318 lines
11 KiB
C
318 lines
11 KiB
C
#ifndef JOS_INC_MMU_H
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#define JOS_INC_MMU_H
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/*
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* This file contains definitions for the x86 memory management unit (MMU),
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* including paging- and segmentation-related data structures and constants,
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* the %cr0, %cr4, and %eflags registers, and traps.
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*/
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/*
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*
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* Part 1. Paging data structures and constants.
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*
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*/
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// A linear address 'la' has a three-part structure as follows:
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//
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// +--------10------+-------10-------+---------12----------+
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// | Page Directory | Page Table | Offset within Page |
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// | Index | Index | |
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// +----------------+----------------+---------------------+
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// \--- PDX(la) --/ \--- PTX(la) --/ \---- PGOFF(la) ----/
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// \---------- PGNUM(la) ----------/
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//
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// The PDX, PTX, PGOFF, and PGNUM macros decompose linear addresses as shown.
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// To construct a linear address la from PDX(la), PTX(la), and PGOFF(la),
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// use PGADDR(PDX(la), PTX(la), PGOFF(la)).
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// page number field of address
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#define PGNUM(la) (((uintptr_t) (la)) >> PTXSHIFT)
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// page directory index
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#define PDX(la) ((((uintptr_t) (la)) >> PDXSHIFT) & 0x3FF)
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// page table index
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#define PTX(la) ((((uintptr_t) (la)) >> PTXSHIFT) & 0x3FF)
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// offset in page
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#define PGOFF(la) (((uintptr_t) (la)) & 0xFFF)
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// construct linear address from indexes and offset
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#define PGADDR(d, t, o) ((void*) ((d) << PDXSHIFT | (t) << PTXSHIFT | (o)))
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// Page directory and page table constants.
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#define NPDENTRIES 1024 // page directory entries per page directory
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#define NPTENTRIES 1024 // page table entries per page table
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#define PGSIZE 4096 // bytes mapped by a page
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#define PGSHIFT 12 // log2(PGSIZE)
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#define PTSIZE (PGSIZE*NPTENTRIES) // bytes mapped by a page directory entry
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#define PTSHIFT 22 // log2(PTSIZE)
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#define PTXSHIFT 12 // offset of PTX in a linear address
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#define PDXSHIFT 22 // offset of PDX in a linear address
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// Page table/directory entry flags.
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#define PTE_P 0x001 // Present
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#define PTE_W 0x002 // Writeable
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#define PTE_U 0x004 // User
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#define PTE_PWT 0x008 // Write-Through
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#define PTE_PCD 0x010 // Cache-Disable
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#define PTE_A 0x020 // Accessed
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#define PTE_D 0x040 // Dirty
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#define PTE_PS 0x080 // Page Size
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#define PTE_G 0x100 // Global
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// The PTE_AVAIL bits aren't used by the kernel or interpreted by the
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// hardware, so user processes are allowed to set them arbitrarily.
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#define PTE_AVAIL 0xE00 // Available for software use
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// Flags in PTE_SYSCALL may be used in system calls. (Others may not.)
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#define PTE_SYSCALL (PTE_AVAIL | PTE_P | PTE_W | PTE_U)
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// Address in page table or page directory entry
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#define PTE_ADDR(pte) ((physaddr_t) (pte) & ~0xFFF)
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// Control Register flags
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#define CR0_PE 0x00000001 // Protection Enable
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#define CR0_MP 0x00000002 // Monitor coProcessor
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#define CR0_EM 0x00000004 // Emulation
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#define CR0_TS 0x00000008 // Task Switched
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#define CR0_ET 0x00000010 // Extension Type
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#define CR0_NE 0x00000020 // Numeric Errror
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#define CR0_WP 0x00010000 // Write Protect
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#define CR0_AM 0x00040000 // Alignment Mask
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#define CR0_NW 0x20000000 // Not Writethrough
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#define CR0_CD 0x40000000 // Cache Disable
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#define CR0_PG 0x80000000 // Paging
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#define CR4_PCE 0x00000100 // Performance counter enable
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#define CR4_MCE 0x00000040 // Machine Check Enable
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#define CR4_PSE 0x00000010 // Page Size Extensions
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#define CR4_DE 0x00000008 // Debugging Extensions
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#define CR4_TSD 0x00000004 // Time Stamp Disable
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#define CR4_PVI 0x00000002 // Protected-Mode Virtual Interrupts
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#define CR4_VME 0x00000001 // V86 Mode Extensions
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// Eflags register
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#define FL_CF 0x00000001 // Carry Flag
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#define FL_PF 0x00000004 // Parity Flag
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#define FL_AF 0x00000010 // Auxiliary carry Flag
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#define FL_ZF 0x00000040 // Zero Flag
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#define FL_SF 0x00000080 // Sign Flag
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#define FL_TF 0x00000100 // Trap Flag
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#define FL_IF 0x00000200 // Interrupt Flag
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#define FL_DF 0x00000400 // Direction Flag
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#define FL_OF 0x00000800 // Overflow Flag
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#define FL_IOPL_MASK 0x00003000 // I/O Privilege Level bitmask
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#define FL_IOPL_0 0x00000000 // IOPL == 0
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#define FL_IOPL_1 0x00001000 // IOPL == 1
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#define FL_IOPL_2 0x00002000 // IOPL == 2
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#define FL_IOPL_3 0x00003000 // IOPL == 3
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#define FL_NT 0x00004000 // Nested Task
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#define FL_RF 0x00010000 // Resume Flag
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#define FL_VM 0x00020000 // Virtual 8086 mode
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#define FL_AC 0x00040000 // Alignment Check
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#define FL_VIF 0x00080000 // Virtual Interrupt Flag
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#define FL_VIP 0x00100000 // Virtual Interrupt Pending
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#define FL_ID 0x00200000 // ID flag
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// Page fault error codes
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#define FEC_PR 0x1 // Page fault caused by protection violation
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#define FEC_WR 0x2 // Page fault caused by a write
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#define FEC_U 0x4 // Page fault occured while in user mode
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/*
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*
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* Part 2. Segmentation data structures and constants.
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*
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*/
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#ifdef __ASSEMBLER__
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/*
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* Macros to build GDT entries in assembly.
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*/
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#define SEG_NULL \
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.word 0, 0; \
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.byte 0, 0, 0, 0
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#define SEG(type,base,lim) \
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.word (((lim) >> 12) & 0xffff), ((base) & 0xffff); \
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.byte (((base) >> 16) & 0xff), (0x90 | (type)), \
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(0xC0 | (((lim) >> 28) & 0xf)), (((base) >> 24) & 0xff)
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#else // not __ASSEMBLER__
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#include <inc/types.h>
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// Segment Descriptors
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struct Segdesc {
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unsigned sd_lim_15_0 : 16; // Low bits of segment limit
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unsigned sd_base_15_0 : 16; // Low bits of segment base address
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unsigned sd_base_23_16 : 8; // Middle bits of segment base address
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unsigned sd_type : 4; // Segment type (see STS_ constants)
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unsigned sd_s : 1; // 0 = system, 1 = application
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unsigned sd_dpl : 2; // Descriptor Privilege Level
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unsigned sd_p : 1; // Present
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unsigned sd_lim_19_16 : 4; // High bits of segment limit
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unsigned sd_avl : 1; // Unused (available for software use)
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unsigned sd_rsv1 : 1; // Reserved
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unsigned sd_db : 1; // 0 = 16-bit segment, 1 = 32-bit segment
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unsigned sd_g : 1; // Granularity: limit scaled by 4K when set
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unsigned sd_base_31_24 : 8; // High bits of segment base address
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};
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// Null segment
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#define SEG_NULL { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }
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// Segment that is loadable but faults when used
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#define SEG_FAULT { 0, 0, 0, 0, 1, 0, 1, 0, 0, 0, 1, 0, 0 }
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// Normal segment
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#define SEG(type, base, lim, dpl) \
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{ ((lim) >> 12) & 0xffff, (base) & 0xffff, ((base) >> 16) & 0xff, \
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type, 1, dpl, 1, (unsigned) (lim) >> 28, 0, 0, 1, 1, \
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(unsigned) (base) >> 24 }
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#define SEG16(type, base, lim, dpl) (struct Segdesc) \
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{ (lim) & 0xffff, (base) & 0xffff, ((base) >> 16) & 0xff, \
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type, 1, dpl, 1, (unsigned) (lim) >> 16, 0, 0, 1, 0, \
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(unsigned) (base) >> 24 }
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#endif /* !__ASSEMBLER__ */
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// Application segment type bits
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#define STA_X 0x8 // Executable segment
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#define STA_E 0x4 // Expand down (non-executable segments)
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#define STA_C 0x4 // Conforming code segment (executable only)
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#define STA_W 0x2 // Writeable (non-executable segments)
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#define STA_R 0x2 // Readable (executable segments)
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#define STA_A 0x1 // Accessed
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// System segment type bits
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#define STS_T16A 0x1 // Available 16-bit TSS
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#define STS_LDT 0x2 // Local Descriptor Table
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#define STS_T16B 0x3 // Busy 16-bit TSS
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#define STS_CG16 0x4 // 16-bit Call Gate
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#define STS_TG 0x5 // Task Gate / Coum Transmitions
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#define STS_IG16 0x6 // 16-bit Interrupt Gate
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#define STS_TG16 0x7 // 16-bit Trap Gate
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#define STS_T32A 0x9 // Available 32-bit TSS
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#define STS_T32B 0xB // Busy 32-bit TSS
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#define STS_CG32 0xC // 32-bit Call Gate
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#define STS_IG32 0xE // 32-bit Interrupt Gate
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#define STS_TG32 0xF // 32-bit Trap Gate
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/*
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*
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* Part 3. Traps.
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*
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*/
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#ifndef __ASSEMBLER__
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// Task state segment format (as described by the Pentium architecture book)
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struct Taskstate {
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uint32_t ts_link; // Old ts selector
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uintptr_t ts_esp0; // Stack pointers and segment selectors
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uint16_t ts_ss0; // after an increase in privilege level
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uint16_t ts_padding1;
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uintptr_t ts_esp1;
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uint16_t ts_ss1;
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uint16_t ts_padding2;
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uintptr_t ts_esp2;
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uint16_t ts_ss2;
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uint16_t ts_padding3;
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physaddr_t ts_cr3; // Page directory base
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uintptr_t ts_eip; // Saved state from last task switch
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uint32_t ts_eflags;
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uint32_t ts_eax; // More saved state (registers)
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uint32_t ts_ecx;
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uint32_t ts_edx;
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uint32_t ts_ebx;
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uintptr_t ts_esp;
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uintptr_t ts_ebp;
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uint32_t ts_esi;
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uint32_t ts_edi;
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uint16_t ts_es; // Even more saved state (segment selectors)
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uint16_t ts_padding4;
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uint16_t ts_cs;
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uint16_t ts_padding5;
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uint16_t ts_ss;
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uint16_t ts_padding6;
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uint16_t ts_ds;
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uint16_t ts_padding7;
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uint16_t ts_fs;
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uint16_t ts_padding8;
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uint16_t ts_gs;
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uint16_t ts_padding9;
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uint16_t ts_ldt;
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uint16_t ts_padding10;
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uint16_t ts_t; // Trap on task switch
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uint16_t ts_iomb; // I/O map base address
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};
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// Gate descriptors for interrupts and traps
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struct Gatedesc {
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unsigned gd_off_15_0 : 16; // low 16 bits of offset in segment
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unsigned gd_sel : 16; // segment selector
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unsigned gd_args : 5; // # args, 0 for interrupt/trap gates
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unsigned gd_rsv1 : 3; // reserved(should be zero I guess)
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unsigned gd_type : 4; // type(STS_{TG,IG32,TG32})
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unsigned gd_s : 1; // must be 0 (system)
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unsigned gd_dpl : 2; // descriptor(meaning new) privilege level
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unsigned gd_p : 1; // Present
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unsigned gd_off_31_16 : 16; // high bits of offset in segment
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};
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// Set up a normal interrupt/trap gate descriptor.
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// - istrap: 1 for a trap (= exception) gate, 0 for an interrupt gate.
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// see section 9.6.1.3 of the i386 reference: "The difference between
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// an interrupt gate and a trap gate is in the effect on IF (the
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// interrupt-enable flag). An interrupt that vectors through an
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// interrupt gate resets IF, thereby preventing other interrupts from
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// interfering with the current interrupt handler. A subsequent IRET
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// instruction restores IF to the value in the EFLAGS image on the
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// stack. An interrupt through a trap gate does not change IF."
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// - sel: Code segment selector for interrupt/trap handler
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// - off: Offset in code segment for interrupt/trap handler
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// - dpl: Descriptor Privilege Level -
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// the privilege level required for software to invoke
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// this interrupt/trap gate explicitly using an int instruction.
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#define SETGATE(gate, istrap, sel, off, dpl) \
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{ \
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(gate).gd_off_15_0 = (uint32_t) (off) & 0xffff; \
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(gate).gd_sel = (sel); \
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(gate).gd_args = 0; \
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(gate).gd_rsv1 = 0; \
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(gate).gd_type = (istrap) ? STS_TG32 : STS_IG32; \
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(gate).gd_s = 0; \
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(gate).gd_dpl = (dpl); \
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(gate).gd_p = 1; \
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(gate).gd_off_31_16 = (uint32_t) (off) >> 16; \
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}
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// Set up a call gate descriptor.
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#define SETCALLGATE(gate, sel, off, dpl) \
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{ \
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(gate).gd_off_15_0 = (uint32_t) (off) & 0xffff; \
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(gate).gd_sel = (sel); \
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(gate).gd_args = 0; \
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(gate).gd_rsv1 = 0; \
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(gate).gd_type = STS_CG32; \
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(gate).gd_s = 0; \
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(gate).gd_dpl = (dpl); \
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(gate).gd_p = 1; \
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(gate).gd_off_31_16 = (uint32_t) (off) >> 16; \
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}
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// Pseudo-descriptors used for LGDT, LLDT and LIDT instructions.
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struct Pseudodesc {
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uint16_t pd_lim; // Limit
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uint32_t pd_base; // Base address
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} __attribute__ ((packed));
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#endif /* !__ASSEMBLER__ */
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#endif /* !JOS_INC_MMU_H */
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