minix/kernel/arch/i386/memory.c


#include "../../kernel.h"
#include "../../proc.h"

#include <minix/type.h>
#include <string.h>

#include <sys/vm.h>

#include <minix/portio.h>

#include "proto.h"

/* VM functions and data. */

PRIVATE int vm_needs_init= 1;
PRIVATE u32_t vm_cr3;

FORWARD _PROTOTYPE( void phys_put32, (phys_bytes addr, u32_t value)	);
FORWARD _PROTOTYPE( u32_t phys_get32, (phys_bytes addr)			);
FORWARD _PROTOTYPE( void vm_set_cr3, (u32_t value)			);
FORWARD _PROTOTYPE( void set_cr3, (void)				);
FORWARD _PROTOTYPE( void vm_enable_paging, (void)			);

/* *** Internal VM Functions *** */

PUBLIC void vm_init(void)
{
	int o;
	phys_bytes p, pt_size;
	phys_bytes vm_dir_base, vm_pt_base, phys_mem;
	u32_t entry;
	unsigned pages;

	if (!vm_size)
		panic("i386_vm_init: no space for page tables", NO_NUM);

	/* Align page directory */
	o= (vm_base % PAGE_SIZE);
	if (o != 0)
		o= PAGE_SIZE-o;
	vm_dir_base= vm_base+o;

	/* Page tables start after the page directory */
	vm_pt_base= vm_dir_base+PAGE_SIZE;

	pt_size= (vm_base+vm_size)-vm_pt_base;
	pt_size -= (pt_size % PAGE_SIZE);

	/* Compute the number of pages based on vm_mem_high */
	pages= (vm_mem_high-1)/PAGE_SIZE + 1;

	if (pages * I386_VM_PT_ENT_SIZE > pt_size)
		panic("i386_vm_init: page table too small", NO_NUM);

	for (p= 0; p*I386_VM_PT_ENT_SIZE < pt_size; p++)
	{
		phys_mem= p*PAGE_SIZE;
		entry= phys_mem | I386_VM_USER | I386_VM_WRITE |
			I386_VM_PRESENT;
		if (phys_mem >= vm_mem_high)
			entry= 0;
		phys_put32(vm_pt_base + p*I386_VM_PT_ENT_SIZE, entry);
	}

	for (p= 0; p < I386_VM_DIR_ENTRIES; p++)
	{
		phys_mem= vm_pt_base + p*PAGE_SIZE;
		entry= phys_mem | I386_VM_USER | I386_VM_WRITE |
			I386_VM_PRESENT;
		if (phys_mem >= vm_pt_base + pt_size)
			entry= 0;
		phys_put32(vm_dir_base + p*I386_VM_PT_ENT_SIZE, entry);
	}
	vm_set_cr3(vm_dir_base);
	level0(vm_enable_paging);
}

PRIVATE void phys_put32(addr, value)
phys_bytes addr;
u32_t value;
{
	phys_copy(vir2phys((vir_bytes)&value), addr, sizeof(value));
}

PRIVATE u32_t phys_get32(addr)
phys_bytes addr;
{
	u32_t value;

	phys_copy(addr, vir2phys((vir_bytes)&value), sizeof(value));

	return value;
}

PRIVATE void vm_set_cr3(value)
u32_t value;
{
	vm_cr3= value;
	level0(set_cr3);
}

PRIVATE void set_cr3()
{
	write_cr3(vm_cr3);
}

PRIVATE void vm_enable_paging(void)
{
	u32_t cr0;

	cr0= read_cr0();
	write_cr0(cr0 | I386_CR0_PG);
}

PUBLIC void vm_map_range(base, size, offset)
u32_t base;
u32_t size;
u32_t offset;
{
	u32_t curr_pt, curr_pt_addr, entry;
	int dir_ent, pt_ent;

	if (base % PAGE_SIZE != 0)
		panic("map_range: bad base", base);
	if (size % PAGE_SIZE != 0)
		panic("map_range: bad size", size);
	if (offset % PAGE_SIZE != 0)
		panic("map_range: bad offset", offset);

	curr_pt= -1;
	curr_pt_addr= 0;
	while (size != 0)
	{
		dir_ent= (base >> I386_VM_DIR_ENT_SHIFT);
		pt_ent= (base >> I386_VM_PT_ENT_SHIFT) & I386_VM_PT_ENT_MASK;
		if (dir_ent != curr_pt)
		{
			/* Get address of page table */
			curr_pt= dir_ent;
			curr_pt_addr= phys_get32(vm_cr3 +
				dir_ent * I386_VM_PT_ENT_SIZE);
			curr_pt_addr &= I386_VM_ADDR_MASK;
		}
		entry= offset | I386_VM_USER | I386_VM_WRITE |
			I386_VM_PRESENT;
#if 0	/* Do we need this for memory mapped I/O? */
		entry |= I386_VM_PCD | I386_VM_PWT;
#endif
		phys_put32(curr_pt_addr + pt_ent * I386_VM_PT_ENT_SIZE, entry);
		offset += PAGE_SIZE;
		base += PAGE_SIZE;
		size -= PAGE_SIZE;
	}

	/* reload root of page table. */
	vm_set_cr3(vm_cr3);
}

PUBLIC vir_bytes alloc_remote_segment(u32_t *selector,
	segframe_t *segments, int index, phys_bytes phys, vir_bytes size,
	int priv)
{
	phys_bytes offset = 0;
	/* Check if the segment size can be recorded in bytes, that is, check
	 * if descriptor's limit field can delimited the allowed memory region
	 * precisely. This works up to 1MB. If the size is larger, 4K pages
	 * instead of bytes are used.
	*/
	if (size < BYTE_GRAN_MAX) {
		init_dataseg(&segments->p_ldt[EXTRA_LDT_INDEX+index],
			phys, size, priv);
		*selector = ((EXTRA_LDT_INDEX+index)*0x08) | (1*0x04) | priv;
		offset = 0;
	} else {
		init_dataseg(&segments->p_ldt[EXTRA_LDT_INDEX+index],
			phys & ~0xFFFF, 0, priv);
		*selector = ((EXTRA_LDT_INDEX+index)*0x08) | (1*0x04) | priv;
		offset = phys & 0xFFFF;
	}

	return offset;
}

PUBLIC phys_bytes umap_remote(struct proc* rp, int seg,
	vir_bytes vir_addr, vir_bytes bytes)
{
/* Calculate the physical memory address for a given virtual address. */
  struct far_mem *fm;

  if (bytes <= 0) return( (phys_bytes) 0);
  if (seg < 0 || seg >= NR_REMOTE_SEGS) return( (phys_bytes) 0);

  fm = &rp->p_priv->s_farmem[seg];
  if (! fm->in_use) return( (phys_bytes) 0);
  if (vir_addr + bytes > fm->mem_len) return( (phys_bytes) 0);

  return(fm->mem_phys + (phys_bytes) vir_addr);
}

/*===========================================================================*
 *                              umap_local                                   *
 *===========================================================================*/
PUBLIC phys_bytes umap_local(rp, seg, vir_addr, bytes)
register struct proc *rp;       /* pointer to proc table entry for process */
int seg;                        /* T, D, or S segment */
vir_bytes vir_addr;             /* virtual address in bytes within the seg */
vir_bytes bytes;                /* # of bytes to be copied */
{
/* Calculate the physical memory address for a given virtual address. */
  vir_clicks vc;                /* the virtual address in clicks */
  phys_bytes pa;                /* intermediate variables as phys_bytes */
  phys_bytes seg_base;

  if (bytes <= 0) return( (phys_bytes) 0);
  if (vir_addr + bytes <= vir_addr) return 0;   /* overflow */
  vc = (vir_addr + bytes - 1) >> CLICK_SHIFT;   /* last click of data */
 
  if (seg != T)
        seg = (vc < rp->p_memmap[D].mem_vir + rp->p_memmap[D].mem_len ? D : S);
 
  if ((vir_addr>>CLICK_SHIFT) >= rp->p_memmap[seg].mem_vir +
        rp->p_memmap[seg].mem_len) return( (phys_bytes) 0 );
 
  if (vc >= rp->p_memmap[seg].mem_vir +
        rp->p_memmap[seg].mem_len) return( (phys_bytes) 0 );
  
  seg_base = (phys_bytes) rp->p_memmap[seg].mem_phys;
  seg_base = seg_base << CLICK_SHIFT;   /* segment origin in bytes */
  pa = (phys_bytes) vir_addr;
  pa -= rp->p_memmap[seg].mem_vir << CLICK_SHIFT;
  return(seg_base + pa);
}
Split of architecture-dependent and -independent functions for i386, mainly in the kernel and headers. This split based on work by Ingmar Alting <iaalting@cs.vu.nl> done for his Minix PowerPC architecture port. . kernel does not program the interrupt controller directly, do any other architecture-dependent operations, or contain assembly any more, but uses architecture-dependent functions in arch/$(ARCH)/. . architecture-dependent constants and types defined in arch/$(ARCH)/include. . <ibm/portio.h> moved to <minix/portio.h>, as they have become, for now, architecture-independent functions. . int86, sdevio, readbios, and iopenable are now i386-specific kernel calls and live in arch/i386/do_* now. . i386 arch now supports even less 86 code; e.g. mpx86.s and klib86.s have gone, and 'machine.protected' is gone (and always taken to be 1 in i386). If 86 support is to return, it should be a new architecture. . prototypes for the architecture-dependent functions defined in kernel/arch/$(ARCH)/*.c but used in kernel/ are in kernel/proto.h . /etc/make.conf included in makefiles and shell scripts that need to know the building architecture; it defines ARCH=<arch>, currently only i386. . some basic per-architecture build support outside of the kernel (lib) . in clock.c, only dequeue a process if it was ready . fixes for new include files files deleted: . mpx/klib.s - only for choosing between mpx/klib86 and -386 . klib86.s - only for 86 i386-specific files files moved (or arch-dependent stuff moved) to arch/i386/: . mpx386.s (entry point) . klib386.s . sconst.h . exception.c . protect.c . protect.h . i8269.c 2006-12-22 16:22:27 +01:00
			`#include "../../kernel.h"`
			`#include "../../proc.h"`

			`#include <minix/type.h>`
			`#include <string.h>`

			`#include <sys/vm.h>`

			`#include <minix/portio.h>`

			`#include "proto.h"`

			`/* VM functions and data. */`

			`PRIVATE int vm_needs_init= 1;`
			`PRIVATE u32_t vm_cr3;`

			`FORWARD _PROTOTYPE( void phys_put32, (phys_bytes addr, u32_t value) );`
			`FORWARD _PROTOTYPE( u32_t phys_get32, (phys_bytes addr) );`
			`FORWARD _PROTOTYPE( void vm_set_cr3, (u32_t value) );`
			`FORWARD _PROTOTYPE( void set_cr3, (void) );`
			`FORWARD _PROTOTYPE( void vm_enable_paging, (void) );`

			`/* * Internal VM Functions * */`

			`PUBLIC void vm_init(void)`
			`{`
			`int o;`
			`phys_bytes p, pt_size;`
			`phys_bytes vm_dir_base, vm_pt_base, phys_mem;`
			`u32_t entry;`
			`unsigned pages;`

			`if (!vm_size)`
			`panic("i386_vm_init: no space for page tables", NO_NUM);`

			`/* Align page directory */`
			`o= (vm_base % PAGE_SIZE);`
			`if (o != 0)`
			`o= PAGE_SIZE-o;`
			`vm_dir_base= vm_base+o;`

			`/* Page tables start after the page directory */`
			`vm_pt_base= vm_dir_base+PAGE_SIZE;`

			`pt_size= (vm_base+vm_size)-vm_pt_base;`
			`pt_size -= (pt_size % PAGE_SIZE);`

			`/* Compute the number of pages based on vm_mem_high */`
			`pages= (vm_mem_high-1)/PAGE_SIZE + 1;`

			`if (pages * I386_VM_PT_ENT_SIZE > pt_size)`
			`panic("i386_vm_init: page table too small", NO_NUM);`

			`for (p= 0; p*I386_VM_PT_ENT_SIZE < pt_size; p++)`
			`{`
			`phys_mem= p*PAGE_SIZE;`
			`entry= phys_mem \| I386_VM_USER \| I386_VM_WRITE \|`
			`I386_VM_PRESENT;`
			`if (phys_mem >= vm_mem_high)`
			`entry= 0;`
			`phys_put32(vm_pt_base + p*I386_VM_PT_ENT_SIZE, entry);`
			`}`

			`for (p= 0; p < I386_VM_DIR_ENTRIES; p++)`
			`{`
			`phys_mem= vm_pt_base + p*PAGE_SIZE;`
			`entry= phys_mem \| I386_VM_USER \| I386_VM_WRITE \|`
			`I386_VM_PRESENT;`
			`if (phys_mem >= vm_pt_base + pt_size)`
			`entry= 0;`
			`phys_put32(vm_dir_base + p*I386_VM_PT_ENT_SIZE, entry);`
			`}`
			`vm_set_cr3(vm_dir_base);`
			`level0(vm_enable_paging);`
			`}`

			`PRIVATE void phys_put32(addr, value)`
			`phys_bytes addr;`
			`u32_t value;`
			`{`
			`phys_copy(vir2phys((vir_bytes)&value), addr, sizeof(value));`
			`}`

			`PRIVATE u32_t phys_get32(addr)`
			`phys_bytes addr;`
			`{`
			`u32_t value;`

			`phys_copy(addr, vir2phys((vir_bytes)&value), sizeof(value));`

			`return value;`
			`}`

			`PRIVATE void vm_set_cr3(value)`
			`u32_t value;`
			`{`
			`vm_cr3= value;`
			`level0(set_cr3);`
			`}`

			`PRIVATE void set_cr3()`
			`{`
			`write_cr3(vm_cr3);`
			`}`

			`PRIVATE void vm_enable_paging(void)`
			`{`
			`u32_t cr0;`

			`cr0= read_cr0();`
			`write_cr0(cr0 \| I386_CR0_PG);`
			`}`

			`PUBLIC void vm_map_range(base, size, offset)`
			`u32_t base;`
			`u32_t size;`
			`u32_t offset;`
			`{`
			`u32_t curr_pt, curr_pt_addr, entry;`
			`int dir_ent, pt_ent;`

			`if (base % PAGE_SIZE != 0)`
			`panic("map_range: bad base", base);`
			`if (size % PAGE_SIZE != 0)`
			`panic("map_range: bad size", size);`
			`if (offset % PAGE_SIZE != 0)`
			`panic("map_range: bad offset", offset);`

			`curr_pt= -1;`
			`curr_pt_addr= 0;`
			`while (size != 0)`
			`{`
			`dir_ent= (base >> I386_VM_DIR_ENT_SHIFT);`
			`pt_ent= (base >> I386_VM_PT_ENT_SHIFT) & I386_VM_PT_ENT_MASK;`
			`if (dir_ent != curr_pt)`
			`{`
			`/* Get address of page table */`
			`curr_pt= dir_ent;`
			`curr_pt_addr= phys_get32(vm_cr3 +`
			`dir_ent * I386_VM_PT_ENT_SIZE);`
			`curr_pt_addr &= I386_VM_ADDR_MASK;`
			`}`
			`entry= offset \| I386_VM_USER \| I386_VM_WRITE \|`
			`I386_VM_PRESENT;`
			`#if 0 /* Do we need this for memory mapped I/O? */`
			`entry \|= I386_VM_PCD \| I386_VM_PWT;`
			`#endif`
			`phys_put32(curr_pt_addr + pt_ent * I386_VM_PT_ENT_SIZE, entry);`
			`offset += PAGE_SIZE;`
			`base += PAGE_SIZE;`
			`size -= PAGE_SIZE;`
			`}`

			`/* reload root of page table. */`
			`vm_set_cr3(vm_cr3);`
			`}`

			`PUBLIC vir_bytes alloc_remote_segment(u32_t *selector,`
			`segframe_t *segments, int index, phys_bytes phys, vir_bytes size,`
			`int priv)`
			`{`
			`phys_bytes offset = 0;`
			`/* Check if the segment size can be recorded in bytes, that is, check`
			`* if descriptor's limit field can delimited the allowed memory region`
			`* precisely. This works up to 1MB. If the size is larger, 4K pages`
			`* instead of bytes are used.`
			`*/`
			`if (size < BYTE_GRAN_MAX) {`
			`init_dataseg(&segments->p_ldt[EXTRA_LDT_INDEX+index],`
			`phys, size, priv);`
			`selector = ((EXTRA_LDT_INDEX+index)0x08) \| (1*0x04) \| priv;`
			`offset = 0;`
			`} else {`
			`init_dataseg(&segments->p_ldt[EXTRA_LDT_INDEX+index],`
			`phys & ~0xFFFF, 0, priv);`
			`selector = ((EXTRA_LDT_INDEX+index)0x08) \| (1*0x04) \| priv;`
			`offset = phys & 0xFFFF;`
			`}`

			`return offset;`
			`}`

			`PUBLIC phys_bytes umap_remote(struct proc* rp, int seg,`
			`vir_bytes vir_addr, vir_bytes bytes)`
			`{`
			`/* Calculate the physical memory address for a given virtual address. */`
			`struct far_mem *fm;`

			`if (bytes <= 0) return( (phys_bytes) 0);`
			`if (seg < 0 \|\| seg >= NR_REMOTE_SEGS) return( (phys_bytes) 0);`

			`fm = &rp->p_priv->s_farmem[seg];`
			`if (! fm->in_use) return( (phys_bytes) 0);`
			`if (vir_addr + bytes > fm->mem_len) return( (phys_bytes) 0);`

			`return(fm->mem_phys + (phys_bytes) vir_addr);`
			`}`

			`/===========================================================================`
			`* umap_local *`
			`===========================================================================/`
			`PUBLIC phys_bytes umap_local(rp, seg, vir_addr, bytes)`
			`register struct proc rp; / pointer to proc table entry for process */`
			`int seg; /* T, D, or S segment */`
			`vir_bytes vir_addr; /* virtual address in bytes within the seg */`
			`vir_bytes bytes; /* # of bytes to be copied */`
			`{`
			`/* Calculate the physical memory address for a given virtual address. */`
			`vir_clicks vc; /* the virtual address in clicks */`
			`phys_bytes pa; /* intermediate variables as phys_bytes */`
			`phys_bytes seg_base;`

			`if (bytes <= 0) return( (phys_bytes) 0);`
			`if (vir_addr + bytes <= vir_addr) return 0; /* overflow */`
			`vc = (vir_addr + bytes - 1) >> CLICK_SHIFT; /* last click of data */`

			`if (seg != T)`
			`seg = (vc < rp->p_memmap[D].mem_vir + rp->p_memmap[D].mem_len ? D : S);`

			`if ((vir_addr>>CLICK_SHIFT) >= rp->p_memmap[seg].mem_vir +`
			`rp->p_memmap[seg].mem_len) return( (phys_bytes) 0 );`

			`if (vc >= rp->p_memmap[seg].mem_vir +`
			`rp->p_memmap[seg].mem_len) return( (phys_bytes) 0 );`

			`seg_base = (phys_bytes) rp->p_memmap[seg].mem_phys;`
			`seg_base = seg_base << CLICK_SHIFT; /* segment origin in bytes */`
			`pa = (phys_bytes) vir_addr;`
			`pa -= rp->p_memmap[seg].mem_vir << CLICK_SHIFT;`
			`return(seg_base + pa);`
			`}`