_footprint(msp, mspace_footprint(msp));
/* Put the new heap in the list, at heaps[0].
* Shift existing heaps down.
*/
memmove(&hs->heaps[1], &hs->heaps[0], hs->numHeaps * sizeof(hs->heaps[0]));
hs->heaps[0] = heap;
hs->numHeaps++;
return true;
}
/*
* The garbage collection daemon. Initiates a concurrent collection
* when signaled. Also periodically trims the heaps when a few seconds
* have elapsed since the last concurrent GC.
*/
static void *gcDaemonThread(void* arg)
{
dvmChangeStatus(NULL, THREAD_VMWAIT);
dvmLockMutex(&gHs->gcThreadMutex);
while (gHs->gcThreadShutdown != true) {
bool trim = false;
if (gHs->gcThreadTrimNeeded) {
int result = dvmRelativeCondWait(&gHs->gcThreadCond, &gHs->gcThreadMutex,
HEAP_TRIM_IDLE_TIME_SECONDS, 0);
if (result == ETIMEDOUT) {
/* Timed out waiting for a GC request, schedule a heap trim. */
trim = true;
}
} else {
dvmWaitCond(&gHs->gcThreadCond, &gHs->gcThreadMutex);
}
dvmLockHeap();
/*
* Another thread may have started a concurrent garbage
* collection before we were scheduled. Check for this
* condition before proceeding.
*/
if (!gDvm.gcHeap->gcRunning) {
dvmChangeStatus(NULL, THREAD_RUNNING);
if (trim) {
trimHeaps();
gHs->gcThreadTrimNeeded = false;
} else {
dvmCollectGarbageInternal(GC_CONCURRENT);
gHs->gcThreadTrimNeeded = true;
}
dvmChangeStatus(NULL, THREAD_VMWAIT);
}
dvmUnlockHeap();
}
dvmChangeStatus(NULL, THREAD_RUNNING);
return NULL;
}
static bool gcDaemonStartup()
{
dvmInitMutex(&gHs->gcThreadMutex);
pthread_cond_init(&gHs->gcThreadCond, NULL);
gHs->gcThreadShutdown = false;
gHs->hasGcThread = dvmCreateInternalThread(&gHs->gcThread, "GC",
gcDaemonThread, NULL);
return gHs->hasGcThread;
}
static void gcDaemonShutdown()
{
if (gHs->hasGcThread) {
dvmLockMutex(&gHs->gcThreadMutex);
gHs->gcThreadShutdown = true;
dvmSignalCond(&gHs->gcThreadCond);
dvmUnlockMutex(&gHs->gcThreadMutex);
pthread_join(gHs->gcThread, NULL);
}
}
/*
* Create a stack big enough for the worst possible case, where the
* heap is perfectly full of the smallest object.
* TODO: be better about memory usage; use a smaller stack with
* overflow detection and recovery.
*/
static bool allocMarkStack(GcMarkStack *stack, size_t maximumSize)
{
const char *name = "dalvik-mark-stack";
void *addr;
assert(stack != NULL);
stack->length = maximumSize * sizeof(Object*) /
(sizeof(Object) + HEAP_SOURCE_CHUNK_OVERHEAD);
addr = dvmAllocRegion(stack->length, PROT_READ | PROT_WRITE, name);
if (addr == NULL) {
return false;
}
stack->base = (const Object **)addr;
stack->limit = (const Object **)((char *)addr + stack->length);
stack->top = NULL;
madvise(stack->base, stack->length, MADV_DONTNEED);
return true;
}
static void freeMarkStack(GcMarkStack *stack)
{
assert(stack != NULL);
munmap(stack->base, stack->length);
memset(stack, 0, sizeof(*stack));
}
/*
* Initializes the heap source; must be called before any other
* dvmHeapSource*() functions. Returns a GcHeap structure
* allocated from the heap source.
*/
GcHeap* dvmHeapSourceStartup(size_t startSize, size_t maximumSize,
size_t growthLimit)
{
GcHeap *gcHeap;
HeapSource *hs;
mspace msp;
size_t length;
void *base;
assert(gHs == NULL);
if (!(startSize <= growthLimit && growthLimit <= maximumSize)) {
LOGE("Bad heap size parameters (start=%zd, max=%zd, limit=%zd)",
startSize, maximumSize, growthLimit);
return NULL;
}
/*
* Allocate a contiguous region of virtual memory to subdivided
* among the heaps managed by the garbage collector.
*/
length = ALIGN_UP_TO_PAGE_SIZE(maximumSize);
base = dvmAllocRegion(length, PROT_NONE, "dalvik-heap");
if (base == NULL) {
return NULL;
}
/* Create an unlocked dlmalloc mspace to use as
* a heap source.
*/
msp = createMspace(base, startSize, maximumSize);
if (msp == NULL) {
goto fail;
}
gcHeap = (GcHeap *)malloc(sizeof(*gcHeap));
if (gcHeap == NULL) {
LOGE_HEAP("Can't allocate heap descriptor");
goto fail;
}
memset(gcHeap, 0, sizeof(*gcHeap));
hs = (HeapSource *)malloc(sizeof(*hs));
if (hs == NULL) {
LOGE_HEAP("Can't allocate heap source");
free(gcHeap);
goto fail;
}
memset(hs, 0, sizeof(*hs));
hs->targetUtilization = DEFAULT_HEAP_UTILIZATION;
hs->startSize = startSize;
hs->maximumSize = maximumSize;
hs->growthLimit = growthLimit;
hs->idealSize = startSize;
hs->softLimit = SIZE_MAX; // no soft limit at first
hs->numHeaps = 0;
hs->sawZygote = gDvm.zygote;
hs->hasGcThread = false;
hs->heapBase = (char *)base;
hs->heapLength = length;
if (!addInitialHeap(hs, msp, growthLimit)) {
LOGE_HEAP("Can't add initial heap");
goto fail;
}
if (!dvmHeapBitmapInit(&hs->liveBits, base, length, "dalvik-bitmap-1")) {
LOGE_HEAP("Can't create liveBits");
goto fail;
}
if (!dvmHeapBitmapInit(&hs->markBits, base, length, "dalvik-bitmap-2")) {
LOGE_HEAP("Can't create markBits");
dvmHeapBitmapDelete(&hs->liveBits);
goto fail;
}
if (!allocMarkStack(&gcHeap->markContext.stack, hs->maximumSize)) {
LOGE("Can't create markStack");
dvmHeapBitmapDelete(&hs->markBits);
dvmHeapBitmapDelete(&hs->liveBits);
goto fail;
}
gcHeap->markContext.bitmap = &hs->markBits;
gcHeap->heapSource = hs;
gHs = hs;
return gcHeap;
fail:
munmap(base, length);
return NULL;
}
bool dvmHeapSourceStartupAfterZygote()
{
return gDvm.concurrentMarkSweep ? gcDaemonStartup() : true;
}
/*
* This is called while in zygote mode, right before we fork() for the
* first time. We create a heap for all future zygote process allocations,
* in an attempt to avoid touching pages in the zygote heap. (This would
* probably be unnecessary if we had a compacting GC -- the source of our
* troubles is small allocations filling in the gaps from larger ones.)
*/
bool dvmHeapSourceStartupBeforeFork()
{
HeapSource *hs = gHs; // use a local to avoid the implicit "volatile"
HS_BOILERPLATE();
assert(gDvm.zygote);
if (!gDvm.newZygoteHeapAllocated) {
/* Create a new heap for post-fork zygote allocations. We only
* try once, even if it fails.
*/
LOGV("Splitting out new zygote heap");
gDvm.newZygoteHeapAllocated = true;
return addNewHeap(hs);
}
return true;
}
void dvmHeapSourceThreadShutdown()
{
if (gDvm.gcHeap != NULL && gDvm.concurrentMarkSweep) {
gcDaemonShutdown();
}
}
/*
* Tears down the entire GcHeap structure and all of the substructures
* attached to it. This call has the side effect of setting the given
* gcHeap pointer and gHs to NULL.
*/
void dvmHeapSourceShutdown(GcHeap **gcHeap)
{
assert(gcHeap != NULL);
if (*gcHeap != NULL && (*gcHeap)->heapSource != NULL) {
HeapSource *hs = (*gcHeap)->heapSource;
dvmHeapBitmapDelete(&hs->liveBits);
dvmHeapBitmapDelete(&hs->markBits);
freeMarkStack(&(*gcHeap)->markContext.stack);
munmap(hs->heapBase, hs->heapLength);
free(hs);
gHs = NULL;
free(*gcHeap);
*gcHeap = NULL;
}
}
/*
* Gets the begining of the allocation for the HeapSource.
*/
void *dvmHeapSourceGetBase()
{
return gHs->heapBase;
}
/*
* Returns the requested value. If the per-heap stats are requested, fill
* them as well.
*
* Caller must hold the heap lock.
*/
size_t dvmHeapSourceGetValue(HeapSourceValueSpec spec, size_t perHeapStats[],
size_t arrayLen)
{
HeapSource *hs = gHs;
size_t value = 0;
size_t total = 0;
HS_BOILERPLATE();
assert(arrayLen >= hs->numHeaps || perHeapStats == NULL);
for (size_t i = 0; i < hs->numHeaps; i++) {
Heap *const heap = &hs->heaps[i];
switch (spec) {
case HS_FOOTPRINT:
value = mspace_footprint(heap->msp);
break;
case HS_ALLOWED_FOOTPRINT:
value = mspace_max_allowed_footprint(heap->msp);
break;
case HS_BYTES_ALLOCATED:
value = heap->bytesAllocated;
break;
case HS_OBJECTS_ALLOCATED:
value = heap->objectsAllocated;
break;
default:
// quiet gcc
break;
}
if (perHeapStats) {
perHeapStats[i] = value;
}
total += value;
}
return total;
}
void dvmHeapSourceGetRegions(uintptr_t *base, uintptr_t *max, size_t numHeaps)
{
HeapSource *hs = gHs;
HS_BOILERPLATE();
assert(numHeaps <= hs->numHeaps);
for (size_t i = 0; i < numHeaps; ++i) {
base[i] = (uintptr_t)hs->heaps[i].base;
max[i] = MIN((uintptr_t)hs->heaps[i].limit - 1, hs->markBits.max);
}
}
/*
* Get the bitmap representing all live objects.
*/
HeapBitmap *dvmHeapSourceGetLiveBits()
{
HS_BOILERPLATE();
return &gHs->liveBits;
}
/*
* Get the bitmap representing all marked objects.
*/
HeapBitmap *dvmHeapSourceGetMarkBits()
{
HS_BOILERPLATE();
return &gHs->markBits;
}
void dvmHeapSourceSwapBitmaps()
{
HeapBitmap tmp = gHs->liveBits;
gHs->liveBits = gHs->markBits;
gHs->markBits = tmp;
}
void dvmHeapSourceZeroMarkBitmap()
{
HS_BOILERPLATE();
dvmHeapBitmapZero(&gHs->markBits);
}
void dvmMarkImmuneObjects(const char *immuneLimit)
{
/*
* Copy the contents of the live bit vector for immune object
* range into the mark bit vector.
*/
/* The only values generated by dvmHeapSourceGetImmuneLimit() */
assert(immuneLimit == gHs->heaps[0].base ||
immuneLimit == NULL);
assert(gHs->liveBits.base == gHs->markBits.base);
assert(gHs->liveBits.bitsLen == gHs->markBits.bitsLen);
/* heap[0] is never immune */
assert(gHs->heaps[0].base >= immuneLimit);
assert(gHs->heaps[0].limit > immuneLimit);
for (size_t i = 1; i < gHs->numHeaps; ++i) {
if (gHs->heaps[i].base < immuneLimit) {
assert(gHs->heaps[i].limit <= immuneLimit);
/* Compute the number of words to copy in the bitmap. */
size_t index = HB_OFFSET_TO_INDEX(
(uintptr_t)gHs->heaps[i].base - gHs->liveBits.base);
/* Compute the starting offset in the live and mark bits. */
char *src = (char *)(gHs->liveBits.bits + index);
char *dst = (char *)(gHs->markBits.bits + index);
/* Compute the number of bytes of the live bitmap to copy. */
size_t length = HB_OFFSET_TO_BYTE_INDEX(
gHs->heaps[i].limit - gHs->heaps[i].base);
/* Do the copy. */
memcpy(dst, src, length);
/* Make sure max points to the address of the highest set bit. */
if (gHs->markBits.max < (uintptr_t)gHs->heaps[i].limit) {
gHs->markBits.max = (uintptr_t)gHs->heaps[i].limit;
}
}
}
}
/*
* Allocates <n> bytes of zeroed data.
*/
void* dvmHeapSourceAlloc(size_t n)
{
HS_BOILERPLATE();
HeapSource *hs = gHs;
Heap* heap = hs2heap(hs);
if (heap->bytesAllocated + n > hs->softLimit) {
/*
* This allocation would push us over the soft limit; act as
* if the heap is full.
*/
LOGV_HEAP("softLimit of %zd.%03zdMB hit for %zd-byte allocation",
FRACTIONAL_MB(hs->softLimit), n);
return NULL;
}
void* ptr = mspace_calloc(heap->msp, 1, n);
if (ptr == NULL) {
return NULL;
}
countAllocation(heap, ptr);
/*
* Check to see if a concurrent GC should be initiated.
*/
if (gDvm.gcHeap->gcRunning || !hs->hasGcThread) {
/*
* The garbage collector thread is already running or has yet
* to be started. Do nothing.
*/
return ptr;
}
if (heap->bytesAllocated > heap->concurrentStartBytes) {
/*
* We have exceeded the allocation threshold. Wake up the
* garbage collector.
*/
dvmSignalCond(&gHs->gcThreadCond);
}
return ptr;
}
/* Remove any hard limits, try to allocate, and shrink back down.
* Last resort when trying to allocate an object.
*/
static void* heapAllocAndGrow(HeapSource *hs, Heap *heap, size_t n)
{
/* Grow as much as possible, but don't let the real footprint
* go over the absolute max.
*/
size_t max = heap->maximumSize;
mspace_set_max_allowed_footprint(heap->msp, max);
void* ptr = dvmHeapSourceAlloc(n);
/* Shrink back down as small as possible. Our caller may
* readjust max_allowed to a more appropriate value.
*/
mspace_set_max_allowed_footprint(heap->msp,
mspace_footprint(heap->msp));
return ptr;
}
/*
* Allocates <n> bytes of zeroed data, growing as much as possible
* if necessary.
*/
void* dvmHeapSourceAllocAndGrow(size_t n)
{
HS_BOILERPLATE();
HeapSource *hs = gHs;
Heap* heap = hs2heap(hs);
void* ptr = dvmHeapSourceAlloc(n);
if (ptr != NULL) {
return ptr;
}
size_t oldIdealSize = hs->idealSize;
if (isSoftLimited(hs)) {
/* We're soft-limited. Try removing the soft limit to
* see if we can allocate without actually growing.
*/
hs->softLimit = SIZE_MAX;
ptr = dvmHeapSourceAlloc(n);
if (ptr != NULL) {
/* Removing the soft limit worked; fix things up to
* reflect the new effective ideal size.
*/
snapIdealFootprint();
return ptr;
}
// softLimit intentionally left at SIZE_MAX.
}
/* We're not soft-limited. Grow the heap to satisfy the request.
* If this call fails, no footprints will have changed.
*/
ptr = heapAllocAndGrow(hs, heap, n);
if (ptr != NULL) {
/* The allocation succeeded. Fix up the ideal size to
* reflect any footprint modifications that had to happen.
*/
snapIdealFootprint();
} else {
/* We just couldn't do it. Restore the original ideal size,
* fixing up softLimit if necessary.
*/
setIdealFootprint(oldIdealSize);
}
return ptr;
}
/*
* Frees the first numPtrs objects in the ptrs list and returns the
* amount of reclaimed storage. The list must contain addresses all in
* the same mspace, and must be in increasing order. This implies that
* there are no duplicates, and no entries are NULL.
*/
size_t dvmHeapSourceFreeList(size_t numPtrs, void **ptrs)
{
HS_BOILERPLATE();
if (numPtrs == 0) {
return 0;
}
assert(ptrs != NULL);
assert(*ptrs != NULL);
Heap* heap = ptr2heap(gHs, *ptrs);
size_t numBytes = 0;
if (heap != NULL) {
mspace msp = heap->msp;
// Calling mspace_free on shared heaps disrupts sharing too
// much. For heap[0] -- the 'active heap' -- we call
// mspace_free, but on the other heaps we only do some
// accounting.
if (heap == gHs->heaps) {
// mspace_merge_objects takes two allocated objects, and
// if the second immediately follows the first, will merge
// them, returning a larger object occupying the same
// memory. This is a local operation, and doesn't require
// dlmalloc to manipulate any freelists. It's pretty
// inexpensive compared to free().
// ptrs is an array of objects all in memory order, and if
// client code has been allocating lots of short-lived
// objects, this is likely to contain runs of objects all
// now garbage, and thus highly amenable to this optimization.
// Unroll the 0th iteration around the loop below,
// countFree ptrs[0] and initializing merged.
assert(ptrs[0] != NULL);
assert(ptr2heap(gHs, ptrs[0]) == heap);
countFree(heap, ptrs[0], &numBytes);
void *merged = ptrs[0];
for (size_t i = 1; i < numPtrs; i++) {
assert(merged != NULL);
assert(ptrs[i] != NULL);
assert((intptr_t)merged < (intptr_t)ptrs[i]);
assert(ptr2heap(gHs, ptrs[i]) == heap);
countFree(heap, ptrs[i], &numBytes);
// Try to merge. If it works, merged now includes the
// memory of ptrs[i]. If it doesn't, free merged, and
// see if ptrs[i] starts a new run of adjacent
// objects to merge.
if (mspace_merge_objects(msp, merged, ptrs[i]) == NULL) {
mspace_free(msp, merged);
merged = ptrs[i];
}
}
assert(merged != NULL);
mspace_free(msp, merged);
} else {
// This is not an 'active heap'. Only do the accounting.
for (size_t i = 0; i < numPtrs; i++) {
assert(ptrs[i] != NULL);
assert(ptr2heap(gHs, ptrs[i]) == heap);
countFree(heap, ptrs[i], &numBytes);
}
}
}
return numBytes;
}
/*
* Returns true iff <ptr> is in the heap source.
*/
bool dvmHeapSourceContainsAddress(const void *ptr)
{
HS_BOILERPLATE();
return (dvmHeapBitmapCoversAddress(&gHs->liveBits, ptr));
}
/*
* Returns true iff <ptr> was allocated from the heap source.
*/
bool dvmHeapSourceContains(const void *ptr)
{
HS_BOILERPLATE();
if (dvmHeapSourceContainsAddress(ptr)) {
return dvmHeapBitmapIsObjectBitSet(&gHs->liveBits, ptr) != 0;
}
return false;
}
bool dvmIsZygoteObject(const Object* obj)
{
HeapSource *hs = gHs;
HS_BOILERPLATE();
if (dvmHeapSourceContains(obj) && hs->sawZygote) {
Heap *heap = ptr2heap(hs, obj);
if (heap != NULL) {
/* If the object is not in the active heap, we assume that
* it was allocated as part of zygote.
*/
return heap != hs->heaps;
}
}
/* The pointer is outside of any known heap, or we are not
* running in zygote mode.
*/
return false;
}
/*
* Returns the number of usable bytes in an allocated chunk; the size
* may be larger than the size passed to dvmHeapSourceAlloc().
*/
size_t dvmHeapSourceChunkSize(const void *ptr)
{
HS_BOILERPLATE();
Heap* heap = ptr2heap(gHs, ptr);
if (heap != NULL) {
return mspace_usable_size(heap->msp, ptr);
}
return 0;
}
/*
* Returns the number of bytes that the heap source has allocated
* from the system using sbrk/mmap, etc.
*
* Caller must hold the heap lock.
*/
size_t dvmHeapSourceFootprint()
{
HS_BOILERPLATE();
//TODO: include size of bitmaps?
return oldHeapOverhead(gHs, true);
}
static size_t getMaximumSize(const HeapSource *hs)
{
return hs->growthLimit;
}
/*
* Returns the current maximum size of the heap source respecting any
* growth limits.
*/
size_t dvmHeapSourceGetMaximumSize()
{
HS_BOILERPLATE();
return getMaximumSize(gHs);
}
/*
* Removes any growth limits. Allows the user to allocate up to the
* maximum heap size.
*/
void dvmClearGrowthLimit()
{
HS_BOILERPLATE();
dvmLockHeap();
dvmWaitForConcurrentGcToComplete();
gDvm.gcHeap->cardTableLength = gDvm.gcHeap->cardTableMaxLength;
gHs->growthLimit = gHs->maximumSize;
size_t overhead = oldHeapOverhead(gHs, false);
gHs->heaps[0].maximumSize = gHs->maximumSize - overhead;
gHs->heaps[0].limit = gHs->heaps[0].base + gHs->heaps[0].maximumSize;
dvmUnlockHeap();
}
/*
* Return the real bytes used by old heaps plus the soft usage of the
* current heap. When a soft limit is in effect, this is effectively
* what it's compared against (though, in practice, it only looks at
* the current heap).
*/
static size_t getSoftFootprint(bool includeActive)
{
HS_BOILERPLATE();
HeapSource *hs = gHs;
size_t ret = oldHeapOverhead(hs, false);
if (includeActive) {
ret += hs->heaps[0].bytesAllocated;
}
return ret;
}
/*
* Gets the maximum number of bytes that the heap source is allowed
* to allocate from the system.
*/
size_t dvmHeapSourceGetIdealFootprint()
{
HeapSource *hs = gHs;
HS_BOILERPLATE();
return hs->idealSize;
}
/*
* Sets the soft limit, handling any necessary changes to the allowed
* footprint of the active heap.
*/
static void setSoftLimit(HeapSource *hs, size_t softLimit)
{
/* Compare against the actual footprint, rather than the
* max_allowed, because the heap may not have grown all the
* way to the allowed size yet.
*/
mspace msp = hs->heaps[0].msp;
size_t currentHeapSize = mspace_footprint(msp);
if (softLimit < currentHeapSize) {
/* Don't let the heap grow any more, and impose a soft limit.
*/
mspace_set_max_allowed_footprint(msp, currentHeapSize);
hs->softLimit = softLimit;
} else {
/* Let the heap grow to the requested max, and remove any
* soft limit, if set.
*/
mspace_set_max_allowed_footprint(msp, softLimit);
hs->softLimit = SIZE_MAX;
}
}
/*
* Sets the maximum number of bytes that the heap source is allowed
* to allocate from the system. Clamps to the appropriate maximum
* value.
*/
static void setIdealFootprint(size_t max)
{
HS_BOILERPLATE();
HeapSource *hs = gHs;
size_t maximumSize = getMaximumSize(hs);
if (max > maximumSize) {
LOGI_HEAP("Clamp target GC heap from %zd.%03zdMB to %u.%03uMB",
FRACTIONAL_MB(max),
FRACTIONAL_MB(maximumSize));
max = maximumSize;
}
/* Convert max into a size that applies to the active heap.
* Old heaps will count against the ideal size.
*/
size_t overhead = getSoftFootprint(false);
size_t activeMax;
if (overhead < max) {
activeMax = max - overhead;
} else {
activeMax = 0;
}
setSoftLimit(hs, activeMax);
hs->idealSize = max;
}
/*
* Make the ideal footprint equal to the current footprint.
*/
static void snapIdealFootprint()
{
HS_BOILERPLATE();
setIdealFootprint(getSoftFootprint(true));
}
/*
* Gets the current ideal heap utilization, represented as a number
* between zero and one.
*/
float dvmGetTargetHeapUtilization()
{
HeapSource *hs = gHs;
HS_BOILERPLATE();
return (float)hs->targetUtilization / (float)HEAP_UTILIZATION_MAX;
}
/*
* Sets the new ideal heap utilization, represented as a number
* between zero and one.
*/
void dvmSetTargetHeapUtilization(float newTarget)
{
HeapSource *hs = gHs;
HS_BOILERPLATE();
/* Clamp it to a reasonable range.
*/
// TODO: This may need some tuning.
if (newTarget < 0.2) {
newTarget = 0.2;
} else if (newTarget > 0.8) {
newTarget = 0.8;
}
hs->targetUtilization =
(size_t)(newTarget * (float)HEAP_UTILIZATION_MAX);
LOGV("Set heap target utilization to %zd/%d (%f)",
hs->targetUtilization, HEAP_UTILIZATION_MAX, newTarget);
}
/*
* Given the size of a live set, returns the ideal heap size given
* the current target utilization and MIN/MAX values.
*
* targetUtilization is in the range 1..HEAP_UTILIZATION_MAX.
*/
static size_t getUtilizationTarget(size_t liveSize, size_t targetUtilization)
{
/* Use the current target utilization ratio to determine the
* ideal heap size based on the size of the live set.
*/
size_t targetSize = (liveSize / targetUtilization) * HEAP_UTILIZATION_MAX;
/* Cap the amount of free space, though, so we don't end up
* with, e.g., 8MB of free space when the live set size hits 8MB.
*/
if (targetSize > liveSize + HEAP_IDEAL_FREE) {
targetSize = liveSize + HEAP_IDEAL_FREE;
} else if (targetSize < liveSize + HEAP_MIN_FREE) {
targetSize = liveSize + HEAP_MIN_FREE;
}
return targetSize;
}
/*
* Given the current contents of the active heap, increase the allowed
* heap footprint to match the target utilization ratio. This
* should only be called immediately after a full mark/sweep.
*/
void dvmHeapSourceGrowForUtilization()
{
HS_BOILERPLATE();
HeapSource *hs = gHs;
Heap* heap = hs2heap(hs);
/* Use the current target utilization ratio to determine the
* ideal heap size based on the size of the live set.
* Note that only the active heap plays any part in this.
*
* Avoid letting the old heaps influence the target free size,
* because they may be full of objects that aren't actually
* in the working set. Just look at the allocated size of
* the current heap.
*/
size_t currentHeapUsed = heap->bytesAllocated;
size_t targetHeapSize =
getUtilizationTarget(currentHeapUsed, hs->targetUtilization);
/* The ideal size includes the old heaps; add overhead so that
* it can be immediately subtracted again in setIdealFootprint().
* If the target heap size would exceed the max, setIdealFootprint()
* will clamp it to a legal value.
*/
size_t overhead = getSoftFootprint(false);
setIdealFootprint(targetHeapSize + overhead);
size_t freeBytes = getAllocLimit(hs);
if (freeBytes < CONCURRENT_MIN_FREE) {
/* Not enough free memory to allow a concurrent GC. */
heap->concurrentStartBytes = SIZE_MAX;
} else {
heap->concurrentStartBytes = freeBytes - CONCURRENT_START;
}
}
/*
* Return free pages to the system.
* TODO: move this somewhere else, especially the native heap part.
*/
static void releasePagesInRange(void *start, void *end, void *nbytes)
{
/* Linux requires that the madvise() start address is page-aligned.
* We also align the end address.
*/
start = (void *)ALIGN_UP_TO_PAGE_SIZE(start);
end = (void *)((size_t)end & ~(SYSTEM_PAGE_SIZE - 1));
if (start < end) {
size_t length = (char *)end - (char *)start;
madvise(start, length, MADV_DONTNEED);
*(size_t *)nbytes += length;
}
}
/*
* Return unused memory to the system if possible.
*/
static void trimHeaps()
{
HS_BOILERPLATE();
HeapSource *hs = gHs;
size_t heapBytes = 0;
for (size_t i = 0; i < hs->numHeaps; i++) {
Heap *heap = &hs->heaps[i];
/* Return the wilderness chunk to the system.
*/
mspace_trim(heap->msp, 0);
/* Return any whole free pages to the system.
*/
mspace_walk_free_pages(heap->msp, releasePagesInRange, &heapBytes);
}
/* Same for the native heap.
*/
dlmalloc_trim(0);
size_t nativeBytes = 0;
dlmalloc_walk_free_pages(releasePagesInRange, &nativeBytes);
LOGD_HEAP("madvised %zd (GC) + %zd (native) = %zd total bytes",
heapBytes, nativeBytes, heapBytes + nativeBytes);
}
/*
* Walks over the heap source and passes every allocated and
* free chunk to the callback.
*/
void dvmHeapSourceWalk(void(*callback)(const void *chunkptr, size_t chunklen,
const void *userptr, size_t userlen,
void *arg),
void *arg)
{
HS_BOILERPLATE();
/* Walk the heaps from oldest to newest.
*/
//TODO: do this in address order
HeapSource *hs = gHs;
for (size_t i = hs->numHeaps; i > 0; --i) {
mspace_walk_heap(hs->heaps[i-1].msp, callback, arg);
}
}
/*
* Gets the number of heaps available in the heap source.
*
* Caller must hold the heap lock, because gHs caches a field
* in gDvm.gcHeap.
*/
size_t dvmHeapSourceGetNumHeaps()
{
HS_BOILERPLATE();
return gHs->numHeaps;
}
void *dvmHeapSourceGetImmuneLimit(bool isPartial)
{
if (isPartial) {
return hs2heap(gHs)->base;
} else {
return NULL;
}
}