freebsd-skq/usr.bin/doscmd/xms.c

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/*-
* Copyright (c) 1997 Helmut Wirth <hfwirth@ping.at>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice immediately at the beginning of the file, witout modification,
* this list of conditions, and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* $Id$
*/
/*
* XMS memory manmagement
*
* To emulate DOS extended memory (EMM) we use an implementation of
* HIMEM.SYS driver capabitlities, according to the XMS 3.0 Spec.
* The actual memory allocated via XMS calls from DOS is allocated
* via malloc by the emulator. Maximum memory allocation is configureable.
*
* Credits to:
* The original author of this file, some parts are still here
* Linux dosemu programmers. I looked into their code.
*/
#include <sys/types.h>
#include <sys/param.h>
#include <sys/mman.h>
#include <unistd.h>
#include "doscmd.h"
#include "xms.h"
/* Extended memory handle management */
static XMS_handle xms_hand[NUM_HANDLES];
int num_free_handle = NUM_HANDLES;
/* This is planned to be selectable from .doscmdrc */
u_long xms_maxsize = DEFAULT_EMM_SIZE;
static u_long xms_free_mem;
static u_long xms_used_mem;
static u_char vec_grabbed;
/* Address entry for zero size allocated handles */
#define XMS_NULL_ALLOC 0xffffffff
/* High memory area (HMA) management */
static u_char HMA_allocated = 0;
static short HMA_a20 = -1;
static int HMA_fd_off, HMA_fd_on;
/* high memory mapfiles */
static char *memfile = "/tmp/doscmd.XXXXXX";
/* Upper memory block (UMB) management */
UMB_block *UMB_freelist = NULL;
UMB_block *UMB_alloclist = NULL;
/* Calls to emulator */
u_long xms_vector;
static u_char xms_trampoline[] = {
0xeb, /* JMP 5 */
0x03,
0x90, /* NOP */
0x90, /* NOP */
0x90, /* NOP */
0xf4, /* HLT */
0xcb, /* RETF */
};
/* Local prototypes */
static void xms_entry(regcontext_t *REGS);
static UMB_block *create_block(u_long addr, u_long size);
static void add_block(UMB_block **listp, UMB_block *blk);
static void merge_blocks();
/* Init the entire module */
void
xms_init(void)
{
int i;
/* Initialize handle table: xms_handle.addr == 0 means free */
bzero((void *)xms_hand, sizeof(XMS_handle) * NUM_HANDLES);
xms_free_mem = xms_maxsize;
xms_used_mem = 0;
vec_grabbed = 0;
HMA_allocated = 0;
/* Initialize UMB blocks */
/* 0xD0000 to 0xDffff */
add_block(&UMB_freelist, create_block(0xd0000, 64*1024));
/*XXX check for EMS emulation, when it is done! */
/* 0xE0000 to 0xEffff */
add_block(&UMB_freelist, create_block(0xe0000, 64*1024));
merge_blocks();
xms_vector = insert_generic_trampoline(
sizeof(xms_trampoline), xms_trampoline);
register_callback(xms_vector + 5, xms_entry, "xms");
}
/*
* UMB management routines: UMBs normally lie between 0xd0000 and
* 0xefff0 in VM86 memory space and are accessible for all DOS applictions.
* We could enable more space, but with the emulator we do not
* need many drivers, so I think 2 * 64kB will suffice. If EMS emulation
* exists, a 64kB segment (0xe0000 - 0xeffff for example) is needed for
* the EMS mapping, in this case we have 64kB UMB space. This is more than
* many PCs are able to do.
* This emulation does only the management for the memory, the memory
* is present and read/write/excutable for VM86 applications.
*/
/* Add a block to a list, maintain ascending start address order */
static void
add_block(UMB_block **listp, UMB_block *blk)
{
UMB_block *bp, *obp;
/* No blocks there, attach the new block to the head */
if (*listp == NULL) {
*listp = blk;
blk->next = NULL;
}
else {
/* Insert at the start */
bp = obp = *listp;
if (blk->addr < bp->addr) {
blk->next = *listp;
*listp = blk;
return;
}
/* Not at the start, insert into the list */
for (; bp != NULL; bp = bp->next) {
if (blk->addr > bp->addr) {
obp = bp;
continue;
}
else {
obp->next = blk;
blk->next = bp;
return;
}
}
/* Append to the end of the list */
obp->next = blk;
blk->next = NULL;
}
return;
}
/* Find a block with address addr in the alloc list */
static UMB_block *
find_allocated_block(u_long addr)
{
UMB_block *bp;
if (UMB_alloclist == NULL)
return NULL;
for (bp = UMB_alloclist; bp != NULL; bp = bp->next)
if (bp->addr == addr)
return bp;
return NULL;
}
/* Remove a block blk from a list, the block must exist on the list */
static void
remove_block(UMB_block **listp, UMB_block *blk)
{
UMB_block *bp;
if (*listp == NULL)
goto faterr;
if (*listp == blk) {
*listp = (*listp)->next;
return;
}
bp = *listp;
do {
if (bp->next == blk) {
bp->next = bp->next->next;
return;
}
bp = bp->next;
} while(bp != NULL);
faterr:
fatal("XMS: UMB remove_block did not find block\n");
}
/* Try to merge neighbouring blocks in the free list */
static void
merge_blocks()
{
UMB_block *bp;
u_long endaddr;
if (UMB_freelist == NULL)
return;
bp = UMB_freelist;
do {
endaddr = bp->addr + bp->size;
if (bp->next != NULL && endaddr == bp->next->addr) {
/* Merge the current and the next block */
UMB_block *mergebp = bp->next;
bp->size += mergebp->size;
bp->next = mergebp->next;
free(mergebp);
}
else
/* Goto next block */
bp = bp->next;
} while (bp != NULL);
}
/* Try to find a free block of size exactly siz */
static UMB_block *
find_exact_block(u_long siz)
{
UMB_block *bp;
if (UMB_freelist == NULL)
return NULL;
for (bp = UMB_freelist; bp != NULL; bp = bp->next)
if (bp->size == siz)
return bp;
return NULL;
}
/* Try to find a block with a size bigger than requested. If there is
* no such block, return the block with the biggest size. If there is
* no free block at all, return NULL
*/
static UMB_block *
find_block(u_long siz)
{
UMB_block *bp;
UMB_block *biggest = NULL;
if (UMB_freelist == NULL)
return NULL;
for (bp = UMB_freelist; bp != NULL; bp = bp->next) {
if (bp->size > siz)
return bp;
if (biggest == NULL) {
biggest = bp;
continue;
}
if (biggest->size < bp->size)
biggest = bp;
}
return biggest;
}
/* Create a block structure, memory is allocated. The structure lives
* until the block is merged into another block, then it is freed */
static UMB_block *
create_block(u_long addr, u_long size)
{
UMB_block *blk;
if ((blk = malloc(sizeof(UMB_block))) == NULL)
fatal ("XMS: Cannot allocate UMB structure\n");
blk->addr = addr;
blk->size = size;
blk->next = NULL;
return blk;
}
/*
* initHMA(): The first 64kB of memory are mapped from 1MB (0x100000)
* again to emulate the address wrap around of the 808x. The HMA area
* is a cheap trick, usable only with 80386 and higher. The 80[345..]86
* does not have this address wrap around. If more than 1MB is installed
* the processor can address more than 1MB: load 0xFFFF to the segment
* register and using the full offset of 0xffff the resulting highest
* address is (0xffff << 4) + 0xffff = 0x10ffef. Nearly 64kB are accessible
* from real or VM86 mode. The mmap calls emulate the address wrap by
* mapping the lowest 64kB the the first 64kB after the 1MB limit.
* In hardware this is achieved by setting and resetting the a20 bit,
* an ugly compatibility hack: The hardware simlpy clamps the address 20
* line of the processor to low and hence the wrap around is forced.
* This is switchable via the BIOS or via HIMEM.SYS and therefore the
* first 64kB over 1MB can be enabled or disabled at will by software.
* DOS uses this trick to load itself high, if the memory is present.
* We emulate this behaviour by mapping and unmapping the HMA area.
* (Linux has implemented this feature using shared memory (SHM) calls.)
*
* This routine is called from doscmd.c at startup. A20 is disabled after
* startup.
*/
void initHMA()
{
caddr_t add;
int mfd;
/*
* We need two files, one for the wrap around mapping and one
* for the HMA contents
*/
mfd = mkstemp(memfile);
if (mfd < 0) {
fprintf(stderr, "memfile: %s\n", strerror(errno));
fprintf(stderr, "High memory will not be mapped\n");
/* We need this for XMS services. If it fails, turn HMA off */
HMA_a20 = -1;
return;
}
unlink(memfile);
HMA_fd_off = squirrel_fd(mfd);
lseek(HMA_fd_off, 64 * 1024 - 1, 0);
write(HMA_fd_off, "", 1);
mfd = mkstemp(memfile);
if (mfd < 0) {
fprintf(stderr, "memfile: %s\n", strerror(errno));
fprintf(stderr, "High memory will not be mapped\n");
/* We need this for XMS services. If it fails, turn HMA off */
HMA_a20 = -1;
return;
}
unlink(memfile);
HMA_fd_on = squirrel_fd(mfd);
lseek(HMA_fd_on, 64 * 1024 - 1, 0);
write(HMA_fd_on, "", 1);
if (mmap((caddr_t)0x000000, 64 * 1024,
PROT_EXEC | PROT_READ | PROT_WRITE,
MAP_FILE | MAP_FIXED | MAP_INHERIT | MAP_SHARED,
HMA_fd_off, 0) < 0) {
perror("Error mapping HMA, HMA disabled: ");
HMA_a20 = -1;
close(HMA_fd_off);
close(HMA_fd_on);
return;
}
if (mmap((caddr_t)0x100000, 64 * 1024,
PROT_EXEC | PROT_READ | PROT_WRITE,
MAP_FILE | MAP_FIXED | MAP_INHERIT | MAP_SHARED,
HMA_fd_off, 0) < 0) {
perror("Error mapping HMA, HMA disabled: ");
HMA_a20 = -1;
close(HMA_fd_off);
close(HMA_fd_on);
return;
}
HMA_a20 = 0;
}
/* Enable the a20 "address line" by unmapping the 64kB over 1MB */
static void enable_a20()
{
if (HMA_a20 < 0)
return;
/* Unmap the wrap around portion (fd = HMA_fd_off) */
/* XXX Not sure about this: Should I unmap first, then map new or
* does it suffice to map new "over' the existing mapping ? Both
* works (define to #if 0 next line and some lines below to try.
*/
#if 1
if (munmap((caddr_t)0x100000, 64 * 1024) < 0) {
fatal("HMA unmapping error: %s\nCannot recover\n", strerror(errno));
}
#endif
/* Map memory for the HMA with fd = HMA_fd_on */
if (mmap((caddr_t)0x100000, 64 * 1024,
PROT_EXEC | PROT_READ | PROT_WRITE,
MAP_FILE | MAP_FIXED | MAP_INHERIT | MAP_SHARED,
HMA_fd_on, 0) < 0) {
fatal("HMA mapping error: %s\nCannot recover\n", strerror(errno));
}
}
/* Disable the a20 "address line" by mapping the 64kB over 1MB again */
static void disable_a20()
{
if (HMA_a20 < 0)
return;
#if 1
/* Unmap the HMA (fd = HMA_fd_on) */
if (munmap((caddr_t)0x100000, 64 * 1024) < 0) {
fatal("HMA unmapping error: %s\nCannot recover\n", strerror(errno));
}
#endif
/* Remap the wrap around area */
if (mmap((caddr_t)0x100000, 64 * 1024,
PROT_EXEC | PROT_READ | PROT_WRITE,
MAP_FILE | MAP_FIXED | MAP_INHERIT | MAP_SHARED,
HMA_fd_off, 0) < 0) {
fatal("HMA mapping error: %s\nCannot recover\n", strerror(errno));
}
}
/*
* This handles calls to int15 function 88: BIOS extended memory
* request. XMS spec says: "In order to maintain compatibility with existing
* device drivers, DOS XMS drivers must not hook INT 15h until the first
* non-Version Number call to the control function is made."
*/
void
get_raw_extmemory_info(regcontext_t *REGS)
{
if (vec_grabbed)
R_AX = 0x0;
else
R_AX = xms_maxsize / 1024;
return;
}
/* Handle management routine: Find next free handle */
static int
get_free_handle()
{
int i;
/* Linear search, there are only a few handles */
for (i = 0; i < NUM_HANDLES; i++) {
if (xms_hand[i].addr == 0)
return i + 1;
}
return 0;
}
/* Installation check */
int
int2f_43(regcontext_t *REGS)
{
switch (R_AL) {
case 0x00: /* installation check */
R_AL = 0x80;
break;
case 0x10: /* get handler address */
N_PUTVEC(R_ES, R_BX, xms_vector);
break;
default:
return (0);
}
return (1);
}
/* Main call entry point for the XMS handler from DOS */
static void
xms_entry(regcontext_t *REGS)
{
if (R_AH != 0) {
if (HMA_a20 < 0) { /* This feature is disabled */
R_AX = 0x0;
R_BL = XMS_HMA_NOT_MANAGED;
return;
}
vec_grabbed = 1;
}
switch (R_AH) {
case XMS_GET_VERSION:
debug(D_XMS, "XMS: Get Version\n");
R_AX = XMS_VERSION; /* 3.0 */
R_BX = XMS_REVISION; /* internal revision 0 */
R_DX = (HMA_a20 < 0) ? 0x0000 : 0x0001;
break;
/*
* XXX Not exact! Spec says compare size to a HMAMIN parameter and
* refuse HMA, if space is too small. With MSDOS 5.0 and higher DOS
* itself uses the HMA (DOS=HIGH), so I think we can safely ignore
* that.
*/
case XMS_ALLOCATE_HIGH_MEMORY:
debug(D_XMS, "XMS: Allocate HMA\n");
if (HMA_allocated) {
R_AX = 0x0;
R_BL = XMS_HMA_ALREADY_USED;
}
else {
HMA_allocated = 1;
R_AX = 0x1;
R_BL = XMS_SUCCESS;
}
break;
case XMS_FREE_HIGH_MEMORY:
debug(D_XMS, "XMS: Free HMA\n");
if (HMA_allocated) {
HMA_allocated = 0;
R_AX = 0x1;
R_BL = XMS_SUCCESS;
}
else {
R_AX = 0x0;
R_BL = XMS_HMA_NOT_ALLOCATED;
}
break;
case XMS_GLOBAL_ENABLE_A20:
debug(D_XMS, "XMS: Global enable A20\n");
if (HMA_a20 == 0)
enable_a20();
HMA_a20 = 1;
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
case XMS_GLOBAL_DISABLE_A20:
debug(D_XMS, "XMS: Global disable A20\n");
if (HMA_a20 != 0)
disable_a20();
HMA_a20 = 0;
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
/*
* This is an accumulating call. Every call increments HMA_a20.
* Caller must use LOCAL_DISBALE_A20 once for each previous call
* to LOCAL_ENABLE_A20.
*/
case XMS_LOCAL_ENABLE_A20:
debug(D_XMS, "XMS: Local enable A20\n");
HMA_a20++;
if (HMA_a20 == 1)
enable_a20();
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
case XMS_LOCAL_DISABLE_A20:
debug(D_XMS, "XMS: Local disable A20\n");
if (HMA_a20 > 0)
HMA_a20--;
if (HMA_a20 == 0)
disable_a20();
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
case XMS_QUERY_A20:
/*
* Disabled because DOS permanently scans this, to avoid endless output.
*/
#if 0
debug(D_XMS, "XMS: Query A20\n"); */
#endif
R_AX = (HMA_a20 > 0) ? 0x1 : 0x0;
R_BL = XMS_SUCCESS;
break;
case XMS_QUERY_FREE_EXTENDED_MEMORY:
R_AX = R_DX = xms_free_mem / 1024;
R_BL = XMS_SUCCESS;
debug(D_XMS, "XMS: Query free EMM: Returned %dkB\n", R_AX);
break;
case XMS_ALLOCATE_EXTENDED_MEMORY:
{
size_t req_siz;
int hindx, hnum;
void *mem;
debug(D_XMS, "XMS: Allocate EMM: ");
/* Enough handles ? */
if ((hnum = get_free_handle()) == 0) {
R_AX = 0x00;
R_BL = XMS_OUT_OF_HANDLES;
debug(D_XMS, " Out of handles\n");
break;
}
hindx = hnum - 1;
req_siz = R_DX * 1024;
/* Enough memory ? */
if (req_siz > xms_free_mem) {
R_AX = 0x00;
R_BL = XMS_FULL;
debug(D_XMS, " No memory left\n");
break;
}
xms_hand[hindx].size = req_siz;
xms_hand[hindx].num_locks = 0;
/* XXX
* Not sure about that: Is it possible to reserve a handle
* but with no memory attached ? XMS specs are unclear on
* that point. Linux implementation does it this way.
*/
if (req_siz == 0)
/* This handle is reserved, but has size 0 and no address */
xms_hand[hindx].addr = XMS_NULL_ALLOC;
else {
if ((mem = malloc(req_siz)) == NULL)
fatal("XMS: Cannot malloc !");
xms_hand[hindx].addr = (u_long)mem;
}
xms_free_mem -= req_siz;
xms_used_mem += req_siz;
num_free_handle--;
R_AX = 0x1;
R_DX = hnum;
R_BL = XMS_SUCCESS;
debug(D_XMS, " Allocated %d kB, handle %d\n",
req_siz / 1024, hnum);
break;
}
case XMS_FREE_EXTENDED_MEMORY:
{
int hnum, hindx;
debug(D_XMS, "XMS: Free EMM: ");
hnum = R_DX;
if (hnum > NUM_HANDLES || hnum == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
debug(D_XMS, " Invalid handle\n");
break;
}
hindx = hnum - 1;
if (xms_hand[hindx].addr == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
debug(D_XMS, " Invalid handle\n");
}
else if (xms_hand[hindx].num_locks > 0) {
R_AX = 0x0;
R_BL = XMS_BLOCK_IS_LOCKED;
debug(D_XMS, " Is locked\n");
}
else {
if (xms_hand[hindx].addr != XMS_NULL_ALLOC) {
free((void *)xms_hand[hindx].addr);
xms_free_mem += xms_hand[hindx].size;
xms_used_mem -= xms_hand[hindx].size;
}
xms_hand[hindx].addr = 0;
xms_hand[hindx].size = 0;
xms_hand[hindx].num_locks = 0;
num_free_handle++;
debug(D_XMS, " Success for handle %d\n", hnum);
R_AX = 0x1;
R_BL = XMS_SUCCESS;
}
break;
}
case XMS_MOVE_EXTENDED_MEMORY_BLOCK:
{
u_long srcptr, dstptr;
u_long srcoffs, dstoffs;
int srcidx, dstidx;
const struct EMM *eptr;
int n;
debug(D_XMS, "XMS: Move EMM block: ");
eptr = (struct EMM *)N_GETPTR(R_DS, R_SI);
/* Sanity check: Don't allow eptr pointing to emulator data */
if (((u_long)eptr + sizeof(struct EMM)) >= 0x100000) {
R_AX = 0x0;
R_BL = XMS_GENERAL_ERROR;
debug(D_XMS, " Offset to EMM structure wrong\n");
break;
}
/* Validate handles and offsets */
if (eptr->src_handle > NUM_HANDLES) {
R_AX = 0x0;
R_BL = XMS_INVALID_SOURCE_HANDLE;
debug(D_XMS, " Invalid handle\n");
break;
}
if (eptr->dst_handle > NUM_HANDLES) {
R_AX = 0x0;
R_BL = XMS_INVALID_DESTINATION_HANDLE;
debug(D_XMS, " Invalid handle\n");
break;
}
srcidx = eptr->src_handle - 1;
dstidx = eptr->dst_handle - 1;
srcoffs = eptr->src_offset;
dstoffs = eptr->dst_offset;
n = eptr->nbytes;
/* Lenght must be even, see XMS spec */
if (n & 1) {
R_AX = 0x0;
R_BL = XMS_INVALID_LENGTH;
debug(D_XMS, " Length not even\n");
break;
}
if (eptr->src_handle != 0) {
srcptr = xms_hand[srcidx].addr;
if (srcptr == 0 || srcptr == XMS_NULL_ALLOC) {
R_AX = 0x0;
R_BL = XMS_INVALID_SOURCE_HANDLE;
debug(D_XMS, " Invalid source handle\n");
break;
}
if ((srcoffs + n) > xms_hand[srcidx].size) {
R_AX = 0x0;
R_BL = XMS_INVALID_SOURCE_OFFSET;
debug(D_XMS, " Invalid source offset\n");
break;
}
srcptr += srcoffs;
}
else {
srcptr = VECPTR(srcoffs);
/* Sanity check: Don't allow srcptr pointing to
* emulator data above 1M
*/
if ((srcptr + n) >= 0x100000) {
R_AX = 0x0;
R_BL = XMS_GENERAL_ERROR;
debug(D_XMS, " Source segment invalid\n");
break;
}
}
if (eptr->dst_handle != 0) {
dstptr = xms_hand[dstidx].addr;
if (dstptr == NULL || dstptr == XMS_NULL_ALLOC) {
R_AX = 0x0;
R_BL = XMS_INVALID_DESTINATION_HANDLE;
debug(D_XMS, " Invalid dest handle\n");
break;
}
if ((dstoffs + n) > xms_hand[dstidx].size) {
R_AX = 0x0;
R_BL = XMS_INVALID_DESTINATION_OFFSET;
debug(D_XMS, " Invalid dest offset\n");
break;
}
dstptr += dstoffs;
}
else {
dstptr = VECPTR(dstoffs);
/* Sanity check: Don't allow dstptr pointing to
* emulator data above 1M
*/
if ((dstptr + n) >= 0x100000) {
R_AX = 0x0;
R_BL = XMS_GENERAL_ERROR;
debug(D_XMS, " Dest segment invalid\n");
break;
}
}
memmove((void *)dstptr, (void *)srcptr, n);
debug(D_XMS, "Moved from %08x to %08x, %04x bytes\n",
srcptr, dstptr, n);
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
}
case XMS_LOCK_EXTENDED_MEMORY_BLOCK:
{
int hnum,hindx;
debug(D_XMS, "XMS: Lock EMM block\n");
hnum = R_DX;
if (hnum > NUM_HANDLES || hnum == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
hindx = hnum - 1;
if (xms_hand[hindx].addr == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
if (xms_hand[hindx].num_locks == 255) {
R_AX = 0x0;
R_BL = XMS_BLOCK_LOCKCOUNT_OVERFLOW;
break;
}
xms_hand[hindx].num_locks++;
R_AX = 0x1;
/*
* The 32 bit "physical" address is returned here. I hope
* the solution to simply return the linear address of the
* malloced area is good enough. Most DOS programs won't
* need this anyway. It could be important for future DPMI.
*/
R_BX = xms_hand[hindx].addr & 0xffff;
R_DX = (xms_hand[hindx].addr & 0xffff0000) >> 16;
break;
}
case XMS_UNLOCK_EXTENDED_MEMORY_BLOCK:
{
int hnum,hindx;
debug(D_XMS, "XMS: Unlock EMM block\n");
hnum = R_DX;
if (hnum > NUM_HANDLES || hnum == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
hindx = hnum - 1;
if (xms_hand[hindx].addr == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
if (xms_hand[hindx].num_locks == 0) {
R_AX = 0x0;
R_BL = XMS_BLOCK_NOT_LOCKED;
break;
}
xms_hand[hindx].num_locks--;
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
}
case XMS_GET_EMB_HANDLE_INFORMATION:
{
int hnum,hindx;
debug(D_XMS, "XMS: Get handle information: DX=%04x\n, R_DX");
hnum = R_DX;
if (hnum > NUM_HANDLES || hnum == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
hindx = hnum - 1;
if (xms_hand[hindx].addr == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
R_AX = 0x1;
R_BH = xms_hand[hindx].num_locks;
R_BL = num_free_handle;
R_DX = xms_hand[hindx].size / 1024;
break;
}
case XMS_RESIZE_EXTENDED_MEMORY_BLOCK:
{
int hnum,hindx;
size_t req_siz;
long sizediff;
void *mem;
debug(D_XMS, "XMS: Resize EMM block\n");
hnum = R_DX;
req_siz = R_BX * 1024;
if (hnum > NUM_HANDLES || hnum == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
hindx = hnum - 1;
if (xms_hand[hindx].addr == 0) {
R_AX = 0x0;
R_BL = XMS_INVALID_HANDLE;
break;
}
if (xms_hand[hindx].num_locks > 0) {
R_AX = 0x0;
R_BL = XMS_BLOCK_IS_LOCKED;
break;
}
sizediff = req_siz - xms_hand[hindx].size;
if (sizediff > 0) {
if ((sizediff + xms_used_mem) > xms_maxsize) {
R_AX = 0x0;
R_BL = XMS_FULL;
break;
}
}
if (sizediff == 0) { /* Never trust DOS programs */
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
}
xms_used_mem += sizediff;
xms_free_mem -= sizediff;
if (xms_hand[hindx].addr == XMS_NULL_ALLOC) {
if ((mem = malloc(req_siz)) == NULL)
fatal("XMS: Cannot malloc !");
xms_hand[hindx].addr = (u_long)mem;
xms_hand[hindx].size = req_siz;
}
else {
if ((mem = realloc((void *)xms_hand[hindx].addr,req_siz))
== NULL)
fatal("XMS: Cannot realloc !");
xms_hand[hindx].addr = (u_long)mem;
xms_hand[hindx].size = req_siz;
}
R_AX = 0x1;
R_BL = XMS_SUCCESS;
break;
}
case XMS_ALLOCATE_UMB:
{
u_long req_siz;
UMB_block *bp;
debug(D_XMS, "XMS: Allocate UMB: DX=%04x\n", R_DX);
req_siz = R_DX * 16;
/* Some programs try to allocate 0 bytes. XMS spec says
* nothing about this. So the driver grants the request
* but it rounds up to the next paragraph size (1) and
* returns this amount of memory
*/
if (req_siz == 0)
req_siz = 0x10;
/* First try to find an exact fit */
if ((bp = find_exact_block(req_siz)) != NULL) {
/* Found ! Move block from free list to alloc list */
remove_block(&UMB_freelist, bp);
add_block(&UMB_alloclist, bp);
R_AX = 0x1;
R_DX = req_siz >> 4;
R_BX = bp->addr >> 4;
break;
}
/* Try to find a block big enough */
bp = find_block(req_siz);
if (bp == NULL) {
R_AX = 0x0;
R_BL = XMS_NO_UMBS_AVAILABLE;
R_DX = 0x0;
}
else if (bp->size < req_siz) {
R_AX = 0x0;
R_BL = XMS_REQUESTED_UMB_TOO_BIG;
R_DX = bp->size / 16;
}
else {
UMB_block *newbp;
/* Found a block large enough. Split it into the size
* we need, rest remains on the free list. New block
* goes to the alloc list
*/
newbp = create_block(bp->addr, req_siz);
bp->addr += req_siz;
bp->size -= req_siz;
add_block(&UMB_alloclist, newbp);
R_AX = 0x1;
R_BX = newbp->addr >> 4;
R_DX = req_siz / 16;
}
break;
}
case XMS_DEALLOCATE_UMB:
{
u_long req_addr;
UMB_block *blk;
debug(D_XMS, "XMS: Deallocate UMB: DX=%04x\n", R_DX);
req_addr = R_DX << 4;
if ((blk = find_allocated_block(req_addr)) == NULL) {
R_AX = 0x0;
R_BL = XMS_INVALID_UMB_SEGMENT;
}
else {
/* Move the block from the alloc list to the free list
* and try to do garbage collection
*/
remove_block(&UMB_alloclist, blk);
add_block(&UMB_freelist, blk);
merge_blocks();
R_AX = 0x1;
R_BL = XMS_SUCCESS;
}
break;
}
/*
* If the option DOS=UMB is enabled, DOS grabs the entire UMB
* at boot time. In any other case this is used to load resident
* utilities. I don't think this function is neccesary here.
*/
case XMS_REALLOCATE_UMB:
debug(D_XMS, "XMS: Reallocate UMB\n");
R_AX = 0x0;
R_BL = XMS_NOT_IMPLEMENTED;
break;
/* These are the same as the above functions, but they use 32 bit
* registers (i.e. EDX instead of DX). This is for allocations of
* more than 64MB. I think this will hardly be used in the emulator
* It seems to work without them, but the functions are in the XMS 3.0
* spec. If something breaks because they are not here, I can implement
* them
*/
case XMS_QUERY_FREE_EXTENDED_MEMORY_LARGE:
case XMS_ALLOCATE_EXTENDED_MEMORY_LARGE:
case XMS_FREE_EXTENDED_MEMORY_LARGE:
debug(D_XMS, "XMS: 8x function called, not implemented\n");
R_AX = 0x0;
R_BL = XMS_NOT_IMPLEMENTED;
break;
default:
debug(D_ALWAYS, "XMS: Unimplemented function %02x, \n", R_AH);
R_AX = 0;
R_BL = XMS_NOT_IMPLEMENTED;
break;
}
}