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qemu/linux-user/vm86.c

292 lines
10 KiB
C

/*
* vm86 linux syscall support
*
* Copyright (c) 2003 Fabrice Bellard
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include "qemu/osdep.h"
#include "qemu.h"
#include "user-internals.h"
//#define DEBUG_VM86
#ifdef DEBUG_VM86
# define LOG_VM86(...) qemu_log(__VA_ARGS__);
#else
# define LOG_VM86(...) do { } while (0)
#endif
#define set_flags(X,new,mask) \
((X) = ((X) & ~(mask)) | ((new) & (mask)))
#define SAFE_MASK (0xDD5)
#define RETURN_MASK (0xDFF)
static inline int is_revectored(int nr, struct target_revectored_struct *bitmap)
{
return (((uint8_t *)bitmap)[nr >> 3] >> (nr & 7)) & 1;
}
static inline void vm_putw(CPUX86State *env, uint32_t segptr,
unsigned int reg16, unsigned int val)
{
cpu_stw_data(env, segptr + (reg16 & 0xffff), val);
}
void save_v86_state(CPUX86State *env)
{
CPUState *cs = env_cpu(env);
TaskState *ts = get_task_state(cs);
struct target_vm86plus_struct * target_v86;
if (!lock_user_struct(VERIFY_WRITE, target_v86, ts->target_v86, 0))
/* FIXME - should return an error */
return;
/* put the VM86 registers in the userspace register structure */
target_v86->regs.eax = tswap32(env->regs[R_EAX]);
target_v86->regs.ebx = tswap32(env->regs[R_EBX]);
target_v86->regs.ecx = tswap32(env->regs[R_ECX]);
target_v86->regs.edx = tswap32(env->regs[R_EDX]);
target_v86->regs.esi = tswap32(env->regs[R_ESI]);
target_v86->regs.edi = tswap32(env->regs[R_EDI]);
target_v86->regs.ebp = tswap32(env->regs[R_EBP]);
target_v86->regs.esp = tswap32(env->regs[R_ESP]);
target_v86->regs.eip = tswap32(env->eip);
target_v86->regs.cs = tswap16(env->segs[R_CS].selector);
target_v86->regs.ss = tswap16(env->segs[R_SS].selector);
target_v86->regs.ds = tswap16(env->segs[R_DS].selector);
target_v86->regs.es = tswap16(env->segs[R_ES].selector);
target_v86->regs.fs = tswap16(env->segs[R_FS].selector);
target_v86->regs.gs = tswap16(env->segs[R_GS].selector);
set_flags(env->eflags, ts->v86flags, VIF_MASK | ts->v86mask);
target_v86->regs.eflags = tswap32(env->eflags);
unlock_user_struct(target_v86, ts->target_v86, 1);
LOG_VM86("save_v86_state: eflags=%08x cs:ip=%04x:%04x\n",
env->eflags, env->segs[R_CS].selector, env->eip);
/* restore 32 bit registers */
env->regs[R_EAX] = ts->vm86_saved_regs.eax;
env->regs[R_EBX] = ts->vm86_saved_regs.ebx;
env->regs[R_ECX] = ts->vm86_saved_regs.ecx;
env->regs[R_EDX] = ts->vm86_saved_regs.edx;
env->regs[R_ESI] = ts->vm86_saved_regs.esi;
env->regs[R_EDI] = ts->vm86_saved_regs.edi;
env->regs[R_EBP] = ts->vm86_saved_regs.ebp;
env->regs[R_ESP] = ts->vm86_saved_regs.esp;
env->eflags = ts->vm86_saved_regs.eflags;
env->eip = ts->vm86_saved_regs.eip;
cpu_x86_load_seg(env, R_CS, ts->vm86_saved_regs.cs);
cpu_x86_load_seg(env, R_SS, ts->vm86_saved_regs.ss);
cpu_x86_load_seg(env, R_DS, ts->vm86_saved_regs.ds);
cpu_x86_load_seg(env, R_ES, ts->vm86_saved_regs.es);
cpu_x86_load_seg(env, R_FS, ts->vm86_saved_regs.fs);
cpu_x86_load_seg(env, R_GS, ts->vm86_saved_regs.gs);
}
/* return from vm86 mode to 32 bit. The vm86() syscall will return
'retval' */
static inline void return_to_32bit(CPUX86State *env, int retval)
{
LOG_VM86("return_to_32bit: ret=0x%x\n", retval);
save_v86_state(env);
env->regs[R_EAX] = retval;
}
static inline void clear_IF(CPUX86State *env)
{
CPUState *cs = env_cpu(env);
TaskState *ts = get_task_state(cs);
ts->v86flags &= ~VIF_MASK;
}
static inline void clear_TF(CPUX86State *env)
{
env->eflags &= ~TF_MASK;
}
static inline void clear_AC(CPUX86State *env)
{
env->eflags &= ~AC_MASK;
}
static inline unsigned int get_vflags(CPUX86State *env)
{
CPUState *cs = env_cpu(env);
TaskState *ts = get_task_state(cs);
unsigned int flags;
flags = env->eflags & RETURN_MASK;
if (ts->v86flags & VIF_MASK)
flags |= IF_MASK;
flags |= IOPL_MASK;
return flags | (ts->v86flags & ts->v86mask);
}
#define ADD16(reg, val) reg = (reg & ~0xffff) | ((reg + (val)) & 0xffff)
/* handle VM86 interrupt (NOTE: the CPU core currently does not
support TSS interrupt revectoring, so this code is always executed) */
static void do_int(CPUX86State *env, int intno)
{
CPUState *cs = env_cpu(env);
TaskState *ts = get_task_state(cs);
uint32_t int_addr, segoffs, ssp;
unsigned int sp;
if (env->segs[R_CS].selector == TARGET_BIOSSEG)
goto cannot_handle;
if (is_revectored(intno, &ts->vm86plus.int_revectored))
goto cannot_handle;
if (intno == 0x21 && is_revectored((env->regs[R_EAX] >> 8) & 0xff,
&ts->vm86plus.int21_revectored))
goto cannot_handle;
int_addr = (intno << 2);
segoffs = cpu_ldl_data(env, int_addr);
if ((segoffs >> 16) == TARGET_BIOSSEG)
goto cannot_handle;
LOG_VM86("VM86: emulating int 0x%x. CS:IP=%04x:%04x\n",
intno, segoffs >> 16, segoffs & 0xffff);
/* save old state */
ssp = env->segs[R_SS].selector << 4;
sp = env->regs[R_ESP] & 0xffff;
vm_putw(env, ssp, sp - 2, get_vflags(env));
vm_putw(env, ssp, sp - 4, env->segs[R_CS].selector);
vm_putw(env, ssp, sp - 6, env->eip);
ADD16(env->regs[R_ESP], -6);
/* goto interrupt handler */
env->eip = segoffs & 0xffff;
cpu_x86_load_seg(env, R_CS, segoffs >> 16);
clear_TF(env);
clear_IF(env);
clear_AC(env);
return;
cannot_handle:
LOG_VM86("VM86: return to 32 bits int 0x%x\n", intno);
return_to_32bit(env, TARGET_VM86_INTx | (intno << 8));
}
void handle_vm86_trap(CPUX86State *env, int trapno)
{
if (trapno == 1 || trapno == 3) {
return_to_32bit(env, TARGET_VM86_TRAP + (trapno << 8));
} else {
do_int(env, trapno);
}
}
int do_vm86(CPUX86State *env, long subfunction, abi_ulong vm86_addr)
{
CPUState *cs = env_cpu(env);
TaskState *ts = get_task_state(cs);
struct target_vm86plus_struct * target_v86;
int ret;
switch (subfunction) {
case TARGET_VM86_REQUEST_IRQ:
case TARGET_VM86_FREE_IRQ:
case TARGET_VM86_GET_IRQ_BITS:
case TARGET_VM86_GET_AND_RESET_IRQ:
qemu_log_mask(LOG_UNIMP, "qemu: unsupported vm86 subfunction (%ld)\n",
subfunction);
ret = -TARGET_EINVAL;
goto out;
case TARGET_VM86_PLUS_INSTALL_CHECK:
/* NOTE: on old vm86 stuff this will return the error
from verify_area(), because the subfunction is
interpreted as (invalid) address to vm86_struct.
So the installation check works.
*/
ret = 0;
goto out;
}
/* save current CPU regs */
ts->vm86_saved_regs.eax = 0; /* default vm86 syscall return code */
ts->vm86_saved_regs.ebx = env->regs[R_EBX];
ts->vm86_saved_regs.ecx = env->regs[R_ECX];
ts->vm86_saved_regs.edx = env->regs[R_EDX];
ts->vm86_saved_regs.esi = env->regs[R_ESI];
ts->vm86_saved_regs.edi = env->regs[R_EDI];
ts->vm86_saved_regs.ebp = env->regs[R_EBP];
ts->vm86_saved_regs.esp = env->regs[R_ESP];
ts->vm86_saved_regs.eflags = env->eflags;
ts->vm86_saved_regs.eip = env->eip;
ts->vm86_saved_regs.cs = env->segs[R_CS].selector;
ts->vm86_saved_regs.ss = env->segs[R_SS].selector;
ts->vm86_saved_regs.ds = env->segs[R_DS].selector;
ts->vm86_saved_regs.es = env->segs[R_ES].selector;
ts->vm86_saved_regs.fs = env->segs[R_FS].selector;
ts->vm86_saved_regs.gs = env->segs[R_GS].selector;
ts->target_v86 = vm86_addr;
if (!lock_user_struct(VERIFY_READ, target_v86, vm86_addr, 1))
return -TARGET_EFAULT;
/* build vm86 CPU state */
ts->v86flags = tswap32(target_v86->regs.eflags);
env->eflags = (env->eflags & ~SAFE_MASK) |
(tswap32(target_v86->regs.eflags) & SAFE_MASK) | VM_MASK;
ts->vm86plus.cpu_type = tswapal(target_v86->cpu_type);
switch (ts->vm86plus.cpu_type) {
case TARGET_CPU_286:
ts->v86mask = 0;
break;
case TARGET_CPU_386:
ts->v86mask = NT_MASK | IOPL_MASK;
break;
case TARGET_CPU_486:
ts->v86mask = AC_MASK | NT_MASK | IOPL_MASK;
break;
default:
ts->v86mask = ID_MASK | AC_MASK | NT_MASK | IOPL_MASK;
break;
}
env->regs[R_EBX] = tswap32(target_v86->regs.ebx);
env->regs[R_ECX] = tswap32(target_v86->regs.ecx);
env->regs[R_EDX] = tswap32(target_v86->regs.edx);
env->regs[R_ESI] = tswap32(target_v86->regs.esi);
env->regs[R_EDI] = tswap32(target_v86->regs.edi);
env->regs[R_EBP] = tswap32(target_v86->regs.ebp);
env->regs[R_ESP] = tswap32(target_v86->regs.esp);
env->eip = tswap32(target_v86->regs.eip);
cpu_x86_load_seg(env, R_CS, tswap16(target_v86->regs.cs));
cpu_x86_load_seg(env, R_SS, tswap16(target_v86->regs.ss));
cpu_x86_load_seg(env, R_DS, tswap16(target_v86->regs.ds));
cpu_x86_load_seg(env, R_ES, tswap16(target_v86->regs.es));
cpu_x86_load_seg(env, R_FS, tswap16(target_v86->regs.fs));
cpu_x86_load_seg(env, R_GS, tswap16(target_v86->regs.gs));
ret = tswap32(target_v86->regs.eax); /* eax will be restored at
the end of the syscall */
memcpy(&ts->vm86plus.int_revectored,
&target_v86->int_revectored, 32);
memcpy(&ts->vm86plus.int21_revectored,
&target_v86->int21_revectored, 32);
ts->vm86plus.vm86plus.flags = tswapal(target_v86->vm86plus.flags);
memcpy(&ts->vm86plus.vm86plus.vm86dbg_intxxtab,
target_v86->vm86plus.vm86dbg_intxxtab, 32);
unlock_user_struct(target_v86, vm86_addr, 0);
LOG_VM86("do_vm86: cs:ip=%04x:%04x\n",
env->segs[R_CS].selector, env->eip);
/* now the virtual CPU is ready for vm86 execution ! */
out:
return ret;
}