/* * Copyright (C) 2010 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 /* for PROT_* */ #include "Dalvik.h" #include "alloc/HeapBitmap.h" #include "alloc/HeapBitmapInlines.h" #include "alloc/HeapSource.h" #include "alloc/Visit.h" /* * Maintain a card table from the the write barrier. All writes of * non-NULL values to heap addresses should go through an entry in * WriteBarrier, and from there to here. * * The heap is divided into "cards" of GC_CARD_SIZE bytes, as * determined by GC_CARD_SHIFT. The card table contains one byte of * data per card, to be used by the GC. The value of the byte will be * one of GC_CARD_CLEAN or GC_CARD_DIRTY. * * After any store of a non-NULL object pointer into a heap object, * code is obliged to mark the card dirty. The setters in * ObjectInlines.h [such as dvmSetFieldObject] do this for you. The * JIT and fast interpreters also contain code to mark cards as dirty. * * The card table's base [the "biased card table"] gets set to a * rather strange value. In order to keep the JIT from having to * fabricate or load GC_DIRTY_CARD to store into the card table, * biased base is within the mmap allocation at a point where it's low * byte is equal to GC_DIRTY_CARD. See dvmCardTableStartup for details. */ /* * Initializes the card table; must be called before any other * dvmCardTable*() functions. */ bool dvmCardTableStartup(size_t heapMaximumSize, size_t growthLimit) { size_t length; void *allocBase; u1 *biasedBase; GcHeap *gcHeap = gDvm.gcHeap; int offset; void *heapBase = dvmHeapSourceGetBase(); assert(gcHeap != NULL); assert(heapBase != NULL); /* All zeros is the correct initial value; all clean. */ assert(GC_CARD_CLEAN == 0); /* Set up the card table */ length = heapMaximumSize / GC_CARD_SIZE; /* Allocate an extra 256 bytes to allow fixed low-byte of base */ allocBase = dvmAllocRegion(length + 0x100, PROT_READ | PROT_WRITE, "dalvik-card-table"); if (allocBase == NULL) { return false; } gcHeap->cardTableBase = (u1*)allocBase; gcHeap->cardTableLength = growthLimit / GC_CARD_SIZE; gcHeap->cardTableMaxLength = length; biasedBase = (u1 *)((uintptr_t)allocBase - ((uintptr_t)heapBase >> GC_CARD_SHIFT)); offset = GC_CARD_DIRTY - ((uintptr_t)biasedBase & 0xff); gcHeap->cardTableOffset = offset + (offset < 0 ? 0x100 : 0); biasedBase += gcHeap->cardTableOffset; assert(((uintptr_t)biasedBase & 0xff) == GC_CARD_DIRTY); gDvm.biasedCardTableBase = biasedBase; return true; } /* * Tears down the entire CardTable. */ void dvmCardTableShutdown() { gDvm.biasedCardTableBase = NULL; munmap(gDvm.gcHeap->cardTableBase, gDvm.gcHeap->cardTableLength); } void dvmClearCardTable() { /* * The goal is to zero out some mmap-allocated pages. We can accomplish * this with memset() or madvise(MADV_DONTNEED). The latter has some * useful properties, notably that the pages are returned to the system, * so cards for parts of the heap we haven't expanded into won't be * allocated physical pages. On the other hand, if we un-map the card * area, we'll have to fault it back in as we resume dirtying objects, * which reduces performance. * * We don't cause any correctness issues by failing to clear cards; we * just take a performance hit during the second pause of the concurrent * collection. The "advisory" nature of madvise() isn't a big problem. * * What we really want to do is: * (1) zero out all cards that were touched * (2) use madvise() to release any pages that won't be used in the near * future * * For #1, we don't really know which cards were touched, but we can * approximate it with the "live bits max" value, which tells us the * highest start address at which an object was allocated. This may * leave vestigial nonzero entries at the end if temporary objects are * created during a concurrent GC, but that should be harmless. (We * can round up to the end of the card table page to reduce this.) * * For #2, we don't know which pages will be used in the future. Some * simple experiments suggested that a "typical" app will touch about * 60KB of pages while initializing, but drops down to 20-24KB while * idle. We can save a few hundred KB system-wide with aggressive * use of madvise(). The cost of mapping those pages back in is paid * outside of the GC pause, which reduces the impact. (We might be * able to get the benefits by only doing this occasionally, e.g. if * the heap shrinks a lot or we somehow notice that we've been idle.) * * Note that cardTableLength is initially set to the growth limit, and * on request will be expanded to the heap maximum. */ assert(gDvm.gcHeap->cardTableBase != NULL); if (gDvm.lowMemoryMode) { // zero out cards with madvise(), discarding all pages in the card table madvise(gDvm.gcHeap->cardTableBase, gDvm.gcHeap->cardTableLength, MADV_DONTNEED); } else { // zero out cards with memset(), using liveBits as an estimate const HeapBitmap* liveBits = dvmHeapSourceGetLiveBits(); size_t maxLiveCard = (liveBits->max - liveBits->base) / GC_CARD_SIZE; maxLiveCard = ALIGN_UP_TO_PAGE_SIZE(maxLiveCard); if (maxLiveCard > gDvm.gcHeap->cardTableLength) { maxLiveCard = gDvm.gcHeap->cardTableLength; } memset(gDvm.gcHeap->cardTableBase, GC_CARD_CLEAN, maxLiveCard); } } /* * Returns true iff the address is within the bounds of the card table. */ bool dvmIsValidCard(const u1 *cardAddr) { GcHeap *h = gDvm.gcHeap; u1* begin = h->cardTableBase + h->cardTableOffset; u1* end = &begin[h->cardTableLength]; return cardAddr >= begin && cardAddr < end; } /* * Returns the address of the relevant byte in the card table, given * an address on the heap. */ u1 *dvmCardFromAddr(const void *addr) { u1 *biasedBase = gDvm.biasedCardTableBase; u1 *cardAddr = biasedBase + ((uintptr_t)addr >> GC_CARD_SHIFT); assert(dvmIsValidCard(cardAddr)); return cardAddr; } /* * Returns the first address in the heap which maps to this card. */ void *dvmAddrFromCard(const u1 *cardAddr) { assert(dvmIsValidCard(cardAddr)); uintptr_t offset = cardAddr - gDvm.biasedCardTableBase; return (void *)(offset << GC_CARD_SHIFT); } /* * Dirties the card for the given address. */ void dvmMarkCard(const void *addr) { u1 *cardAddr = dvmCardFromAddr(addr); *cardAddr = GC_CARD_DIRTY; } /* * Returns true if the object is on a dirty card. */ static bool isObjectDirty(const Object *obj) { assert(obj != NULL); assert(dvmIsValidObject(obj)); u1 *card = dvmCardFromAddr(obj); return *card == GC_CARD_DIRTY; } /* * Context structure for verifying the card table. */ struct WhiteReferenceCounter { HeapBitmap *markBits; size_t whiteRefs; }; /* * Visitor that counts white referents. */ static void countWhiteReferenceVisitor(void *addr, void *arg) { WhiteReferenceCounter *ctx; Object *obj; assert(addr != NULL); assert(arg != NULL); obj = *(Object **)addr; if (obj == NULL) { return; } assert(dvmIsValidObject(obj)); ctx = (WhiteReferenceCounter *)arg; if (dvmHeapBitmapIsObjectBitSet(ctx->markBits, obj)) { return; } ctx->whiteRefs += 1; } /* * Visitor that logs white references. */ static void dumpWhiteReferenceVisitor(void *addr, void *arg) { WhiteReferenceCounter *ctx; Object *obj; assert(addr != NULL); assert(arg != NULL); obj = *(Object **)addr; if (obj == NULL) { return; } assert(dvmIsValidObject(obj)); ctx = (WhiteReferenceCounter*)arg; if (dvmHeapBitmapIsObjectBitSet(ctx->markBits, obj)) { return; } ALOGE("object %p is white", obj); } /* * Visitor that signals the caller when a matching reference is found. */ static void dumpReferencesVisitor(void *pObj, void *arg) { Object *obj = *(Object **)pObj; Object *lookingFor = *(Object **)arg; if (lookingFor != NULL && lookingFor == obj) { *(Object **)arg = NULL; } } static void dumpReferencesCallback(Object *obj, void *arg) { if (obj == (Object *)arg) { return; } dvmVisitObject(dumpReferencesVisitor, obj, &arg); if (arg == NULL) { ALOGD("Found %p in the heap @ %p", arg, obj); dvmDumpObject(obj); } } /* * Root visitor that looks for matching references. */ static void dumpReferencesRootVisitor(void *ptr, u4 threadId, RootType type, void *arg) { Object *obj = *(Object **)ptr; Object *lookingFor = *(Object **)arg; if (obj == lookingFor) { ALOGD("Found %p in a root @ %p", arg, ptr); } } /* * Invokes visitors to search for references to an object. */ static void dumpReferences(const Object *obj) { HeapBitmap *bitmap = dvmHeapSourceGetLiveBits(); void *arg = (void *)obj; dvmVisitRoots(dumpReferencesRootVisitor, arg); dvmHeapBitmapWalk(bitmap, dumpReferencesCallback, arg); } /* * Returns true if the given object is a reference object and the * just the referent is unmarked. */ static bool isReferentUnmarked(const Object *obj, const WhiteReferenceCounter* ctx) { assert(obj != NULL); assert(obj->clazz != NULL); assert(ctx != NULL); if (ctx->whiteRefs != 1) { return false; } else if (IS_CLASS_FLAG_SET(obj->clazz, CLASS_ISREFERENCE)) { size_t offset = gDvm.offJavaLangRefReference_referent; const Object *referent = dvmGetFieldObject(obj, offset); return !dvmHeapBitmapIsObjectBitSet(ctx->markBits, referent); } else { return false; } } /* * Returns true if the given object is a string and has been interned * by the user. */ static bool isWeakInternedString(const Object *obj) { assert(obj != NULL); if (obj->clazz == gDvm.classJavaLangString) { return dvmIsWeakInternedString((StringObject *)obj); } else { return false; } } /* * Returns true if the given object has been pushed on the mark stack * by root marking. */ static bool isPushedOnMarkStack(const Object *obj) { GcMarkStack *stack = &gDvm.gcHeap->markContext.stack; for (const Object **ptr = stack->base; ptr < stack->top; ++ptr) { if (*ptr == obj) { return true; } } return false; } /* * Callback applied to marked objects. If the object is gray and on * an unmarked card an error is logged and the VM is aborted. Card * table verification occurs between root marking and weak reference * processing. We treat objects marked from the roots and weak * references specially as it is permissible for these objects to be * gray and on an unmarked card. */ static void verifyCardTableCallback(Object *obj, void *arg) { WhiteReferenceCounter ctx = { (HeapBitmap *)arg, 0 }; dvmVisitObject(countWhiteReferenceVisitor, obj, &ctx); if (ctx.whiteRefs == 0) { return; } else if (isObjectDirty(obj)) { return; } else if (isReferentUnmarked(obj, &ctx)) { return; } else if (isWeakInternedString(obj)) { return; } else if (isPushedOnMarkStack(obj)) { return; } else { ALOGE("Verify failed, object %p is gray and on an unmarked card", obj); dvmDumpObject(obj); dvmVisitObject(dumpWhiteReferenceVisitor, obj, &ctx); dumpReferences(obj); dvmAbort(); } } /* * Verifies that gray objects are on a dirty card. */ void dvmVerifyCardTable() { HeapBitmap *markBits = gDvm.gcHeap->markContext.bitmap; dvmHeapBitmapWalk(markBits, verifyCardTableCallback, markBits); }