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Update kernel

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This commit is contained in:
Alex
2023-08-06 04:53:14 +03:00
parent 3b65386399
commit 2c51e4432f
181 changed files with 21873 additions and 21475 deletions
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778
Core/Memory/PhysicalMemoryManager.cpp
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@ -26,467 +26,477 @@
namespace Memory
{
uint64_t Physical::GetTotalMemory()
{
SmartLock(this->MemoryLock);
return this->TotalMemory;
}
uint64_t Physical::GetTotalMemory()
{
return this->TotalMemory.load();
}
uint64_t Physical::GetFreeMemory()
{
SmartLock(this->MemoryLock);
return this->FreeMemory;
}
uint64_t Physical::GetFreeMemory()
{
return this->FreeMemory.load();
}
uint64_t Physical::GetReservedMemory()
{
SmartLock(this->MemoryLock);
return this->ReservedMemory;
}
uint64_t Physical::GetReservedMemory()
{
return this->ReservedMemory.load();
}
uint64_t Physical::GetUsedMemory()
{
SmartLock(this->MemoryLock);
return this->UsedMemory;
}
uint64_t Physical::GetUsedMemory()
{
return this->UsedMemory.load();
}
bool Physical::SwapPage(void *Address)
{
fixme("%p", Address);
return false;
}
bool Physical::SwapPage(void *Address)
{
fixme("%p", Address);
return false;
}
bool Physical::SwapPages(void *Address, size_t PageCount)
{
for (size_t i = 0; i < PageCount; i++)
{
if (!this->SwapPage((void *)((uintptr_t)Address + (i * PAGE_SIZE))))
return false;
}
return false;
}
bool Physical::SwapPages(void *Address, size_t PageCount)
{
for (size_t i = 0; i < PageCount; i++)
{
if (!this->SwapPage((void *)((uintptr_t)Address + (i * PAGE_SIZE))))
return false;
}
return false;
}
bool Physical::UnswapPage(void *Address)
{
fixme("%p", Address);
return false;
}
bool Physical::UnswapPage(void *Address)
{
fixme("%p", Address);
return false;
}
bool Physical::UnswapPages(void *Address, size_t PageCount)
{
for (size_t i = 0; i < PageCount; i++)
{
if (!this->UnswapPage((void *)((uintptr_t)Address + (i * PAGE_SIZE))))
return false;
}
return false;
}
bool Physical::UnswapPages(void *Address, size_t PageCount)
{
for (size_t i = 0; i < PageCount; i++)
{
if (!this->UnswapPage((void *)((uintptr_t)Address + (i * PAGE_SIZE))))
return false;
}
return false;
}
void *Physical::RequestPage()
{
SmartLock(this->MemoryLock);
void *Physical::RequestPage()
{
SmartLock(this->MemoryLock);
for (; PageBitmapIndex < PageBitmap.Size * 8; PageBitmapIndex++)
{
if (PageBitmap[PageBitmapIndex] == true)
continue;
for (; PageBitmapIndex < PageBitmap.Size * 8; PageBitmapIndex++)
{
if (PageBitmap[PageBitmapIndex] == true)
continue;
this->LockPage((void *)(PageBitmapIndex * PAGE_SIZE));
this->LockPage((void *)(PageBitmapIndex * PAGE_SIZE));
#ifdef DEBUG
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "RequestPage( )=%p~%p\n\r",
(void *)(PageBitmapIndex * PAGE_SIZE), __builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "RequestPage( )=%p~%p\n\r",
(void *)(PageBitmapIndex * PAGE_SIZE), __builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
#endif
return (void *)(PageBitmapIndex * PAGE_SIZE);
}
return (void *)(PageBitmapIndex * PAGE_SIZE);
}
if (this->SwapPage((void *)(PageBitmapIndex * PAGE_SIZE)))
{
this->LockPage((void *)(PageBitmapIndex * PAGE_SIZE));
return (void *)(PageBitmapIndex * PAGE_SIZE);
}
if (this->SwapPage((void *)(PageBitmapIndex * PAGE_SIZE)))
{
this->LockPage((void *)(PageBitmapIndex * PAGE_SIZE));
return (void *)(PageBitmapIndex * PAGE_SIZE);
}
if (TaskManager && !TaskManager->IsPanic())
{
error("Out of memory! Killing current process...");
TaskManager->KillProcess(TaskManager->GetCurrentProcess(), Tasking::KILL_OOM);
TaskManager->Schedule();
}
if (TaskManager && !TaskManager->IsPanic())
{
error("Out of memory! Killing current process...");
TaskManager->KillProcess(thisProcess, Tasking::KILL_OOM);
TaskManager->Yield();
}
error("Out of memory! (Free: %ldMB; Used: %ldMB; Reserved: %ldMB)", TO_MB(FreeMemory), TO_MB(UsedMemory), TO_MB(ReservedMemory));
CPU::Stop();
__builtin_unreachable();
}
error("Out of memory! (Free: %ld MiB; Used: %ld MiB; Reserved: %ld MiB)",
TO_MiB(FreeMemory), TO_MiB(UsedMemory), TO_MiB(ReservedMemory));
KPrint("Out of memory! (Free: %ld MiB; Used: %ld MiB; Reserved: %ld MiB)",
TO_MiB(FreeMemory), TO_MiB(UsedMemory), TO_MiB(ReservedMemory));
CPU::Stop();
__builtin_unreachable();
}
void *Physical::RequestPages(size_t Count)
{
SmartLock(this->MemoryLock);
void *Physical::RequestPages(size_t Count)
{
SmartLock(this->MemoryLock);
for (; PageBitmapIndex < PageBitmap.Size * 8; PageBitmapIndex++)
{
if (PageBitmap[PageBitmapIndex] == true)
continue;
for (; PageBitmapIndex < PageBitmap.Size * 8; PageBitmapIndex++)
{
if (PageBitmap[PageBitmapIndex] == true)
continue;
for (uint64_t Index = PageBitmapIndex; Index < PageBitmap.Size * 8; Index++)
{
if (PageBitmap[Index] == true)
continue;
for (uint64_t Index = PageBitmapIndex; Index < PageBitmap.Size * 8; Index++)
{
if (PageBitmap[Index] == true)
continue;
for (size_t i = 0; i < Count; i++)
{
if (PageBitmap[Index + i] == true)
goto NextPage;
}
for (size_t i = 0; i < Count; i++)
{
if (PageBitmap[Index + i] == true)
goto NextPage;
}
this->LockPages((void *)(Index * PAGE_SIZE), Count);
this->LockPages((void *)(Index * PAGE_SIZE), Count);
#ifdef DEBUG
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "RequestPages( %ld )=%p~%p\n\r",
Count,
(void *)(Index * PAGE_SIZE), __builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "RequestPages( %ld )=%p~%p\n\r",
Count,
(void *)(Index * PAGE_SIZE), __builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
#endif
return (void *)(Index * PAGE_SIZE);
return (void *)(Index * PAGE_SIZE);
NextPage:
Index += Count;
continue;
}
}
NextPage:
Index += Count;
continue;
}
}
if (this->SwapPages((void *)(PageBitmapIndex * PAGE_SIZE), Count))
{
this->LockPages((void *)(PageBitmapIndex * PAGE_SIZE), Count);
return (void *)(PageBitmapIndex * PAGE_SIZE);
}
if (this->SwapPages((void *)(PageBitmapIndex * PAGE_SIZE), Count))
{
this->LockPages((void *)(PageBitmapIndex * PAGE_SIZE), Count);
return (void *)(PageBitmapIndex * PAGE_SIZE);
}
if (TaskManager && !TaskManager->IsPanic())
{
error("Out of memory! Killing current process...");
TaskManager->KillProcess(TaskManager->GetCurrentProcess(), Tasking::KILL_OOM);
TaskManager->Schedule();
}
if (TaskManager && !TaskManager->IsPanic())
{
error("Out of memory! Killing current process...");
TaskManager->KillProcess(thisProcess, Tasking::KILL_OOM);
TaskManager->Yield();
}
error("Out of memory! (Free: %ldMB; Used: %ldMB; Reserved: %ldMB)", TO_MB(FreeMemory), TO_MB(UsedMemory), TO_MB(ReservedMemory));
CPU::Halt(true);
__builtin_unreachable();
}
error("Out of memory! (Free: %ld MiB; Used: %ld MiB; Reserved: %ld MiB)",
TO_MiB(FreeMemory), TO_MiB(UsedMemory), TO_MiB(ReservedMemory));
KPrint("Out of memory! (Free: %ld MiB; Used: %ld MiB; Reserved: %ld MiB)",
TO_MiB(FreeMemory), TO_MiB(UsedMemory), TO_MiB(ReservedMemory));
CPU::Halt(true);
__builtin_unreachable();
}
void Physical::FreePage(void *Address)
{
SmartLock(this->MemoryLock);
void Physical::FreePage(void *Address)
{
SmartLock(this->MemoryLock);
if (unlikely(Address == nullptr))
{
warn("Null pointer passed to FreePage.");
return;
}
if (unlikely(Address == nullptr))
{
warn("Null pointer passed to FreePage.");
return;
}
size_t Index = (size_t)Address / PAGE_SIZE;
size_t Index = (size_t)Address / PAGE_SIZE;
if (unlikely(PageBitmap[Index] == false))
{
warn("Tried to free an already free page. (%p)", Address);
return;
}
if (unlikely(PageBitmap[Index] == false))
{
warn("Tried to free an already free page. (%p)",
Address);
return;
}
if (PageBitmap.Set(Index, false))
{
FreeMemory += PAGE_SIZE;
UsedMemory -= PAGE_SIZE;
if (PageBitmapIndex > Index)
PageBitmapIndex = Index;
}
if (PageBitmap.Set(Index, false))
{
FreeMemory += PAGE_SIZE;
UsedMemory -= PAGE_SIZE;
if (PageBitmapIndex > Index)
PageBitmapIndex = Index;
}
#ifdef DEBUG
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "FreePage( %p )~%p\n\r",
Address,
__builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "FreePage( %p )~%p\n\r",
Address,
__builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
#endif
}
}
void Physical::FreePages(void *Address, size_t Count)
{
if (unlikely(Address == nullptr || Count == 0))
{
warn("%s%s%s passed to FreePages.", Address == nullptr ? "Null pointer " : "", Address == nullptr && Count == 0 ? "and " : "", Count == 0 ? "Zero count" : "");
return;
}
void Physical::FreePages(void *Address, size_t Count)
{
if (unlikely(Address == nullptr || Count == 0))
{
warn("%s%s%s passed to FreePages.", Address == nullptr ? "Null pointer " : "", Address == nullptr && Count == 0 ? "and " : "", Count == 0 ? "Zero count" : "");
return;
}
#ifdef DEBUG
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "!FreePages( %p %ld )~%p\n\r",
Address, Count,
__builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
if (EnableExternalMemoryTracer)
{
char LockTmpStr[64];
strcpy_unsafe(LockTmpStr, __FUNCTION__);
strcat_unsafe(LockTmpStr, "_memTrk");
mExtTrkLock.TimeoutLock(LockTmpStr, 10000);
sprintf(mExtTrkLog, "!FreePages( %p %ld )~%p\n\r",
Address, Count,
__builtin_return_address(0));
UniversalAsynchronousReceiverTransmitter::UART mTrkUART = UniversalAsynchronousReceiverTransmitter::UART(UniversalAsynchronousReceiverTransmitter::COM3);
for (short i = 0; i < MEM_TRK_MAX_SIZE; i++)
{
if (mExtTrkLog[i] == '\r')
break;
mTrkUART.Write(mExtTrkLog[i]);
}
mExtTrkLock.Unlock();
}
#endif
for (size_t t = 0; t < Count; t++)
this->FreePage((void *)((uintptr_t)Address + (t * PAGE_SIZE)));
}
for (size_t t = 0; t < Count; t++)
this->FreePage((void *)((uintptr_t)Address + (t * PAGE_SIZE)));
}
void Physical::LockPage(void *Address)
{
if (unlikely(Address == nullptr))
warn("Trying to lock null address.");
void Physical::LockPage(void *Address)
{
if (unlikely(Address == nullptr))
warn("Trying to lock null address.");
uintptr_t Index = (uintptr_t)Address / PAGE_SIZE;
uintptr_t Index = (uintptr_t)Address / PAGE_SIZE;
if (unlikely(PageBitmap[Index] == true))
return;
if (unlikely(PageBitmap[Index] == true))
return;
if (PageBitmap.Set(Index, true))
{
FreeMemory -= PAGE_SIZE;
UsedMemory += PAGE_SIZE;
}
}
if (PageBitmap.Set(Index, true))
{
FreeMemory -= PAGE_SIZE;
UsedMemory += PAGE_SIZE;
}
}
void Physical::LockPages(void *Address, size_t PageCount)
{
if (unlikely(Address == nullptr || PageCount == 0))
warn("Trying to lock %s%s.", Address ? "null address" : "", PageCount ? "0 pages" : "");
void Physical::LockPages(void *Address, size_t PageCount)
{
if (unlikely(Address == nullptr || PageCount == 0))
warn("Trying to lock %s%s.",
Address ? "null address" : "",
PageCount ? "0 pages" : "");
for (size_t i = 0; i < PageCount; i++)
this->LockPage((void *)((uintptr_t)Address + (i * PAGE_SIZE)));
}
for (size_t i = 0; i < PageCount; i++)
this->LockPage((void *)((uintptr_t)Address + (i * PAGE_SIZE)));
}
void Physical::ReservePage(void *Address)
{
if (unlikely(Address == nullptr))
warn("Trying to reserve null address.");
void Physical::ReservePage(void *Address)
{
if (unlikely(Address == nullptr))
warn("Trying to reserve null address.");
uintptr_t Index = (Address == NULL) ? 0 : (uintptr_t)Address / PAGE_SIZE;
uintptr_t Index = (Address == NULL) ? 0 : (uintptr_t)Address / PAGE_SIZE;
if (unlikely(PageBitmap[Index] == true))
return;
if (unlikely(PageBitmap[Index] == true))
return;
if (PageBitmap.Set(Index, true))
{
FreeMemory -= PAGE_SIZE;
ReservedMemory += PAGE_SIZE;
}
}
if (PageBitmap.Set(Index, true))
{
FreeMemory -= PAGE_SIZE;
ReservedMemory += PAGE_SIZE;
}
}
void Physical::ReservePages(void *Address, size_t PageCount)
{
if (unlikely(Address == nullptr || PageCount == 0))
warn("Trying to reserve %s%s.", Address ? "null address" : "", PageCount ? "0 pages" : "");
void Physical::ReservePages(void *Address, size_t PageCount)
{
if (unlikely(Address == nullptr || PageCount == 0))
warn("Trying to reserve %s%s.",
Address ? "null address" : "",
PageCount ? "0 pages" : "");
for (size_t t = 0; t < PageCount; t++)
{
uintptr_t Index = ((uintptr_t)Address + (t * PAGE_SIZE)) / PAGE_SIZE;
for (size_t t = 0; t < PageCount; t++)
{
uintptr_t Index = ((uintptr_t)Address + (t * PAGE_SIZE)) / PAGE_SIZE;
if (unlikely(PageBitmap[Index] == true))
return;
if (unlikely(PageBitmap[Index] == true))
return;
if (PageBitmap.Set(Index, true))
{
FreeMemory -= PAGE_SIZE;
ReservedMemory += PAGE_SIZE;
}
}
}
if (PageBitmap.Set(Index, true))
{
FreeMemory -= PAGE_SIZE;
ReservedMemory += PAGE_SIZE;
}
}
}
void Physical::UnreservePage(void *Address)
{
if (unlikely(Address == nullptr))
warn("Trying to unreserve null address.");
void Physical::UnreservePage(void *Address)
{
if (unlikely(Address == nullptr))
warn("Trying to unreserve null address.");
uintptr_t Index = (Address == NULL) ? 0 : (uintptr_t)Address / PAGE_SIZE;
uintptr_t Index = (Address == NULL) ? 0 : (uintptr_t)Address / PAGE_SIZE;
if (unlikely(PageBitmap[Index] == false))
return;
if (unlikely(PageBitmap[Index] == false))
return;
if (PageBitmap.Set(Index, false))
{
FreeMemory += PAGE_SIZE;
ReservedMemory -= PAGE_SIZE;
if (PageBitmapIndex > Index)
PageBitmapIndex = Index;
}
}
if (PageBitmap.Set(Index, false))
{
FreeMemory += PAGE_SIZE;
ReservedMemory -= PAGE_SIZE;
if (PageBitmapIndex > Index)
PageBitmapIndex = Index;
}
}
void Physical::UnreservePages(void *Address, size_t PageCount)
{
if (unlikely(Address == nullptr || PageCount == 0))
warn("Trying to unreserve %s%s.", Address ? "null address" : "", PageCount ? "0 pages" : "");
void Physical::UnreservePages(void *Address, size_t PageCount)
{
if (unlikely(Address == nullptr || PageCount == 0))
warn("Trying to unreserve %s%s.",
Address ? "null address" : "",
PageCount ? "0 pages" : "");
for (size_t t = 0; t < PageCount; t++)
{
uintptr_t Index = ((uintptr_t)Address + (t * PAGE_SIZE)) / PAGE_SIZE;
for (size_t t = 0; t < PageCount; t++)
{
uintptr_t Index = ((uintptr_t)Address + (t * PAGE_SIZE)) / PAGE_SIZE;
if (unlikely(PageBitmap[Index] == false))
return;
if (unlikely(PageBitmap[Index] == false))
return;
if (PageBitmap.Set(Index, false))
{
FreeMemory += PAGE_SIZE;
ReservedMemory -= PAGE_SIZE;
if (PageBitmapIndex > Index)
PageBitmapIndex = Index;
}
}
}
if (PageBitmap.Set(Index, false))
{
FreeMemory += PAGE_SIZE;
ReservedMemory -= PAGE_SIZE;
if (PageBitmapIndex > Index)
PageBitmapIndex = Index;
}
}
}
void Physical::Init()
{
SmartLock(this->MemoryLock);
void Physical::Init()
{
SmartLock(this->MemoryLock);
uint64_t MemorySize = bInfo.Memory.Size;
debug("Memory size: %lld bytes (%ld pages)", MemorySize, TO_PAGES(MemorySize));
TotalMemory = MemorySize;
FreeMemory = MemorySize;
uint64_t MemorySize = bInfo.Memory.Size;
debug("Memory size: %lld bytes (%ld pages)",
MemorySize, TO_PAGES(MemorySize));
TotalMemory = MemorySize;
FreeMemory = MemorySize;
size_t BitmapSize = (size_t)(MemorySize / PAGE_SIZE) / 8 + 1;
uintptr_t BitmapAddress = 0x0;
size_t BitmapAddressSize = 0;
size_t BitmapSize = (size_t)(MemorySize / PAGE_SIZE) / 8 + 1;
uintptr_t BitmapAddress = 0x0;
size_t BitmapAddressSize = 0;
uintptr_t KernelStart = (uintptr_t)bInfo.Kernel.PhysicalBase;
uintptr_t KernelEnd = (uintptr_t)bInfo.Kernel.PhysicalBase + bInfo.Kernel.Size;
uintptr_t KernelStart = (uintptr_t)bInfo.Kernel.PhysicalBase;
uintptr_t KernelEnd = (uintptr_t)bInfo.Kernel.PhysicalBase + bInfo.Kernel.Size;
for (uint64_t i = 0; i < bInfo.Memory.Entries; i++)
{
if (bInfo.Memory.Entry[i].Type == Usable)
{
uintptr_t RegionAddress = (uintptr_t)bInfo.Memory.Entry[i].BaseAddress;
uintptr_t RegionSize = bInfo.Memory.Entry[i].Length;
for (uint64_t i = 0; i < bInfo.Memory.Entries; i++)
{
if (bInfo.Memory.Entry[i].Type == Usable)
{
uintptr_t RegionAddress = (uintptr_t)bInfo.Memory.Entry[i].BaseAddress;
uintptr_t RegionSize = bInfo.Memory.Entry[i].Length;
/* We don't want to use 0 as a memory address. */
if (RegionAddress == 0x0)
continue;
/* We don't want to use the first 1MB of memory. */
if (RegionAddress <= 0xFFFFF)
continue;
if ((BitmapSize + 0x100) > RegionSize)
{
debug("Region %p-%p (%dMB) is too small for bitmap.",
(void *)RegionAddress,
(void *)(RegionAddress + RegionSize),
TO_MB(RegionSize));
continue;
}
if ((BitmapSize + 0x100) > RegionSize)
{
debug("Region %p-%p (%d MiB) is too small for bitmap.",
(void *)RegionAddress,
(void *)(RegionAddress + RegionSize),
TO_MiB(RegionSize));
continue;
}
BitmapAddress = RegionAddress;
BitmapAddressSize = RegionSize;
BitmapAddress = RegionAddress;
BitmapAddressSize = RegionSize;
if (RegionAddress >= KernelStart && KernelEnd <= (RegionAddress + RegionSize))
{
BitmapAddress = KernelEnd;
BitmapAddressSize = RegionSize - (KernelEnd - RegionAddress);
}
if (RegionAddress >= KernelStart && KernelEnd <= (RegionAddress + RegionSize))
{
BitmapAddress = KernelEnd;
BitmapAddressSize = RegionSize - (KernelEnd - RegionAddress);
}
if ((BitmapSize + 0x100) > BitmapAddressSize)
{
debug("Region %p-%p (%dMB) is too small for bitmap.",
(void *)RegionAddress,
(void *)(RegionAddress + BitmapAddressSize),
TO_MB(BitmapAddressSize));
continue;
}
if ((BitmapSize + 0x100) > BitmapAddressSize)
{
debug("Region %p-%p (%d MiB) is too small for bitmap.",
(void *)RegionAddress,
(void *)(RegionAddress + BitmapAddressSize),
TO_MiB(BitmapAddressSize));
continue;
}
for (size_t i = 0; i < MAX_MODULES; i++)
{
uintptr_t ModuleStart = (uintptr_t)bInfo.Modules[i].Address;
uintptr_t ModuleEnd = (uintptr_t)bInfo.Modules[i].Address + bInfo.Modules[i].Size;
for (size_t i = 0; i < MAX_MODULES; i++)
{
uintptr_t ModuleStart = (uintptr_t)bInfo.Modules[i].Address;
uintptr_t ModuleEnd = (uintptr_t)bInfo.Modules[i].Address + bInfo.Modules[i].Size;
if (ModuleStart == 0x0)
break;
if (ModuleStart == 0x0)
break;
if (RegionAddress >= ModuleStart && ModuleEnd <= (RegionAddress + RegionSize))
{
BitmapAddress = ModuleEnd;
BitmapAddressSize = RegionSize - (ModuleEnd - RegionAddress);
}
}
if (RegionAddress >= ModuleStart && ModuleEnd <= (RegionAddress + RegionSize))
{
BitmapAddress = ModuleEnd;
BitmapAddressSize = RegionSize - (ModuleEnd - RegionAddress);
}
}
if ((BitmapSize + 0x100) > BitmapAddressSize)
{
debug("Region %p-%p (%dMB) is too small for bitmap.",
(void *)BitmapAddress,
(void *)(BitmapAddress + BitmapAddressSize),
TO_MB(BitmapAddressSize));
continue;
}
if ((BitmapSize + 0x100) > BitmapAddressSize)
{
debug("Region %p-%p (%d MiB) is too small for bitmap.",
(void *)BitmapAddress,
(void *)(BitmapAddress + BitmapAddressSize),
TO_MiB(BitmapAddressSize));
continue;
}
debug("Found free memory for bitmap: %p (%dMB)",
(void *)BitmapAddress,
TO_MB(BitmapAddressSize));
break;
}
}
debug("Found free memory for bitmap: %p (%d MiB)",
(void *)BitmapAddress,
TO_MiB(BitmapAddressSize));
break;
}
}
if (BitmapAddress == 0x0)
{
error("No free memory found!");
CPU::Stop();
}
if (BitmapAddress == 0x0)
{
error("No free memory found!");
CPU::Stop();
}
/* TODO: Read swap config and make the configure the bitmap size correctly */
debug("Initializing Bitmap at %p-%p (%d Bytes)",
BitmapAddress,
(void *)(BitmapAddress + BitmapSize),
BitmapSize);
/* TODO: Read swap config and make the configure the bitmap size correctly */
debug("Initializing Bitmap at %p-%p (%d Bytes)",
BitmapAddress,
(void *)(BitmapAddress + BitmapSize),
BitmapSize);
PageBitmap.Size = BitmapSize;
PageBitmap.Buffer = (uint8_t *)BitmapAddress;
for (size_t i = 0; i < BitmapSize; i++)
*(uint8_t *)(PageBitmap.Buffer + i) = 0;
PageBitmap.Size = BitmapSize;
PageBitmap.Buffer = (uint8_t *)BitmapAddress;
for (size_t i = 0; i < BitmapSize; i++)
*(uint8_t *)(PageBitmap.Buffer + i) = 0;
ReserveEssentials();
}
ReserveEssentials();
}
Physical::Physical() {}
Physical::~Physical() {}
Physical::Physical() {}
Physical::~Physical() {}
}