source: trunk/minix/kernel/protect.c@ 9

/* This file contains code for initialization of protected mode, to initialize
 * code and data segment descriptors, and to initialize global descriptors
 * for local descriptors in the process table.
 */

#include "kernel.h"
#include "proc.h"
#include "protect.h"

#if _WORD_SIZE == 4
#define INT_GATE_TYPE   (INT_286_GATE | DESC_386_BIT)
#define TSS_TYPE        (AVL_286_TSS  | DESC_386_BIT)
#else
#define INT_GATE_TYPE   INT_286_GATE
#define TSS_TYPE        AVL_286_TSS
#endif

struct desctableptr_s {
  char limit[sizeof(u16_t)];
  char base[sizeof(u32_t)];             /* really u24_t + pad for 286 */
};

struct gatedesc_s {
  u16_t offset_low;
  u16_t selector;
  u8_t pad;                     /* |000|XXXXX| ig & trpg, |XXXXXXXX| task g */
  u8_t p_dpl_type;              /* |P|DL|0|TYPE| */
  u16_t offset_high;
};

struct tss_s {
  reg_t backlink;
  reg_t sp0;                    /* stack pointer to use during interrupt */
  reg_t ss0;                    /*   "   segment  "  "    "        "     */
  reg_t sp1;
  reg_t ss1;
  reg_t sp2;
  reg_t ss2;
#if _WORD_SIZE == 4
  reg_t cr3;
#endif
  reg_t ip;
  reg_t flags;
  reg_t ax;
  reg_t cx;
  reg_t dx;
  reg_t bx;
  reg_t sp;
  reg_t bp;
  reg_t si;
  reg_t di;
  reg_t es;
  reg_t cs;
  reg_t ss;
  reg_t ds;
#if _WORD_SIZE == 4
  reg_t fs;
  reg_t gs;
#endif
  reg_t ldt;
#if _WORD_SIZE == 4
  u16_t trap;
  u16_t iobase;
/* u8_t iomap[0]; */
#endif
};

PUBLIC struct segdesc_s gdt[GDT_SIZE];          /* used in klib.s and mpx.s */
PRIVATE struct gatedesc_s idt[IDT_SIZE];        /* zero-init so none present */
PUBLIC struct tss_s tss;                        /* zero init */

FORWARD _PROTOTYPE( void int_gate, (unsigned vec_nr, vir_bytes offset,
                unsigned dpl_type) );
FORWARD _PROTOTYPE( void sdesc, (struct segdesc_s *segdp, phys_bytes base,
                vir_bytes size) );

/*===========================================================================*
 *                              prot_init                                    *
 *===========================================================================*/
PUBLIC void prot_init()
{
/* Set up tables for protected mode.
 * All GDT slots are allocated at compile time.
 */
  struct gate_table_s *gtp;
  struct desctableptr_s *dtp;
  unsigned ldt_index;
  register struct proc *rp;

  static struct gate_table_s {
        _PROTOTYPE( void (*gate), (void) );
        unsigned char vec_nr;
        unsigned char privilege;
  }
  gate_table[] = {
        { divide_error, DIVIDE_VECTOR, INTR_PRIVILEGE },
        { single_step_exception, DEBUG_VECTOR, INTR_PRIVILEGE },
        { nmi, NMI_VECTOR, INTR_PRIVILEGE },
        { breakpoint_exception, BREAKPOINT_VECTOR, USER_PRIVILEGE },
        { overflow, OVERFLOW_VECTOR, USER_PRIVILEGE },
        { bounds_check, BOUNDS_VECTOR, INTR_PRIVILEGE },
        { inval_opcode, INVAL_OP_VECTOR, INTR_PRIVILEGE },
        { copr_not_available, COPROC_NOT_VECTOR, INTR_PRIVILEGE },
        { double_fault, DOUBLE_FAULT_VECTOR, INTR_PRIVILEGE },
        { copr_seg_overrun, COPROC_SEG_VECTOR, INTR_PRIVILEGE },
        { inval_tss, INVAL_TSS_VECTOR, INTR_PRIVILEGE },
        { segment_not_present, SEG_NOT_VECTOR, INTR_PRIVILEGE },
        { stack_exception, STACK_FAULT_VECTOR, INTR_PRIVILEGE },
        { general_protection, PROTECTION_VECTOR, INTR_PRIVILEGE },
#if _WORD_SIZE == 4
        { page_fault, PAGE_FAULT_VECTOR, INTR_PRIVILEGE },
        { copr_error, COPROC_ERR_VECTOR, INTR_PRIVILEGE },
#endif
        { hwint00, VECTOR( 0), INTR_PRIVILEGE },
        { hwint01, VECTOR( 1), INTR_PRIVILEGE },
        { hwint02, VECTOR( 2), INTR_PRIVILEGE },
        { hwint03, VECTOR( 3), INTR_PRIVILEGE },
        { hwint04, VECTOR( 4), INTR_PRIVILEGE },
        { hwint05, VECTOR( 5), INTR_PRIVILEGE },
        { hwint06, VECTOR( 6), INTR_PRIVILEGE },
        { hwint07, VECTOR( 7), INTR_PRIVILEGE },
        { hwint08, VECTOR( 8), INTR_PRIVILEGE },
        { hwint09, VECTOR( 9), INTR_PRIVILEGE },
        { hwint10, VECTOR(10), INTR_PRIVILEGE },
        { hwint11, VECTOR(11), INTR_PRIVILEGE },
        { hwint12, VECTOR(12), INTR_PRIVILEGE },
        { hwint13, VECTOR(13), INTR_PRIVILEGE },
        { hwint14, VECTOR(14), INTR_PRIVILEGE },
        { hwint15, VECTOR(15), INTR_PRIVILEGE },
#if _WORD_SIZE == 2
        { p_s_call, SYS_VECTOR, USER_PRIVILEGE },       /* 286 system call */
#else
        { s_call, SYS386_VECTOR, USER_PRIVILEGE },      /* 386 system call */
#endif
        { level0_call, LEVEL0_VECTOR, TASK_PRIVILEGE },
  };

  /* Build gdt and idt pointers in GDT where the BIOS expects them. */
  dtp= (struct desctableptr_s *) &gdt[GDT_INDEX];
  * (u16_t *) dtp->limit = (sizeof gdt) - 1;
  * (u32_t *) dtp->base = vir2phys(gdt);

  dtp= (struct desctableptr_s *) &gdt[IDT_INDEX];
  * (u16_t *) dtp->limit = (sizeof idt) - 1;
  * (u32_t *) dtp->base = vir2phys(idt);

  /* Build segment descriptors for tasks and interrupt handlers. */
  init_codeseg(&gdt[CS_INDEX],
         kinfo.code_base, kinfo.code_size, INTR_PRIVILEGE);
  init_dataseg(&gdt[DS_INDEX],
         kinfo.data_base, kinfo.data_size, INTR_PRIVILEGE);
  init_dataseg(&gdt[ES_INDEX], 0L, 0, TASK_PRIVILEGE);

  /* Build scratch descriptors for functions in klib88. */
  init_dataseg(&gdt[DS_286_INDEX], 0L, 0, TASK_PRIVILEGE);
  init_dataseg(&gdt[ES_286_INDEX], 0L, 0, TASK_PRIVILEGE);

  /* Build local descriptors in GDT for LDT's in process table.
   * The LDT's are allocated at compile time in the process table, and
   * initialized whenever a process' map is initialized or changed.
   */
  for (rp = BEG_PROC_ADDR, ldt_index = FIRST_LDT_INDEX;
       rp < END_PROC_ADDR; ++rp, ldt_index++) {
        init_dataseg(&gdt[ldt_index], vir2phys(rp->p_ldt),
                                     sizeof(rp->p_ldt), INTR_PRIVILEGE);
        gdt[ldt_index].access = PRESENT | LDT;
        rp->p_ldt_sel = ldt_index * DESC_SIZE;
  }

  /* Build main TSS.
   * This is used only to record the stack pointer to be used after an
   * interrupt.
   * The pointer is set up so that an interrupt automatically saves the
   * current process's registers ip:cs:f:sp:ss in the correct slots in the
   * process table.
   */
  tss.ss0 = DS_SELECTOR;
  init_dataseg(&gdt[TSS_INDEX], vir2phys(&tss), sizeof(tss), INTR_PRIVILEGE);
  gdt[TSS_INDEX].access = PRESENT | (INTR_PRIVILEGE << DPL_SHIFT) | TSS_TYPE;

  /* Build descriptors for interrupt gates in IDT. */
  for (gtp = &gate_table[0];
       gtp < &gate_table[sizeof gate_table / sizeof gate_table[0]]; ++gtp) {
        int_gate(gtp->vec_nr, (vir_bytes) gtp->gate,
                 PRESENT | INT_GATE_TYPE | (gtp->privilege << DPL_SHIFT));
  }

#if _WORD_SIZE == 4
  /* Complete building of main TSS. */
  tss.iobase = sizeof tss;      /* empty i/o permissions map */
#endif
}

/*===========================================================================*
 *                              init_codeseg                                 *
 *===========================================================================*/
PUBLIC void init_codeseg(segdp, base, size, privilege)
register struct segdesc_s *segdp;
phys_bytes base;
vir_bytes size;
int privilege;
{
/* Build descriptor for a code segment. */
  sdesc(segdp, base, size);
  segdp->access = (privilege << DPL_SHIFT)
                | (PRESENT | SEGMENT | EXECUTABLE | READABLE);
                /* CONFORMING = 0, ACCESSED = 0 */
}

/*===========================================================================*
 *                              init_dataseg                                 *
 *===========================================================================*/
PUBLIC void init_dataseg(segdp, base, size, privilege)
register struct segdesc_s *segdp;
phys_bytes base;
vir_bytes size;
int privilege;
{
/* Build descriptor for a data segment. */
  sdesc(segdp, base, size);
  segdp->access = (privilege << DPL_SHIFT) | (PRESENT | SEGMENT | WRITEABLE);
                /* EXECUTABLE = 0, EXPAND_DOWN = 0, ACCESSED = 0 */
}

/*===========================================================================*
 *                              sdesc                                        *
 *===========================================================================*/
PRIVATE void sdesc(segdp, base, size)
register struct segdesc_s *segdp;
phys_bytes base;
vir_bytes size;
{
/* Fill in the size fields (base, limit and granularity) of a descriptor. */
  segdp->base_low = base;
  segdp->base_middle = base >> BASE_MIDDLE_SHIFT;
  segdp->base_high = base >> BASE_HIGH_SHIFT;

#if _WORD_SIZE == 4
  --size;                       /* convert to a limit, 0 size means 4G */
  if (size > BYTE_GRAN_MAX) {
        segdp->limit_low = size >> PAGE_GRAN_SHIFT;
        segdp->granularity = GRANULAR | (size >>
                                     (PAGE_GRAN_SHIFT + GRANULARITY_SHIFT));
  } else {
        segdp->limit_low = size;
        segdp->granularity = size >> GRANULARITY_SHIFT;
  }
  segdp->granularity |= DEFAULT;        /* means BIG for data seg */
#else
  segdp->limit_low = size - 1;
#endif
}

/*===========================================================================*
 *                              seg2phys                                     *
 *===========================================================================*/
PUBLIC phys_bytes seg2phys(seg)
U16_t seg;
{
/* Return the base address of a segment, with seg being either a 8086 segment
 * register, or a 286/386 segment selector.
 */
  phys_bytes base;
  struct segdesc_s *segdp;

  if (! machine.prot) {
        base = hclick_to_physb(seg);
  } else {
        segdp = &gdt[seg >> 3];
        base =    ((u32_t) segdp->base_low << 0)
                | ((u32_t) segdp->base_middle << 16)
                | ((u32_t) segdp->base_high << 24);
  }
  return base;
}

/*===========================================================================*
 *                              phys2seg                                     *
 *===========================================================================*/
PUBLIC void phys2seg(seg, off, phys)
u16_t *seg;
vir_bytes *off;
phys_bytes phys;
{
/* Return a segment selector and offset that can be used to reach a physical
 * address, for use by a driver doing memory I/O in the A0000 - DFFFF range.
 */
#if _WORD_SIZE == 2
  if (! machine.prot) {
        *seg = phys / HCLICK_SIZE;
        *off = phys % HCLICK_SIZE;
  } else {
        unsigned bank = phys >> 16;
        unsigned index = bank - 0xA + A_INDEX;
        init_dataseg(&gdt[index], (phys_bytes) bank << 16, 0, TASK_PRIVILEGE);
        *seg = (index * 0x08) | TASK_PRIVILEGE;
        *off = phys & 0xFFFF;
  }
#else
  *seg = FLAT_DS_SELECTOR;
  *off = phys;
#endif
}

/*===========================================================================*
 *                              int_gate                                     *
 *===========================================================================*/
PRIVATE void int_gate(vec_nr, offset, dpl_type)
unsigned vec_nr;
vir_bytes offset;
unsigned dpl_type;
{
/* Build descriptor for an interrupt gate. */
  register struct gatedesc_s *idp;

  idp = &idt[vec_nr];
  idp->offset_low = offset;
  idp->selector = CS_SELECTOR;
  idp->p_dpl_type = dpl_type;
#if _WORD_SIZE == 4
  idp->offset_high = offset >> OFFSET_HIGH_SHIFT;
#endif
}

/*===========================================================================*
 *                              enable_iop                                   * 
 *===========================================================================*/
PUBLIC void enable_iop(pp)
struct proc *pp;
{
/* Allow a user process to use I/O instructions.  Change the I/O Permission
 * Level bits in the psw. These specify least-privileged Current Permission
 * Level allowed to execute I/O instructions. Users and servers have CPL 3. 
 * You can't have less privilege than that. Kernel has CPL 0, tasks CPL 1.
 */
  pp->p_reg.psw |= 0x3000;
}

/*===========================================================================*
 *                              alloc_segments                               *
 *===========================================================================*/
PUBLIC void alloc_segments(rp)
register struct proc *rp;
{
/* This is called at system initialization from main() and by do_newmap(). 
 * The code has a separate function because of all hardware-dependencies.
 * Note that IDLE is part of the kernel and gets TASK_PRIVILEGE here.
 */
  phys_bytes code_bytes;
  phys_bytes data_bytes;
  int privilege;

  if (machine.prot) {
      data_bytes = (phys_bytes) (rp->p_memmap[S].mem_vir + 
          rp->p_memmap[S].mem_len) << CLICK_SHIFT;
      if (rp->p_memmap[T].mem_len == 0)
          code_bytes = data_bytes;      /* common I&D, poor protect */
      else
          code_bytes = (phys_bytes) rp->p_memmap[T].mem_len << CLICK_SHIFT;
      privilege = (iskernelp(rp)) ? TASK_PRIVILEGE : USER_PRIVILEGE;
      init_codeseg(&rp->p_ldt[CS_LDT_INDEX],
          (phys_bytes) rp->p_memmap[T].mem_phys << CLICK_SHIFT,
          code_bytes, privilege);
      init_dataseg(&rp->p_ldt[DS_LDT_INDEX],
          (phys_bytes) rp->p_memmap[D].mem_phys << CLICK_SHIFT,
          data_bytes, privilege);
      rp->p_reg.cs = (CS_LDT_INDEX * DESC_SIZE) | TI | privilege;
#if _WORD_SIZE == 4
      rp->p_reg.gs =
      rp->p_reg.fs =
#endif
      rp->p_reg.ss =
      rp->p_reg.es =
      rp->p_reg.ds = (DS_LDT_INDEX*DESC_SIZE) | TI | privilege;
  } else {
      rp->p_reg.cs = click_to_hclick(rp->p_memmap[T].mem_phys);
      rp->p_reg.ss =
      rp->p_reg.es =
      rp->p_reg.ds = click_to_hclick(rp->p_memmap[D].mem_phys);
  }
}