// This file contains definitions for the // x86 memory management unit (MMU). // Eflags register #define FL_IF 0x00000200 // Interrupt Enable // Control Register flags #define CR0_PE 0x00000001 // Protection Enable #define CR0_WP 0x00010000 // Write Protect #define CR0_PG 0x80000000 // Paging #define CR4_PSE 0x00000010 // Page size extension // various segment selectors. #define SEG_KCODE 1 // kernel code #define SEG_KDATA 2 // kernel data+stack #define SEG_UCODE 3 // user code #define SEG_UDATA 4 // user data+stack #define SEG_TSS 5 // this process's task state // cpu->gdt[NSEGS] holds the above segments. #define NSEGS 6 #ifndef __ASSEMBLER__ // Segment Descriptor struct segdesc { uint lim_15_0 : 16; // Low bits of segment limit uint base_15_0 : 16; // Low bits of segment base address uint base_23_16 : 8; // Middle bits of segment base address uint type : 4; // Segment type (see STS_ constants) uint s : 1; // 0 = system, 1 = application uint dpl : 2; // Descriptor Privilege Level uint p : 1; // Present uint lim_19_16 : 4; // High bits of segment limit uint avl : 1; // Unused (available for software use) uint rsv1 : 1; // Reserved uint db : 1; // 0 = 16-bit segment, 1 = 32-bit segment uint g : 1; // Granularity: limit scaled by 4K when set uint base_31_24 : 8; // High bits of segment base address }; // Normal segment #define SEG(type, base, lim, dpl) (struct segdesc) \ { ((lim) >> 12) & 0xffff, (uint)(base) & 0xffff, \ ((uint)(base) >> 16) & 0xff, type, 1, dpl, 1, \ (uint)(lim) >> 28, 0, 0, 1, 1, (uint)(base) >> 24 } #define SEG16(type, base, lim, dpl) (struct segdesc) \ { (lim) & 0xffff, (uint)(base) & 0xffff, \ ((uint)(base) >> 16) & 0xff, type, 1, dpl, 1, \ (uint)(lim) >> 16, 0, 0, 1, 0, (uint)(base) >> 24 } #endif #define DPL_USER 0x3 // User DPL // Application segment type bits #define STA_X 0x8 // Executable segment #define STA_W 0x2 // Writeable (non-executable segments) #define STA_R 0x2 // Readable (executable segments) // System segment type bits #define STS_T32A 0x9 // Available 32-bit TSS #define STS_IG32 0xE // 32-bit Interrupt Gate #define STS_TG32 0xF // 32-bit Trap Gate // A virtual address 'la' has a three-part structure as follows: // // +--------10------+-------10-------+---------12----------+ // | Page Directory | Page Table | Offset within Page | // | Index | Index | | // +----------------+----------------+---------------------+ // \--- PDX(va) --/ \--- PTX(va) --/ // page directory index #define PDX(va) (((uint)(va) >> PDXSHIFT) & 0x3FF) // page table index #define PTX(va) (((uint)(va) >> PTXSHIFT) & 0x3FF) // construct virtual address from indexes and offset #define PGADDR(d, t, o) ((uint)((d) << PDXSHIFT | (t) << PTXSHIFT | (o))) // Page directory and page table constants. #define NPDENTRIES 1024 // # directory entries per page directory #define NPTENTRIES 1024 // # PTEs per page table #define PGSIZE 4096 // bytes mapped by a page #define PTXSHIFT 12 // offset of PTX in a linear address #define PDXSHIFT 22 // offset of PDX in a linear address #define PGROUNDUP(sz) (((sz) + PGSIZE - 1) & ~(PGSIZE - 1)) #define PGROUNDDOWN(a) (((a)) & ~(PGSIZE - 1)) // Page table/directory entry flags. #define PTE_P 0x001 // Present #define PTE_W 0x002 // Writeable #define PTE_U 0x004 // User #define PTE_PS 0x080 // Page Size // Address in page table or page directory entry #define PTE_ADDR(pte) ((uint)(pte) & ~0xFFF) #define PTE_FLAGS(pte) ((uint)(pte) & 0xFFF) #ifndef __ASSEMBLER__ typedef uint pte_t; // Task state segment format struct taskstate { uint link; // Old ts selector uint esp0; // Stack pointers and segment selectors ushort ss0; // after an increase in privilege level ushort padding1; uint *esp1; ushort ss1; ushort padding2; uint *esp2; ushort ss2; ushort padding3; void *cr3; // Page directory base uint *eip; // Saved state from last task switch uint eflags; uint eax; // More saved state (registers) uint ecx; uint edx; uint ebx; uint *esp; uint *ebp; uint esi; uint edi; ushort es; // Even more saved state (segment selectors) ushort padding4; ushort cs; ushort padding5; ushort ss; ushort padding6; ushort ds; ushort padding7; ushort fs; ushort padding8; ushort gs; ushort padding9; ushort ldt; ushort padding10; ushort t; // Trap on task switch ushort iomb; // I/O map base address }; // Gate descriptors for interrupts and traps struct gatedesc { uint off_15_0 : 16; // low 16 bits of offset in segment uint cs : 16; // code segment selector uint args : 5; // # args, 0 for interrupt/trap gates uint rsv1 : 3; // reserved(should be zero I guess) uint type : 4; // type(STS_{IG32,TG32}) uint s : 1; // must be 0 (system) uint dpl : 2; // descriptor(meaning new) privilege level uint p : 1; // Present uint off_31_16 : 16; // high bits of offset in segment }; // Set up a normal interrupt/trap gate descriptor. // - istrap: 1 for a trap (= exception) gate, 0 for an interrupt gate. // interrupt gate clears FL_IF, trap gate leaves FL_IF alone // - sel: Code segment selector for interrupt/trap handler // - off: Offset in code segment for interrupt/trap handler // - dpl: Descriptor Privilege Level - // the privilege level required for software to invoke // this interrupt/trap gate explicitly using an int instruction. #define SETGATE(gate, istrap, sel, off, d) \ { \ (gate).off_15_0 = (uint)(off) & 0xffff; \ (gate).cs = (sel); \ (gate).args = 0; \ (gate).rsv1 = 0; \ (gate).type = (istrap) ? STS_TG32 : STS_IG32; \ (gate).s = 0; \ (gate).dpl = (d); \ (gate).p = 1; \ (gate).off_31_16 = (uint)(off) >> 16; \ } #endif