// === CONSTANTS ===
#define PHYS_BITS 52 // TODO: Move out
+#define VIRT_BITS 48
#define PML4_SHIFT 39
#define PDP_SHIFT 30
#define PTAB_SHIFT 12
#define PADDR_MASK 0x7FFFFFFF##FFFFF000
-#define PAGE_MASK (((Uint)1 << 36)-1)
-#define TABLE_MASK (((Uint)1 << 27)-1)
-#define PDP_MASK (((Uint)1 << 18)-1)
-#define PML4_MASK (((Uint)1 << 9)-1)
+#define PAGE_MASK ((1LL << 36)-1)
+#define TABLE_MASK ((1LL << 27)-1)
+#define PDP_MASK ((1LL << 18)-1)
+#define PML4_MASK ((1LL << 9)-1)
#define PF_PRESENT 0x001
#define PF_WRITE 0x002
#define PF_USER 0x004
-#define PF_LARGE 0x000
+#define PF_LARGE 0x080
+#define PF_GLOBAL 0x100
#define PF_COW 0x200
#define PF_PAGED 0x400
#define PF_NX 0x80000000##00000000
// === IMPORTS ===
extern void Error_Backtrace(Uint IP, Uint BP);
extern tPAddr gInitialPML4[512];
+extern void Threads_SegFault(tVAddr Addr);
// === PROTOTYPES ===
void MM_InitVirt(void);
// === CODE ===
void MM_InitVirt(void)
{
- MM_DumpTables(0, -1L);
+// MM_DumpTables(0, -1L);
}
void MM_FinishVirtualInit(void)
void MM_PageFault(tVAddr Addr, Uint ErrorCode, tRegs *Regs)
{
// TODO: Implement Copy-on-Write
- #if 0
- if( gaPageDir [Addr>>22] & PF_PRESENT
- && gaPageTable[Addr>>12] & PF_PRESENT
- && gaPageTable[Addr>>12] & PF_COW )
+ #if 1
+ if( PAGEMAPLVL4(Addr>>39) & PF_PRESENT
+ && PAGEDIRPTR (Addr>>30) & PF_PRESENT
+ && PAGEDIR (Addr>>21) & PF_PRESENT
+ && PAGETABLE (Addr>>12) & PF_PRESENT
+ && PAGETABLE (Addr>>12) & PF_COW )
{
tPAddr paddr;
- if(MM_GetRefCount( gaPageTable[Addr>>12] & PADDR_MASK ) == 1)
+ if(MM_GetRefCount( PAGETABLE(Addr>>12) & PADDR_MASK ) == 1)
{
- gaPageTable[Addr>>12] &= ~PF_COW;
- gaPageTable[Addr>>12] |= PF_PRESENT|PF_WRITE;
+ PAGETABLE(Addr>>12) &= ~PF_COW;
+ PAGETABLE(Addr>>12) |= PF_PRESENT|PF_WRITE;
}
else
{
//Log("MM_PageFault: COW - MM_DuplicatePage(0x%x)", Addr);
- paddr = MM_DuplicatePage( Addr );
- MM_DerefPhys( gaPageTable[Addr>>12] & PADDR_MASK );
- gaPageTable[Addr>>12] &= PF_USER;
- gaPageTable[Addr>>12] |= paddr|PF_PRESENT|PF_WRITE;
+ paddr = MM_AllocPhys();
+ if( !paddr ) {
+ Threads_SegFault(Addr);
+ return ;
+ }
+ {
+ void *tmp = (void*)MM_MapTemp(paddr);
+ memcpy( tmp, (void*)(Addr & ~0xFFF), 0x1000 );
+ MM_FreeTemp( (tVAddr)tmp );
+ }
+ MM_DerefPhys( PAGETABLE(Addr>>12) & PADDR_MASK );
+ PAGETABLE(Addr>>12) &= PF_USER;
+ PAGETABLE(Addr>>12) |= paddr|PF_PRESENT|PF_WRITE;
}
INVLPG( Addr & ~0xFFF );
// If it was a user, tell the thread handler
if(ErrorCode & 4) {
- Warning("%s %s %s memory%s",
- (ErrorCode&4?"User":"Kernel"),
+ Warning("User %s %s memory%s",
(ErrorCode&2?"write to":"read from"),
(ErrorCode&1?"bad/locked":"non-present"),
(ErrorCode&16?" (Instruction Fetch)":"")
);
- Warning("User Pagefault: Instruction at %04x:%08x accessed %p",
+ Warning("User Pagefault: Instruction at %04x:%p accessed %p",
Regs->CS, Regs->RIP, Addr);
__asm__ __volatile__ ("sti"); // Restart IRQs
-// Threads_SegFault(Addr);
+ Threads_SegFault(Addr);
return ;
}
Warning("Reserved Bits Trashed!");
else
{
- Warning("%s %s %s memory%s",
- (ErrorCode&4?"User":"Kernel"),
+ Warning("Kernel %s %s memory%s",
(ErrorCode&2?"write to":"read from"),
(ErrorCode&1?"bad/locked":"non-present"),
(ErrorCode&16?" (Instruction Fetch)":"")
|| !(PAGETABLE(page) & PF_PRESENT)
|| (PAGETABLE(page) & MASK) != expected)
{
- if(expected != CHANGEABLE_BITS) {
- Log("%016llx => %013llx : 0x%6llx (%c%c%c%c)",
+ if(expected != CHANGEABLE_BITS)
+ {
+ Log("%016llx => %13llx : 0x%6llx (%c%c%c%c)",
CANOICAL(rangeStart),
PAGETABLE(rangeStart>>12) & PADDR_MASK,
curPos - rangeStart,
}
if(expected != CHANGEABLE_BITS) {
- Log("%016llx => %013llx : 0x%6llx (%c%c%c%c)",
+ Log("%016llx => %13llx : 0x%6llx (%c%c%c%c)",
CANOICAL(rangeStart),
PAGETABLE(rangeStart>>12) & PADDR_MASK,
curPos - rangeStart,
const int nADDR_SIZES = sizeof(ADDR_SIZES)/sizeof(ADDR_SIZES[0]);
int i;
+ #define BITMASK(bits) ( (1LL << (bits))-1 )
+
if( bTemp )
{
pmlevels[3] = &TMPTABLE(0); // Page Table
else
{
pmlevels[3] = (void*)MM_FRACTAL_BASE; // Page Table
- pmlevels[2] = &pmlevels[3][(MM_FRACTAL_BASE>>12)&PAGE_MASK]; // PDIR
- pmlevels[1] = &pmlevels[2][(MM_FRACTAL_BASE>>21)&TABLE_MASK]; // PDPT
- pmlevels[0] = &pmlevels[1][(MM_FRACTAL_BASE>>30)&PDP_MASK]; // PML4
+ pmlevels[2] = &pmlevels[3][(MM_FRACTAL_BASE>>12)&BITMASK(VIRT_BITS-12)]; // PDIR
+ pmlevels[1] = &pmlevels[2][(MM_FRACTAL_BASE>>21)&BITMASK(VIRT_BITS-21)]; // PDPT
+ pmlevels[0] = &pmlevels[1][(MM_FRACTAL_BASE>>30)&BITMASK(VIRT_BITS-30)]; // PML4
}
// Mask address
if( !(pmlevels[i][Addr >> ADDR_SIZES[i]] & 1) )
{
if( !bAllocate ) return -4; // If allocation is not requested, error
- tmp = MM_AllocPhys();
- if(!tmp) return -2;
+ if( !(tmp = MM_AllocPhys()) ) return -2;
pmlevels[i][Addr >> ADDR_SIZES[i]] = tmp | 3;
+ if( Addr < 0x800000000000 )
+ pmlevels[i][Addr >> ADDR_SIZES[i]] |= PF_USER;
INVLPG( &pmlevels[i+1][ (Addr>>ADDR_SIZES[i])*512 ] );
memset( &pmlevels[i+1][ (Addr>>ADDR_SIZES[i])*512 ], 0, 0x1000 );
+ LOG("Init PML%i ent 0x%x %p with %P", 4 - i,
+ Addr>>ADDR_SIZES[i],
+ (Addr>>ADDR_SIZES[i])<<ADDR_SIZES[i], tmp);
}
// Catch large pages
else if( pmlevels[i][Addr >> ADDR_SIZES[i]] & PF_LARGE )
if( *ent & 1 ) LEAVE_RET('i', 0);
*ent = PAddr | 3;
-
+
+ if( VAddr < 0x800000000000 )
+ *ent |= PF_USER;
+
INVLPG( VAddr );
LEAVE('i', 1);
int i;
tVAddr kstackbase;
- // tThread->KernelStack is the top
- // There is 1 guard page below the stack
- kstackbase = Proc_GetCurThread()->KernelStack - KERNEL_STACK_SIZE + 0x1000;
-
- Log("MM_Clone: kstackbase = %p", kstackbase);
-
// #1 Create a copy of the PML4
ret = MM_AllocPhys();
if(!ret) return 0;
// 320 0xFFFFA.... - Kernel Stacks
if( i == 320 ) continue;
// 509 0xFFFFFE0.. - Fractal mapping
- if( i == 509 ) continue;
+ if( i == 508 ) continue;
// 510 0xFFFFFE8.. - Temp fractal mapping
- if( i == 510 ) continue;
+ if( i == 509 ) continue;
TMPMAPLVL4(i) = PAGEMAPLVL4(i);
if( TMPMAPLVL4(i) & 1 )
}
// #5 Set fractal mapping
- TMPMAPLVL4(509) = ret | 3;
- TMPMAPLVL4(510) = 0; // Temp
+ TMPMAPLVL4(508) = ret | 3;
+ TMPMAPLVL4(509) = 0; // Temp
- // #6 Create kernel stack (-1 to account for the guard)
- TMPMAPLVL4(320) = 0;
- for( i = 0; i < KERNEL_STACK_SIZE/0x1000-1; i ++ )
+ // #6 Create kernel stack
+ // tThread->KernelStack is the top
+ // There is 1 guard page below the stack
+ kstackbase = Proc_GetCurThread()->KernelStack - KERNEL_STACK_SIZE;
+
+// Log("MM_Clone: kstackbase = %p", kstackbase);
+
+ TMPMAPLVL4(MM_KSTACK_BASE >> PML4_SHIFT) = 0;
+ for( i = 1; i < KERNEL_STACK_SIZE/0x1000; i ++ )
{
tPAddr phys = MM_AllocPhys();
tVAddr tmpmapping;
MM_MapEx(kstackbase+i*0x1000, phys, 1, 0);
+ Log_Debug("MM", "MM_Clone: Cloning stack page %p from %P to %P",
+ kstackbase+i*0x1000, MM_GetPhysAddr( kstackbase+i*0x1000 ), phys
+ );
tmpmapping = MM_MapTemp(phys);
- memcpy((void*)tmpmapping, (void*)(kstackbase+i*0x1000), 0x1000);
+ if( MM_GetPhysAddr( kstackbase+i*0x1000 ) )
+ memcpy((void*)tmpmapping, (void*)(kstackbase+i*0x1000), 0x1000);
+ else
+ memset((void*)tmpmapping, 0, 0x1000);
+// if( i == 0xF )
+// Debug_HexDump("MM_Clone: *tmpmapping = ", (void*)tmpmapping, 0x1000);
MM_FreeTemp(tmpmapping);
}
+// MAGIC_BREAK();
+
// #7 Return
TMPCR3() = 0;
INVLPG_ALL();
Mutex_Release(&glMM_TempFractalLock);
- Log("MM_Clone: RETURN %P\n", ret);
+// Log("MM_Clone: RETURN %P", ret);
return ret;
}
}
}
-tVAddr MM_NewWorkerStack(void)
+tVAddr MM_NewWorkerStack(void *StackData, size_t StackSize)
{
tVAddr ret;
int i;
// #2 Scan for a free stack addresss < 2^47
for(ret = 0x100000; ret < (1ULL << 47); ret += KERNEL_STACK_SIZE)
{
- if( MM_GetPhysAddr(ret) == 0 ) break;
+ tPAddr *ptr;
+ if( MM_GetPageEntryPtr(ret, 1, 0, 0, &ptr) == 0 ) break;
+ if( !(*ptr & 1) ) break;
}
if( ret >= (1ULL << 47) ) {
Mutex_Release(&glMM_TempFractalLock);
}
MM_MapEx(ret + i*0x1000, phys, 1, 0);
}
+
+ if( StackSize > 0x1000 ) {
+ Log_Error("MM", "MM_NewWorkerStack: StackSize(0x%x) > 0x1000, cbf handling", StackSize);
+ }
+ else {
+ tPAddr *ptr, paddr;
+ tVAddr tmp_addr;
+ MM_GetPageEntryPtr(ret + i*0x1000, 1, 0, 0, &ptr);
+ paddr = *ptr & ~0xFFF;
+ tmp_addr = MM_MapTemp(paddr);
+ memcpy( (void*)(tmp_addr + (0x1000 - StackSize)), StackData, StackSize );
+ MM_FreeTemp(tmp_addr);
+ }
Mutex_Release(&glMM_TempFractalLock);
Uint i;
for( ; base < MM_KSTACK_TOP; base += KERNEL_STACK_SIZE )
{
- if(MM_GetPhysAddr(base) != 0)
+ if(MM_GetPhysAddr(base+KERNEL_STACK_SIZE-0x1000) != 0)
continue;
//Log("MM_NewKStack: Found one at %p", base + KERNEL_STACK_SIZE);
- for( i = 0; i < KERNEL_STACK_SIZE; i += 0x1000)
+ for( i = 0x1000; i < KERNEL_STACK_SIZE; i += 0x1000)
{
if( !MM_Allocate(base+i) )
{