internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
// Ignore pointers out of our memory area
if (PageTable.IsForeignAddr(addr))
{
return;
}
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsGcPage(pageType))
{
VTable.Assert((PageTable.IsNonGcPage(pageType) &&
PageTable.IsMyPage(page)) ||
PageTable.IsStackPage(pageType));
return;
}
VTable.Assert(PageTable.IsMyPage(page));
Object obj = Magic.fromAddress(addr);
VTable.Assert(IsPossiblyObject(obj), "Bad Object/VTable");
if (obj.GcMark() == UIntPtr.Zero)
{
// The object was not live
*loc = UIntPtr.Zero;
}
}
internal override int GetGeneration(Object obj)
{
UIntPtr addr = Magic.addressOf(obj);
UIntPtr page = PageTable.Page(addr);
return((int)PageTable.Type(page));
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsZombiePage(pageType))
{
VTable.Assert(PageTable.IsGcPage(pageType) ||
PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType));
return;
}
UIntPtr vtableAddr = Allocator.GetObjectVTable(addr);
if ((vtableAddr & 0x1) == 0x1)
{
// Link this field to be updated
*loc = vtableAddr;
Allocator.SetObjectVTable(addr, (UIntPtr)loc + 1);
}
else
{
// Zero the reference (not marked)
*loc = UIntPtr.Zero;
}
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsZombiePage(pageType))
{
VTable.Assert(PageTable.IsGcPage(pageType) ||
PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType));
return;
}
UIntPtr vtableAddr = Allocator.GetObjectVTable(addr);
// Mark object
if (vtableAddr == UIntPtr.Zero)
{
VTable.DebugPrint("Found null vtable in MarkReference (loc = 0x{0:x8}, addr = 0x{1:x8})\n",
__arglist(((UIntPtr)loc), addr));
VTable.NotReached();
}
*loc = vtableAddr;
Allocator.SetObjectVTable(addr, (UIntPtr)loc + 1);
// If first visit to the object, schedule visit of fields
if ((vtableAddr & 0x1) == 0)
{
MarkVisit(addr, vtableAddr & (UIntPtr) ~2U);
}
}
internal override unsafe void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
if (!PageTable.IsGcPage(page))
{
PageType pageType = PageTable.Type(page);
VTable.Assert(pageType == PageType.NonGC ||
pageType == PageType.Stack,
@"pageType == PageType.NonGC ||
pageType == PageType.Stack");
return;
}
UIntPtr objAddr = SegregatedFreeList.Find(addr);
Object obj = Magic.fromAddress(objAddr);
UIntPtr count = getBackupRefcount(obj);
setBackupRefcount(obj, count + 1);
if (obj.GcMark((UIntPtr)1))
{
this.workList.Write(objAddr);
}
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
// Ignore pointers out of our memory area
if (PageTable.IsForeignAddr(addr))
{
return;
}
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsGcPage(pageType))
{
VTable.Assert((PageTable.IsNonGcPage(pageType) &&
PageTable.IsMyPage(page)) ||
PageTable.IsStackPage(pageType));
return;
}
VTable.Assert(PageTable.IsMyPage(page));
Object obj = Magic.fromAddress(addr);
VTable.Assert(IsPossiblyObject(obj), "Bad object/vtable");
if (obj.GcMark((UIntPtr)1))
{
// We changed the color of the object, so we
// have to mark the objects reachable from the fields
workList.Write(addr);
}
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
// Ignore pointers out of our memory area
if (PageTable.IsForeignAddr(addr))
{
return;
}
UIntPtr page = PageTable.Page(addr);
if (!PageTable.IsMyGcPage(page))
{
PageType pageType = PageTable.Type(page);
#if SINGULARITY_PROCESS
// We have to allow reference pointers to the
// ThreadContext, which lives in the kernel space.
VTable.Assert((PageTable.IsNonGcPage(pageType) &&
PageTable.IsMyPage(page)) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType) ||
(PageTable.IsGcPage(pageType) &&
PageTable.IsKernelPage(page)));
#else
VTable.Assert((PageTable.IsNonGcPage(pageType) &&
PageTable.IsMyPage(page)) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType));
#endif
return;
}
UIntPtr objectAddr = SegregatedFreeList.Find(addr);
markAndProcessReferenceVisitor.Visit(&objectAddr);
}
internal static void VerifyUnusedPage(UIntPtr page, bool containsHeader)
{
if (PageTable.Type(page) == PageType.UnusedDirty)
{
return;
}
// Verify that the page is indeed clean
UIntPtr *startAddr = (UIntPtr *)PageTable.PageAddr(page);
UIntPtr *endAddr = (UIntPtr *)PageTable.PageAddr(page + 1);
// If the page contains a header then we can't expect the header
// to be clean.
if (containsHeader)
{
startAddr += (uint)
(Util.UIntPtrPad((UIntPtr)sizeof(UnusedBlockHeader))
/ (uint)sizeof(UIntPtr));
}
while (startAddr < endAddr)
{
VTable.Assert(*startAddr == UIntPtr.Zero,
"UnusedClean page contains nonzero data");
startAddr++;
}
}
internal override unsafe void Visit(UIntPtr *loc)
{
UIntPtr pageLoc = PageTable.Page((UIntPtr)loc);
PageType pageType = PageTable.Type(pageLoc);
if (pageType != PageType.NonGC &&
pageType != PageType.Stack)
{
VTable.Assert(PageTable.IsGcPage(pageLoc),
@"PageTable.IsGcPage(pageLoc)");
return;
}
uint addr = (uint)*loc;
if (pageType == PageType.NonGC || (addr & 0x03) == 0)
{
this.visitor.Visit(loc);
}
if (pageType == PageType.Stack)
{
*loc = (UIntPtr)(addr | 0x01);
}
}
internal override unsafe void Visit(UIntPtr *loc)
{
UIntPtr objAddr = *loc;
UIntPtr page = PageTable.Page(objAddr);
if (!PageTable.IsGcPage(page))
{
PageType pageType = PageTable.Type(page);
VTable.Assert(pageType == PageType.NonGC ||
pageType == PageType.Stack,
@"pageType == PageType.NonGC ||
pageType == PageType.Stack");
return;
}
Object obj = Magic.fromAddress(objAddr);
if (obj.GcMark((UIntPtr)1))
{
this.time = this.time + 1;
setDfsDiscoveryTime(obj, this.time);
UIntPtr vtableAddr = Magic.addressOf(obj.vtable);
this.Visit(&vtableAddr);
this.VisitReferenceFields(obj);
this.time = this.time + 1;
setDfsFinishingTime(obj, this.time);
}
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsZombiePage(pageType))
{
VTable.Assert(PageTable.IsGcPage(pageType) ||
PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType),
"Semispace:ForwardOnlyReferenceVisitor");
return;
}
PageType gen = PageTable.ZombieToLive(pageType);
UIntPtr vtableAddr = Allocator.GetObjectVTable(addr);
UIntPtr vtablePageIndex = PageTable.Page(vtableAddr);
if (PageTable.Type(vtablePageIndex) == gen)
{
// The vtable field is really a forwarding pointer
*loc = vtableAddr;
}
else
{
// The object was not live
*loc = UIntPtr.Zero;
}
}
internal static void VerifyUnusedRegion(UIntPtr startPage,
UIntPtr endPage)
{
// Verify that all of the pages are of the same Clean/Dirty type.
PageType startType = PageTable.Type(startPage);
for (UIntPtr page = startPage; page < endPage; ++page)
{
VTable.Assert(startType == PageTable.Type(page),
"Unused page types don't match in region");
}
if (startPage > UIntPtr.Zero &&
PageTable.IsUnusedPage(startPage - 1) &&
PageTable.IsMyPage(startPage - 1))
{
// We have already checked the region
return;
}
UIntPtr regionAddr = PageTable.PageAddr(startPage);
UnusedBlockHeader *regionHeader = (UnusedBlockHeader *)regionAddr;
UIntPtr pageCount = regionHeader->count;
VTable.Assert
(pageCount >= (endPage - startPage),
"Region-to-verify is larger than its header specifies");
endPage = startPage + pageCount;
for (UIntPtr page = startPage; page < endPage; ++page)
{
VTable.Assert(PageTable.IsUnusedPage(page) &&
PageTable.IsMyPage(page),
"Non my-unused page in unused region");
PageManager.VerifyUnusedPage
(page, (page == startPage) || (page == (endPage - 1)));
}
VTable.Assert(!(endPage < PageTable.pageTableCount &&
PageTable.IsUnusedPage(endPage) &&
PageTable.IsMyPage(endPage)),
"My-unused page immediately after unused region");
// Verify that the region is correctly linked into the
// list of unused memory blocks
int slot = SlotFromCount(pageCount);
UnusedBlockHeader *header = unusedMemoryBlocks[slot].next;
UnusedBlockHeader.Verify(header);
while (regionAddr != (UIntPtr)header)
{
header = header->next;
VTable.Assert(header != null,
"Unused region not list for its slot number");
UnusedBlockHeader.Verify(header);
}
}
internal static bool IsMyLiveGcCard(UIntPtr c)
{
VTable.Assert(IsValidCardNo(c), "IsMyLiveGcCard invalid");
UIntPtr page = PageTable.Page(CardAddr(c));
return(PageTable.IsMyPage(page) &&
PageTable.IsLiveGcPage(PageTable.Type(page)));
}
internal static bool TryReservePages(Thread currentThread,
UIntPtr startPage,
UIntPtr pageCount,
PageType newType,
ref bool fCleanPages)
{
Trace.Log(Trace.Area.Page,
"TryReservePages start={0:x} count={1:x}",
__arglist(startPage, pageCount));
VTable.Deny(PageTable.IsUnusedPageType(newType));
VTable.Assert(pageCount > UIntPtr.Zero);
VTable.Deny(startPage != UIntPtr.Zero &&
PageTable.IsUnusedPage(startPage - 1) &&
PageTable.IsMyPage(startPage - 1));
UIntPtr endPage = startPage + pageCount;
UIntPtr index = startPage;
while (index < endPage &&
PageTable.IsUnusedPage(index) &&
PageTable.IsMyPage(index))
{
index++;
}
if (PageTable.IsUnallocatedPage(PageTable.Type(index)))
{
// We should try to extend the region of allocated pages
UIntPtr pagesNeeded = pageCount - (index - startPage);
UIntPtr bytesNeeded = PageTable.RegionSize(pagesNeeded);
UIntPtr allocSize = Util.Pad(bytesNeeded, heap_commit_size);
UIntPtr startAddr = PageTable.PageAddr(index);
bool gotMemory = false;
bool iflag = EnterMutex(currentThread);
try {
gotMemory =
MemoryManager.AllocateMemory(startAddr, allocSize);
if (gotMemory)
{
UIntPtr allocPages = PageTable.PageCount(allocSize);
MarkUnusedPages(/* avoid recursive locking */ null,
index, allocPages, true);
}
} finally {
LeaveMutex(currentThread, iflag);
}
if (gotMemory)
{
bool success =
TryReserveUnusedPages(currentThread, startPage,
pageCount, newType,
ref fCleanPages);
Trace.Log(Trace.Area.Page,
"TryReservePages success={0}",
__arglist(success));
return(success);
}
}
return(false);
}
internal void ProcessPinnedPages(ReferenceVisitor ptrVisitor)
{
if (pinnedPageList == null || pinnedPageList.Count == 0)
{
return;
}
pinnedPageList.Sort(comparer);
int limit = pinnedPageList.Count;
for (int i = 0; i < limit; i++)
{
UIntPtr page = (UIntPtr)pinnedPageList[i];
PageType fromSpaceType = PageTable.Type(page);
VTable.Assert(PageTable.IsZombiePage(fromSpaceType),
"Semispace:RegisterPinnedReference:2");
PageType toSpaceType =
PageTable.ZombieToLive(fromSpaceType);
PageTable.SetType(page, toSpaceType);
}
int pageIndex = 0;
while (pageIndex < limit)
{
UIntPtr startPage = (UIntPtr)pinnedPageList[pageIndex];
UIntPtr endPage = startPage + 1;
pageIndex++;
while (pageIndex < limit &&
(UIntPtr)pinnedPageList[pageIndex] == endPage)
{
pageIndex++;
endPage++;
}
UIntPtr objectAddr = FirstPinnedObjectAddr(startPage);
UIntPtr pastAddr = PostPinnedObjectAddr(endPage);
while (objectAddr < pastAddr)
{
if (Allocator.IsAlignment(objectAddr))
{
objectAddr += UIntPtr.Size;
}
else if (BumpAllocator.IsUnusedSpace(objectAddr))
{
objectAddr = (PageTable.PagePad(objectAddr) +
PreHeader.Size);
}
else
{
Object obj = Magic.fromAddress(objectAddr);
objectAddr += ptrVisitor.VisitReferenceFields(obj);
}
}
}
}
internal override unsafe void Visit(UIntPtr *loc)
{
// <loc> is an address of a reference location
// in the static data area.
UIntPtr page = PageTable.Page((UIntPtr)loc);
PageType pageType = PageTable.Type(page);
VTable.Assert(pageType == PageType.NonGC,
@"pageType == PageType.NonGC");
PtrCount++;
}
internal static bool ShouldPin(UIntPtr objAddr)
{
UIntPtr page = PageTable.Page(objAddr);
if (PageTable.Type(page) != SegregatedFreeList.SMALL_OBJ_PAGE)
{
// in practice this won't be reached
return(true);
}
SegregatedFreeList.PageHeader *ph =
(SegregatedFreeList.PageHeader *)PageTable.PageAddr(page);
return(new CoCoPageUserValue(ph->userValue).Pinned);
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
Trace.Log(Trace.Area.Pointer,
"FwdThrRef: loc={0}, addr={1}, page={2}",
__arglist(loc, addr, page));
PageType pageType = PageTable.Type(page);
// if an object "spills" into a page that
// is pinned, and the object is copied
// during a collection, we will end up with
// the first part of the object in a zombie page
// the second part of the object in a GC page.
// We need to find the start of the object and
// use that to determine whether the object has
// been moved.
if (!PageTable.IsZombiePage(pageType) &&
!PageTable.IsGcPage(pageType))
{
VTable.Assert(PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType) ||
VTable.BuildC2Mods,
"Semispace:ForwardThreadReference");
return;
}
UIntPtr objectPtr = InteriorPtrTable.Find(addr);
if (objectPtr == addr)
{
generalReferenceVisitor.Visit(loc);
}
else
{
// we can check for the page type of
// objectPtr here to see if it is zombie page.
// If true we can just return.
UIntPtr newObject = objectPtr;
generalReferenceVisitor.Visit(&newObject);
UIntPtr newAddr = newObject + (addr - objectPtr);
Trace.Log(Trace.Area.Pointer,
"FwdThrRef: {0} -> {1}",
__arglist(addr, newAddr));
*loc = newAddr;
}
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
if (!PageTable.IsZombiePage(PageTable.Type(page)))
{
return;
}
UIntPtr objectAddr =
registerThreadReferenceVisitor.threadPtrQueue.Read();
UIntPtr addressDelta =
registerThreadReferenceVisitor.threadPtrQueue.Read();
*loc = objectAddr + addressDelta;
}
// BUGBUG: We are allocating an ArrayList while the collector
// is running. If the ArrayList gets big enough to be
// allocated in the older generation, then the RemSet has the
// potential to overflow since the boxed integers will reside
// in the young generation. We should eventually eliminate
// the use of ArrayList in this class as well as avoid boxing
// the page indices.
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsZombiePage(pageType))
{
VTable.Assert(PageTable.IsGcPage(pageType) ||
PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType) ||
VTable.BuildC2Mods,
"Semispace:RegisterPinnedReference:1");
return;
}
PageType gen = PageTable.ZombieToLive(pageType);
UIntPtr pinnedObjectAddr = InteriorPtrTable.Find(addr);
if (pinnedPageList == null)
{
pinnedPageList = new ArrayList();
comparer = new UIntPtrComparer();
}
Object pinnedObject = Magic.fromAddress(pinnedObjectAddr);
UIntPtr objectSize =
ObjectLayout.ObjectSize(pinnedObjectAddr,
pinnedObject.vtable);
UIntPtr beforeObjectAddr = pinnedObjectAddr - PreHeader.Size;
UIntPtr pastObjectAddr = beforeObjectAddr + objectSize;
UIntPtr firstPage = PageTable.Page(beforeObjectAddr);
UIntPtr lastPage = PageTable.Page(pastObjectAddr - 1);
for (UIntPtr i = firstPage; i <= lastPage; i++)
{
if (!pinnedPageList.Contains(i))
{
Trace.Log(Trace.Area.Pointer,
"RegPin: ptr={0} page={1} gen={2}",
__arglist(pinnedObjectAddr, i, gen));
GenerationalCollector.gcPromotedTable[(int)gen - 1] +=
PageTable.PageSize;
pinnedPageList.Add(i);
}
}
}
// this is _just_ a notification - it doesn't pin the object, it's just
// what we do if an object ends up being pinned.
internal static void NotifyPin(UIntPtr objAddr)
{
UIntPtr page = PageTable.Page(objAddr);
if (PageTable.Type(page) != SegregatedFreeList.SMALL_OBJ_PAGE)
{
return;
}
SegregatedFreeList.PageHeader *ph =
(SegregatedFreeList.PageHeader *)PageTable.PageAddr(page);
CoCoPageUserValue v = new CoCoPageUserValue(ph->userValue);
if (v.Marked)
{
v.Pinned = true;
}
ph->userValue = v.Bits;
}
internal override unsafe void Visit(UIntPtr *loc)
{
// <loc> is a traceable pointer; its referent
// either resides in the heap, the stack or in
// the static data area.
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
VTable.Assert(PageTable.IsMyPage(page),
"MemoryAccounting: !IsMyPage");
if (!PageTable.IsGcPage(page))
{
PageType pageType = PageTable.Type(page);
VTable.Assert(pageType == PageType.NonGC ||
pageType == PageType.Stack ||
pageType == PageType.Shared,
"unexpected page type");
if (pageType == PageType.NonGC)
{
// A managed pointer into the static data area.
managedPtrsToStaticData++;
}
else
{
// A managed pointer into the stack area.
managedPtrsToStack++;
}
return;
}
UIntPtr objAddr = GC.installedGC.FindObjectAddr(addr);
if (objAddr != addr)
{
// A "truly" interior pointer into a heap object.
interiorManagedHeapPtrs++;
}
else
{
exteriorManagedHeapPtrs++;
}
}
internal static uint TotalNumPages(PageType kind)
{
uint pageCount = 0;
for (UIntPtr i = UIntPtr.Zero; i < PageTable.pageTableCount;
i++)
{
if (PageTable.IsMyPage(i))
{
PageType pageType = PageTable.Type(i);
if (pageType == kind)
{
pageCount++;
}
}
}
return(pageCount);
}
internal override unsafe void Visit(UIntPtr *loc)
{
UIntPtr pageLoc = PageTable.Page((UIntPtr)loc);
PageType pageType = PageTable.Type(pageLoc);
if (pageType != PageType.NonGC &&
pageType != PageType.Stack)
{
VTable.Assert(PageTable.IsGcPage(pageLoc),
@"PageTable.IsGcPage(pageLoc)");
return;
}
if (pageType == PageType.Stack)
{
*loc = (UIntPtr)((uint)*loc & 0xfffffffc);
}
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
// Ignore pointers out of our memory area
if (PageTable.IsForeignAddr(addr))
{
return;
}
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (PageTable.IsGcPage(pageType))
{
Object obj = Magic.fromAddress(addr);
VTable.Assert(obj.GcMark() != UIntPtr.Zero);
VTable.Assert(PageTable.IsMyPage(page));
}
}
internal static unsafe void ClearThreadStack(Thread thread)
{
short threadIndex = (short)thread.threadIndex;
UIntPtr endPage = PageTable.Page(CallStack.StackBase(thread));
UIntPtr startPage = endPage - 1;
VTable.Assert(PageTable.IsStackPage(PageTable.Type(startPage)));
VTable.Assert(PageTable.Extra(startPage) == threadIndex);
while (startPage > 0 &&
PageTable.IsStackPage(PageTable.Type(startPage - 1)) &&
PageTable.Extra(startPage - 1) == threadIndex)
{
startPage--;
}
UIntPtr startAddr = PageTable.PageAddr(startPage);
UIntPtr size = PageTable.RegionSize(endPage - startPage);
SetUnallocatedPages(startAddr, size);
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsZombiePage(pageType))
{
VTable.Assert(PageTable.IsGcPage(pageType) ||
PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType));
return;
}
UIntPtr objectAddr = InteriorPtrTable.Find(addr);
this.threadPtrQueue.Write(objectAddr);
this.threadPtrQueue.Write(addr - objectAddr);
}
internal unsafe override void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
PageType pageType = PageTable.Type(page);
if (!PageTable.IsZombiePage(pageType))
{
VTable.Assert(PageTable.IsGcPage(pageType) ||
PageTable.IsNonGcPage(pageType) ||
PageTable.IsStackPage(pageType) ||
PageTable.IsSharedPage(pageType));
return;
}
UIntPtr objectAddr = InteriorPtrTable.Find(addr);
registerThreadReferenceVisitor.threadPtrQueue.Write(objectAddr);
registerThreadReferenceVisitor.threadPtrQueue.Write(addr - objectAddr);
*Allocator.GetObjectVTableAddress(objectAddr) |= (UIntPtr)2U;
}
internal override unsafe void Visit(UIntPtr *loc)
{
UIntPtr addr = *loc;
UIntPtr page = PageTable.Page(addr);
if (!PageTable.IsGcPage(page))
{
PageType pageType = PageTable.Type(page);
VTable.Assert(pageType == PageType.NonGC ||
pageType == PageType.Stack,
@"pageType == PageType.NonGC ||
pageType == PageType.Stack");
return;
}
UIntPtr objAddr = SegregatedFreeList.Find(addr);
incrementBackupRefCount.Traverse(objAddr);
}
private static void ReferenceCheck(PageType addrType, UIntPtr *addr,
Object value)
{
VTable.Assert(PageTable.IsGcPage(addrType));
if (GC.remsetType == RemSetType.Cards)
{
GenerationalGCData.
installedRemSet.RecordReference(addr, value);
return;
}
UIntPtr valueAddr = Magic.addressOf(value);
PageType valType = PageTable.Type(PageTable.Page(valueAddr));
if (PageTable.IsGcPage(valType) && (addrType > valType))
{
GenerationalGCData.
installedRemSet.RecordReference(addr, value);
}
}
