#include <mm_virt.h>
#include <hal_proc.h>
-#define AP_KRW_ONLY 0x1
-#define AP_KRO_ONLY 0x5
-#define AP_RW_BOTH 0x3
-#define AP_RO_BOTH 0x6
+#define TRACE_MAPS 0
+
+#define AP_KRW_ONLY 1 // Kernel page
+#define AP_KRO_ONLY 5 // Kernel RO page
+#define AP_RW_BOTH 3 // Standard RW
+#define AP_RO_BOTH 6 // COW Page
+#define AP_RO_USER 2 // User RO Page
#define PADDR_MASK_LVL1 0xFFFFFC00
// === IMPORTS ===
//#define FRACTAL(table1, addr) ((table1)[ (0xFF8/4*1024) + ((addr)>>20)])
#define FRACTAL(table1, addr) ((table1)[ (0xFF8/4*1024) + ((addr)>>22)])
-#define USRFRACTAL(table1, addr) ((table1)[ (0x7F8/4*1024) + ((addr)>>22)])
+#define USRFRACTAL(addr) (*((Uint32*)(0x7FDFF000) + ((addr)>>22)))
#define TLBIALL() __asm__ __volatile__ ("mcr p15, 0, %0, c8, c7, 0" : : "r" (0))
#define TLBIMVA(addr) __asm__ __volatile__ ("mcr p15, 0, %0, c8, c7, 1" : : "r" (addr))
int MM_int_AllocateCoarse(tVAddr VAddr, int Domain);
int MM_int_SetPageInfo(tVAddr VAddr, tMM_PageInfo *pi);
int MM_int_GetPageInfo(tVAddr VAddr, tMM_PageInfo *pi);
+tVAddr MM_NewUserStack(void);
+tPAddr MM_AllocateZero(tVAddr VAddr);
tPAddr MM_AllocateRootTable(void);
void MM_int_CloneTable(Uint32 *DestEnt, int Table);
tPAddr MM_Clone(void);
//void MM_DumpTables(tVAddr Start, tVAddr End);
// === GLOBALS ===
+tPAddr giMM_ZeroPage;
// === CODE ===
int MM_InitialiseVirtual(void)
desc[2] = desc[0] + 0x800;
desc[3] = desc[0] + 0xC00;
- FRACTAL(table1, VAddr) = paddr | 3;
+ if( VAddr < 0x80000000 ) {
+// Log("USRFRACTAL(%p) = %p", VAddr, &USRFRACTAL(VAddr));
+ USRFRACTAL(VAddr) = paddr | 3;
+ }
+ else {
+// Log("FRACTAL(%p) = %p", VAddr, &FRACTAL(table1, VAddr));
+ FRACTAL(table1, VAddr) = paddr | 3;
+ }
// TLBIALL
TLBIALL();
switch(pi.AP)
{
+ case 0:
+ break;
case AP_KRW_ONLY:
ret |= MM_PFLAG_KERNEL;
break;
case AP_RW_BOTH:
break;
case AP_RO_BOTH:
+ ret |= MM_PFLAG_COW;
+ break;
+ case AP_RO_USER:
ret |= MM_PFLAG_RO;
break;
}
void MM_SetFlags(tVAddr VAddr, Uint Flags, Uint Mask)
{
tMM_PageInfo pi;
+ Uint curFlags;
+
if( MM_int_GetPageInfo(VAddr, &pi) )
- return;
+ return ;
+
+ curFlags = MM_GetPhysAddr(VAddr);
+ if( (curFlags & Mask) == Flags )
+ return ;
+ curFlags &= ~Mask;
+ curFlags |= Flags;
+
+ if( curFlags & MM_PFLAG_COW )
+ pi.AP = AP_RO_BOTH;
+ else
+ {
+ switch(curFlags & (MM_PFLAG_KERNEL|MM_PFLAG_RO) )
+ {
+ case 0:
+ pi.AP = AP_RW_BOTH; break;
+ case MM_PFLAG_KERNEL:
+ pi.AP = AP_KRW_ONLY; break;
+ case MM_PFLAG_RO:
+ pi.AP = AP_RO_USER; break;
+ case MM_PFLAG_KERNEL|MM_PFLAG_RO:
+ pi.AP = AP_KRO_ONLY; break;
+ }
+ }
+
+ pi.bExecutable = !!(curFlags & MM_PFLAG_EXEC);
+
+ MM_int_SetPageInfo(VAddr, &pi);
}
int MM_Map(tVAddr VAddr, tPAddr PAddr)
{
tMM_PageInfo pi = {0};
-// Log("MM_Map %P=>%p", PAddr, VAddr);
+ #if TRACE_MAPS
+ Log("MM_Map %P=>%p", PAddr, VAddr);
+ #endif
pi.PhysAddr = PAddr;
pi.Size = 12;
- pi.AP = AP_KRW_ONLY; // Kernel Read/Write
+ if(VAddr < USER_STACK_TOP)
+ pi.AP = AP_RW_BOTH;
+ else
+ pi.AP = AP_KRW_ONLY; // Kernel Read/Write
pi.bExecutable = 1;
if( MM_int_SetPageInfo(VAddr, &pi) ) {
MM_DerefPhys(pi.PhysAddr);
pi.PhysAddr = MM_AllocPhys();
if( pi.PhysAddr == 0 ) LEAVE_RET('i', 0);
pi.Size = 12;
- pi.AP = AP_KRW_ONLY; // Kernel Read/Write
+ if(VAddr < USER_STACK_TOP)
+ pi.AP = AP_RW_BOTH;
+ else
+ pi.AP = AP_KRW_ONLY;
pi.bExecutable = 1;
if( MM_int_SetPageInfo(VAddr, &pi) ) {
MM_DerefPhys(pi.PhysAddr);
return pi.PhysAddr;
}
+tPAddr MM_AllocateZero(tVAddr VAddr)
+{
+ if( !giMM_ZeroPage ) {
+ giMM_ZeroPage = MM_Allocate(VAddr);
+ MM_RefPhys(giMM_ZeroPage);
+ memset((void*)VAddr, 0, PAGE_SIZE);
+ }
+ else {
+ MM_RefPhys(giMM_ZeroPage);
+ MM_Map(VAddr, giMM_ZeroPage);
+ }
+ MM_SetFlags(VAddr, MM_PFLAG_COW, MM_PFLAG_COW);
+ return giMM_ZeroPage;
+}
+
void MM_Deallocate(tVAddr VAddr)
{
tMM_PageInfo pi;
{
tPAddr table;
Uint32 *tmp_map;
- Uint32 *cur = (void*)MM_TABLE0USER;
+ Uint32 *cur = (void*)MM_TABLE1USER;
// Uint32 *cur = &FRACTAL(MM_TABLE1USER,0);
int i;
for( i = 0; i < 1024; i ++ )
{
- switch(cur[i] & 3)
+// Log_Debug("MMVirt", "cur[%i] (%p) = %x", Table*256+i, &cur[Table*256+i], cur[Table*256+i]);
+ switch(cur[Table*256+i] & 3)
{
case 0: tmp_map[i] = 0; break;
case 1:
tmp_map[i] = 0;
- Log_Error("MMVirt", "TODO: Support large pages in MM_int_CloneTable");
+ Log_Error("MMVirt", "TODO: Support large pages in MM_int_CloneTable (%p)", (Table*256+i)*0x1000);
// Large page?
break;
case 2:
Uint32 *new_lvl1_1, *new_lvl1_2, *cur;
Uint32 *tmp_map;
int i;
+
+// MM_DumpTables(0, KERNEL_BASE);
ret = MM_AllocateRootTable();
new_lvl1_1 = (void*)MM_MapTemp(ret);
new_lvl1_2 = (void*)MM_MapTemp(ret+0x1000);
tmp_map = new_lvl1_1;
- new_lvl1_1[0] = 0x8202; // Section mapping the first meg for exception vectors (K-RO)
- for( i = 1; i < 0x800-4; i ++ )
+ for( i = 0; i < 0x800-4; i ++ )
{
-// Log("i = %i", i);
+ // HACK! Ignore the original identity mapping
+ if( i == 0 && Threads_GetTID() == 0 ) {
+ tmp_map[0] = 0;
+ continue;
+ }
if( i == 0x400 )
tmp_map = &new_lvl1_2[-0x400];
switch( cur[i] & 3 )
Uint32 *table = (void*)MM_MapTemp(tmp);
Uint32 sp;
register Uint32 __SP asm("sp");
- Log("new_lvl1_2 = %p, &new_lvl1_2[0x3FC] = %p", new_lvl1_2, &new_lvl1_2[0x3FC]);
+
// Map table to last 4MiB of user space
new_lvl1_2[0x3FC] = tmp + 0*0x400 + 1;
new_lvl1_2[0x3FD] = tmp + 1*0x400 + 1;
// Fractal
table[j++] = (ret + 0x0000) | 0x813;
table[j++] = (ret + 0x1000) | 0x813;
- Log("table[%i] = %x, table[%i] = %x", j-2, table[j-2], j-1, table[j-1]);
+ // Nuke the rest
for( ; j < 1024; j ++ )
table[j] = 0;
sp = __SP & ~(MM_KSTACK_SIZE-1);
j = (sp / 0x1000) % 1024;
num = MM_KSTACK_SIZE/0x1000;
- Log("sp = %p, j = %i", sp, j);
+
+ Log("num = %i, sp = %p, j = %i", num, sp, j);
// Copy stack pages
for(; num--; j ++, sp += 0x1000)
MM_FreeTemp( (tVAddr) tmp_page );
}
-// Debug_HexDump("MMVirt - last table", table, 0x1000);
-
MM_FreeTemp( (tVAddr)table );
}
-// Debug_HexDump("MMVirt - Return page 1", new_lvl1_1, 0x1000);
-// Debug_HexDump("MMVirt - Return page 2", new_lvl1_2, 0x1000);
-
MM_FreeTemp( (tVAddr)new_lvl1_1 );
MM_FreeTemp( (tVAddr)new_lvl1_2 );
-// Log("Table dump");
-// MM_DumpTables(0, -1);
-
return ret;
}
if( MM_int_GetPageInfo(ret, &pi) == 0 )
continue;
-// Log("MapTemp %P at %p", PAddr, ret);
+ Log("MapTemp %P at %p by %p", PAddr, ret, __builtin_return_address(0));
MM_RefPhys(PAddr); // Counter the MM_Deallocate in FreeTemp
MM_Map(ret, PAddr);
// Map the pages
for( i = 0; i < NPages; i ++ )
- MM_Map(ret+i*PAGE_SIZE, PAddr+i*PAddr);
+ MM_Map(ret+i*PAGE_SIZE, PAddr+i*PAGE_SIZE);
// and return
LEAVE('p', ret);
return ret;
tVAddr MM_AllocDMA(int Pages, int MaxBits, tPAddr *PAddr)
{
- Log_Error("MMVirt", "TODO: Implement MM_AllocDMA");
- return 0;
+ tPAddr phys;
+ tVAddr ret;
+
+ phys = MM_AllocPhysRange(Pages, MaxBits);
+ if(!phys) {
+ Log_Warning("MMVirt", "No space left for a %i page block (MM_AllocDMA)", Pages);
+ return 0;
+ }
+
+ ret = MM_MapHWPages(phys, Pages);
+ *PAddr = phys;
+
+ return ret;
}
void MM_UnmapHWPages(tVAddr Vaddr, Uint Number)
return addr + ofs;
}
+tVAddr MM_NewUserStack(void)
+{
+ tVAddr addr, ofs;
+
+ addr = USER_STACK_TOP - USER_STACK_SIZE;
+ if( MM_GetPhysAddr(addr + PAGE_SIZE) ) {
+ Log_Error("MMVirt", "Unable to create initial user stack, addr %p taken",
+ addr + PAGE_SIZE
+ );
+ return 0;
+ }
+
+ // 1 guard page
+ for( ofs = PAGE_SIZE; ofs < USER_STACK_SIZE; ofs += PAGE_SIZE )
+ {
+ tPAddr rv;
+ if(ofs >= USER_STACK_SIZE - USER_STACK_COMM)
+ rv = MM_Allocate(addr + ofs);
+ else
+ rv = MM_AllocateZero(addr + ofs);
+ if(rv == 0)
+ {
+ while(ofs)
+ {
+ ofs -= PAGE_SIZE;
+ MM_Deallocate(addr + ofs);
+ }
+ Log_Warning("MMVirt", "MM_NewUserStack: Unable to allocate");
+ return 0;
+ }
+ MM_SetFlags(addr+ofs, 0, MM_PFLAG_KERNEL);
+ }
+ Log("Return %p", addr + ofs);
+ MM_DumpTables(0, 0x80000000);
+ return addr + ofs;
+}
+
void MM_int_DumpTableEnt(tVAddr Start, size_t Len, tMM_PageInfo *Info)
{
- Log("%p => %8x - 0x%7x %i %x",
- Start, Info->PhysAddr-Len, Len,
- Info->Domain,
- Info->AP
- );
+ if( giMM_ZeroPage && Info->PhysAddr == giMM_ZeroPage )
+ {
+ Debug("%p => %8s - 0x%7x %i %x",
+ Start, "ZERO", Len,
+ Info->Domain, Info->AP
+ );
+ }
+ else
+ {
+ Debug("%p => %8x - 0x%7x %i %x",
+ Start, Info->PhysAddr-Len, Len,
+ Info->Domain, Info->AP
+ );
+ }
}
void MM_DumpTables(tVAddr Start, tVAddr End)
pi_old.Size = 0;
- Log("Page Table Dump:");
+ Debug("Page Table Dump:");
range_start = Start;
for( addr = Start; i == 0 || (addr && addr < End); i = 1 )
{
+ int rv;
// Log("addr = %p", addr);
- int rv = MM_int_GetPageInfo(addr, &pi);
+ rv = MM_int_GetPageInfo(addr, &pi);
if( rv
|| pi.Size != pi_old.Size
|| pi.Domain != pi_old.Domain
}
pi_old = pi;
- pi_old.PhysAddr += 1 << pi_old.Size;
+ // Handle the zero page
+ if( !giMM_ZeroPage || pi_old.Size != 12 || pi_old.PhysAddr != giMM_ZeroPage )
+ pi_old.PhysAddr += 1 << pi_old.Size;
addr += 1 << pi_old.Size;
inRange = (rv == 0);
}
if(inRange)
MM_int_DumpTableEnt(range_start, addr - range_start, &pi);
+ Debug("Done");
}