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/*
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* QEMU PC System Emulator
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*
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* Copyright ( c ) 2003 Fabrice Bellard
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*
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* Permission is hereby granted , free of charge , to any person obtaining a copy
* of this software and associated documentation files ( the " Software " ) , to deal
* in the Software without restriction , including without limitation the rights
* to use , copy , modify , merge , publish , distribute , sublicense , and / or sell
* copies of the Software , and to permit persons to whom the Software is
* furnished to do so , subject to the following conditions :
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software .
*
* THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
* IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
* LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM ,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE .
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*/
# include <stdlib.h>
# include <stdio.h>
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# include <stdarg.h>
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# include <string.h>
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# include <ctype.h>
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# include <getopt.h>
# include <inttypes.h>
# include <unistd.h>
# include <sys/mman.h>
# include <fcntl.h>
# include <signal.h>
# include <time.h>
# include <sys/time.h>
# include <malloc.h>
# include <termios.h>
# include <sys/poll.h>
# include <errno.h>
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# include <sys/wait.h>
# include <sys/ioctl.h>
# include <sys/socket.h>
# include <linux/if.h>
# include <linux/if_tun.h>
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# include "cpu.h"
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# include "disas.h"
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# include "thunk.h"
# include "vl.h"
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# define DEFAULT_NETWORK_SCRIPT " / etc / qemu-ifup"
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# define BIOS_FILENAME "bios.bin"
# define VGABIOS_FILENAME "vgabios.bin"
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//#define DEBUG_UNUSED_IOPORT
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//#define DEBUG_IRQ_LATENCY
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/* output Bochs bios info messages */
//#define DEBUG_BIOS
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//#define DEBUG_CMOS
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/* debug PIC */
//#define DEBUG_PIC
/* debug NE2000 card */
//#define DEBUG_NE2000
/* debug PC keyboard */
//#define DEBUG_KBD
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/* debug PC keyboard : only mouse */
//#define DEBUG_MOUSE
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//#define DEBUG_SERIAL
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# if !defined(CONFIG_SOFTMMU)
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# define PHYS_RAM_MAX_SIZE (256 * 1024 * 1024)
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# else
# define PHYS_RAM_MAX_SIZE (2047 * 1024 * 1024)
# endif
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# if defined (TARGET_I386)
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# define KERNEL_LOAD_ADDR 0x00100000
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# elif defined (TARGET_PPC)
//#define USE_OPEN_FIRMWARE
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# if !defined (USE_OPEN_FIRMWARE)
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# define KERNEL_LOAD_ADDR 0x01000000
# define KERNEL_STACK_ADDR 0x01200000
# else
# define KERNEL_LOAD_ADDR 0x00000000
# define KERNEL_STACK_ADDR 0x00400000
# endif
# endif
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# define INITRD_LOAD_ADDR 0x00400000
# define KERNEL_PARAMS_ADDR 0x00090000
# define KERNEL_CMDLINE_ADDR 0x00099000
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# define GUI_REFRESH_INTERVAL 30
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/* XXX: use a two level table to limit memory usage */
# define MAX_IOPORTS 65536
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static const char * bios_dir = CONFIG_QEMU_SHAREDIR ;
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char phys_ram_file [ 1024 ] ;
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CPUState * global_env ;
CPUState * cpu_single_env ;
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IOPortReadFunc * ioport_read_table [ 3 ] [ MAX_IOPORTS ] ;
IOPortWriteFunc * ioport_write_table [ 3 ] [ MAX_IOPORTS ] ;
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BlockDriverState * bs_table [ MAX_DISKS ] , * fd_table [ MAX_FD ] ;
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int vga_ram_size ;
static DisplayState display_state ;
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int nographic ;
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int term_inited ;
int64_t ticks_per_sec ;
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int boot_device = ' c ' ;
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static int ram_size ;
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/***********************************************************/
/* x86 io ports */
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uint32_t default_ioport_readb ( CPUState * env , uint32_t address )
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{
# ifdef DEBUG_UNUSED_IOPORT
fprintf ( stderr , " inb: port=0x%04x \n " , address ) ;
# endif
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return 0xff ;
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}
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void default_ioport_writeb ( CPUState * env , uint32_t address , uint32_t data )
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{
# ifdef DEBUG_UNUSED_IOPORT
fprintf ( stderr , " outb: port=0x%04x data=0x%02x \n " , address , data ) ;
# endif
}
/* default is to make two byte accesses */
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uint32_t default_ioport_readw ( CPUState * env , uint32_t address )
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{
uint32_t data ;
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data = ioport_read_table [ 0 ] [ address & ( MAX_IOPORTS - 1 ) ] ( env , address ) ;
data | = ioport_read_table [ 0 ] [ ( address + 1 ) & ( MAX_IOPORTS - 1 ) ] ( env , address + 1 ) < < 8 ;
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return data ;
}
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void default_ioport_writew ( CPUState * env , uint32_t address , uint32_t data )
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{
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ioport_write_table [ 0 ] [ address & ( MAX_IOPORTS - 1 ) ] ( env , address , data & 0xff ) ;
ioport_write_table [ 0 ] [ ( address + 1 ) & ( MAX_IOPORTS - 1 ) ] ( env , address + 1 , ( data > > 8 ) & 0xff ) ;
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}
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uint32_t default_ioport_readl ( CPUState * env , uint32_t address )
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{
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# ifdef DEBUG_UNUSED_IOPORT
fprintf ( stderr , " inl: port=0x%04x \n " , address ) ;
# endif
return 0xffffffff ;
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}
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void default_ioport_writel ( CPUState * env , uint32_t address , uint32_t data )
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{
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# ifdef DEBUG_UNUSED_IOPORT
fprintf ( stderr , " outl: port=0x%04x data=0x%02x \n " , address , data ) ;
# endif
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}
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void init_ioports ( void )
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{
int i ;
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for ( i = 0 ; i < MAX_IOPORTS ; i + + ) {
ioport_read_table [ 0 ] [ i ] = default_ioport_readb ;
ioport_write_table [ 0 ] [ i ] = default_ioport_writeb ;
ioport_read_table [ 1 ] [ i ] = default_ioport_readw ;
ioport_write_table [ 1 ] [ i ] = default_ioport_writew ;
ioport_read_table [ 2 ] [ i ] = default_ioport_readl ;
ioport_write_table [ 2 ] [ i ] = default_ioport_writel ;
}
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}
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/* size is the word size in byte */
int register_ioport_read ( int start , int length , IOPortReadFunc * func , int size )
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{
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int i , bsize ;
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if ( size = = 1 )
bsize = 0 ;
else if ( size = = 2 )
bsize = 1 ;
else if ( size = = 4 )
bsize = 2 ;
else
return - 1 ;
for ( i = start ; i < start + length ; i + = size )
ioport_read_table [ bsize ] [ i ] = func ;
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return 0 ;
}
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/* size is the word size in byte */
int register_ioport_write ( int start , int length , IOPortWriteFunc * func , int size )
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{
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int i , bsize ;
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if ( size = = 1 )
bsize = 0 ;
else if ( size = = 2 )
bsize = 1 ;
else if ( size = = 4 )
bsize = 2 ;
else
return - 1 ;
for ( i = start ; i < start + length ; i + = size )
ioport_write_table [ bsize ] [ i ] = func ;
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return 0 ;
}
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void pstrcpy ( char * buf , int buf_size , const char * str )
{
int c ;
char * q = buf ;
if ( buf_size < = 0 )
return ;
for ( ; ; ) {
c = * str + + ;
if ( c = = 0 | | q > = buf + buf_size - 1 )
break ;
* q + + = c ;
}
* q = ' \0 ' ;
}
/* strcat and truncate. */
char * pstrcat ( char * buf , int buf_size , const char * s )
{
int len ;
len = strlen ( buf ) ;
if ( len < buf_size )
pstrcpy ( buf + len , buf_size - len , s ) ;
return buf ;
}
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# if defined (TARGET_I386)
int load_kernel ( const char * filename , uint8_t * addr ,
uint8_t * real_addr )
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{
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int fd , size ;
int setup_sects ;
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fd = open ( filename , O_RDONLY ) ;
if ( fd < 0 )
return - 1 ;
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/* load 16 bit code */
if ( read ( fd , real_addr , 512 ) ! = 512 )
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goto fail ;
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setup_sects = real_addr [ 0x1F1 ] ;
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if ( ! setup_sects )
setup_sects = 4 ;
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if ( read ( fd , real_addr + 512 , setup_sects * 512 ) ! =
setup_sects * 512 )
goto fail ;
/* load 32 bit code */
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size = read ( fd , addr , 16 * 1024 * 1024 ) ;
if ( size < 0 )
goto fail ;
close ( fd ) ;
return size ;
fail :
close ( fd ) ;
return - 1 ;
}
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# endif
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/* return the size or -1 if error */
int load_image ( const char * filename , uint8_t * addr )
{
int fd , size ;
fd = open ( filename , O_RDONLY ) ;
if ( fd < 0 )
return - 1 ;
size = lseek ( fd , 0 , SEEK_END ) ;
lseek ( fd , 0 , SEEK_SET ) ;
if ( read ( fd , addr , size ) ! = size ) {
close ( fd ) ;
return - 1 ;
}
close ( fd ) ;
return size ;
}
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void cpu_outb ( CPUState * env , int addr , int val )
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{
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ioport_write_table [ 0 ] [ addr & ( MAX_IOPORTS - 1 ) ] ( env , addr , val ) ;
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}
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void cpu_outw ( CPUState * env , int addr , int val )
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{
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ioport_write_table [ 1 ] [ addr & ( MAX_IOPORTS - 1 ) ] ( env , addr , val ) ;
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}
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void cpu_outl ( CPUState * env , int addr , int val )
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{
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ioport_write_table [ 2 ] [ addr & ( MAX_IOPORTS - 1 ) ] ( env , addr , val ) ;
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}
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int cpu_inb ( CPUState * env , int addr )
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{
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return ioport_read_table [ 0 ] [ addr & ( MAX_IOPORTS - 1 ) ] ( env , addr ) ;
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}
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int cpu_inw ( CPUState * env , int addr )
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{
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return ioport_read_table [ 1 ] [ addr & ( MAX_IOPORTS - 1 ) ] ( env , addr ) ;
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}
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int cpu_inl ( CPUState * env , int addr )
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{
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return ioport_read_table [ 2 ] [ addr & ( MAX_IOPORTS - 1 ) ] ( env , addr ) ;
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}
/***********************************************************/
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void ioport80_write ( CPUState * env , uint32_t addr , uint32_t data )
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{
}
void hw_error ( const char * fmt , . . . )
{
va_list ap ;
va_start ( ap , fmt ) ;
fprintf ( stderr , " qemu: hardware error: " ) ;
vfprintf ( stderr , fmt , ap ) ;
fprintf ( stderr , " \n " ) ;
# ifdef TARGET_I386
cpu_x86_dump_state ( global_env , stderr , X86_DUMP_FPU | X86_DUMP_CCOP ) ;
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# else
cpu_dump_state ( global_env , stderr , 0 ) ;
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# endif
va_end ( ap ) ;
abort ( ) ;
}
/***********************************************************/
/* cmos emulation */
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# if defined (TARGET_I386)
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# define RTC_SECONDS 0
# define RTC_SECONDS_ALARM 1
# define RTC_MINUTES 2
# define RTC_MINUTES_ALARM 3
# define RTC_HOURS 4
# define RTC_HOURS_ALARM 5
# define RTC_ALARM_DONT_CARE 0xC0
# define RTC_DAY_OF_WEEK 6
# define RTC_DAY_OF_MONTH 7
# define RTC_MONTH 8
# define RTC_YEAR 9
# define RTC_REG_A 10
# define RTC_REG_B 11
# define RTC_REG_C 12
# define RTC_REG_D 13
/* PC cmos mappings */
# define REG_EQUIPMENT_BYTE 0x14
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# define REG_IBM_CENTURY_BYTE 0x32
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# define REG_IBM_PS2_CENTURY_BYTE 0x37
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uint8_t cmos_data [ 128 ] ;
uint8_t cmos_index ;
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void cmos_ioport_write ( CPUState * env , uint32_t addr , uint32_t data )
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{
if ( addr = = 0x70 ) {
cmos_index = data & 0x7f ;
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} else {
# ifdef DEBUG_CMOS
printf ( " cmos: write index=0x%02x val=0x%02x \n " ,
cmos_index , data ) ;
# endif
switch ( addr ) {
case RTC_SECONDS_ALARM :
case RTC_MINUTES_ALARM :
case RTC_HOURS_ALARM :
/* XXX: not supported */
cmos_data [ cmos_index ] = data ;
break ;
case RTC_SECONDS :
case RTC_MINUTES :
case RTC_HOURS :
case RTC_DAY_OF_WEEK :
case RTC_DAY_OF_MONTH :
case RTC_MONTH :
case RTC_YEAR :
cmos_data [ cmos_index ] = data ;
break ;
case RTC_REG_A :
case RTC_REG_B :
cmos_data [ cmos_index ] = data ;
break ;
case RTC_REG_C :
case RTC_REG_D :
/* cannot write to them */
break ;
default :
cmos_data [ cmos_index ] = data ;
break ;
}
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}
}
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static inline int to_bcd ( int a )
{
return ( ( a / 10 ) < < 4 ) | ( a % 10 ) ;
}
static void cmos_update_time ( void )
{
struct tm * tm ;
time_t ti ;
ti = time ( NULL ) ;
tm = gmtime ( & ti ) ;
cmos_data [ RTC_SECONDS ] = to_bcd ( tm - > tm_sec ) ;
cmos_data [ RTC_MINUTES ] = to_bcd ( tm - > tm_min ) ;
cmos_data [ RTC_HOURS ] = to_bcd ( tm - > tm_hour ) ;
cmos_data [ RTC_DAY_OF_WEEK ] = to_bcd ( tm - > tm_wday ) ;
cmos_data [ RTC_DAY_OF_MONTH ] = to_bcd ( tm - > tm_mday ) ;
cmos_data [ RTC_MONTH ] = to_bcd ( tm - > tm_mon + 1 ) ;
cmos_data [ RTC_YEAR ] = to_bcd ( tm - > tm_year % 100 ) ;
cmos_data [ REG_IBM_CENTURY_BYTE ] = to_bcd ( ( tm - > tm_year / 100 ) + 19 ) ;
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cmos_data [ REG_IBM_PS2_CENTURY_BYTE ] = cmos_data [ REG_IBM_CENTURY_BYTE ] ;
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}
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uint32_t cmos_ioport_read ( CPUState * env , uint32_t addr )
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{
int ret ;
if ( addr = = 0x70 ) {
return 0xff ;
} else {
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switch ( cmos_index ) {
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case RTC_SECONDS :
case RTC_MINUTES :
case RTC_HOURS :
case RTC_DAY_OF_WEEK :
case RTC_DAY_OF_MONTH :
case RTC_MONTH :
case RTC_YEAR :
case REG_IBM_CENTURY_BYTE :
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case REG_IBM_PS2_CENTURY_BYTE :
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cmos_update_time ( ) ;
ret = cmos_data [ cmos_index ] ;
break ;
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case RTC_REG_A :
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ret = cmos_data [ cmos_index ] ;
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/* toggle update-in-progress bit for Linux (same hack as
plex86 ) */
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cmos_data [ RTC_REG_A ] ^ = 0x80 ;
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break ;
case RTC_REG_C :
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ret = cmos_data [ cmos_index ] ;
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pic_set_irq ( 8 , 0 ) ;
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cmos_data [ RTC_REG_C ] = 0x00 ;
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break ;
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default :
ret = cmos_data [ cmos_index ] ;
break ;
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}
# ifdef DEBUG_CMOS
printf ( " cmos: read index=0x%02x val=0x%02x \n " ,
cmos_index , ret ) ;
# endif
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return ret ;
}
}
void cmos_init ( void )
{
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int val ;
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cmos_update_time ( ) ;
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cmos_data [ RTC_REG_A ] = 0x26 ;
cmos_data [ RTC_REG_B ] = 0x02 ;
cmos_data [ RTC_REG_C ] = 0x00 ;
cmos_data [ RTC_REG_D ] = 0x80 ;
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/* various important CMOS locations needed by PC/Bochs bios */
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cmos_data [ REG_EQUIPMENT_BYTE ] = 0x02 ; /* FPU is there */
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cmos_data [ REG_EQUIPMENT_BYTE ] | = 0x04 ; /* PS/2 mouse installed */
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/* memory size */
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val = ( ram_size / 1024 ) - 1024 ;
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if ( val > 65535 )
val = 65535 ;
cmos_data [ 0x17 ] = val ;
cmos_data [ 0x18 ] = val > > 8 ;
cmos_data [ 0x30 ] = val ;
cmos_data [ 0x31 ] = val > > 8 ;
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val = ( ram_size / 65536 ) - ( ( 16 * 1024 * 1024 ) / 65536 ) ;
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if ( val > 65535 )
val = 65535 ;
cmos_data [ 0x34 ] = val ;
cmos_data [ 0x35 ] = val > > 8 ;
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switch ( boot_device ) {
case ' a ' :
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case ' b ' :
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cmos_data [ 0x3d ] = 0x01 ; /* floppy boot */
break ;
default :
case ' c ' :
cmos_data [ 0x3d ] = 0x02 ; /* hard drive boot */
break ;
case ' d ' :
cmos_data [ 0x3d ] = 0x03 ; /* CD-ROM boot */
break ;
}
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register_ioport_write ( 0x70 , 2 , cmos_ioport_write , 1 ) ;
register_ioport_read ( 0x70 , 2 , cmos_ioport_read , 1 ) ;
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}
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void cmos_register_fd ( uint8_t fd0 , uint8_t fd1 )
{
int nb = 0 ;
cmos_data [ 0x10 ] = 0 ;
switch ( fd0 ) {
case 0 :
/* 1.44 Mb 3"5 drive */
cmos_data [ 0x10 ] | = 0x40 ;
break ;
case 1 :
/* 2.88 Mb 3"5 drive */
cmos_data [ 0x10 ] | = 0x60 ;
break ;
case 2 :
/* 1.2 Mb 5"5 drive */
cmos_data [ 0x10 ] | = 0x20 ;
break ;
}
switch ( fd1 ) {
case 0 :
/* 1.44 Mb 3"5 drive */
cmos_data [ 0x10 ] | = 0x04 ;
break ;
case 1 :
/* 2.88 Mb 3"5 drive */
cmos_data [ 0x10 ] | = 0x06 ;
break ;
case 2 :
/* 1.2 Mb 5"5 drive */
cmos_data [ 0x10 ] | = 0x02 ;
break ;
}
if ( fd0 < 3 )
nb + + ;
if ( fd1 < 3 )
nb + + ;
switch ( nb ) {
case 0 :
break ;
case 1 :
cmos_data [ REG_EQUIPMENT_BYTE ] | = 0x01 ; /* 1 drive, ready for boot */
break ;
case 2 :
cmos_data [ REG_EQUIPMENT_BYTE ] | = 0x41 ; /* 2 drives, ready for boot */
break ;
}
}
# endif /* TARGET_I386 */
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/***********************************************************/
/* 8259 pic emulation */
typedef struct PicState {
uint8_t last_irr ; /* edge detection */
uint8_t irr ; /* interrupt request register */
uint8_t imr ; /* interrupt mask register */
uint8_t isr ; /* interrupt service register */
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uint8_t priority_add ; /* highest irq priority */
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uint8_t irq_base ;
uint8_t read_reg_select ;
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uint8_t poll ;
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uint8_t special_mask ;
uint8_t init_state ;
uint8_t auto_eoi ;
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uint8_t rotate_on_auto_eoi ;
uint8_t special_fully_nested_mode ;
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uint8_t init4 ; /* true if 4 byte init */
} PicState ;
/* 0 is master pic, 1 is slave pic */
PicState pics [ 2 ] ;
int pic_irq_requested ;
/* set irq level. If an edge is detected, then the IRR is set to 1 */
static inline void pic_set_irq1 ( PicState * s , int irq , int level )
{
int mask ;
mask = 1 < < irq ;
if ( level ) {
if ( ( s - > last_irr & mask ) = = 0 )
s - > irr | = mask ;
s - > last_irr | = mask ;
} else {
s - > last_irr & = ~ mask ;
}
}
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/* return the highest priority found in mask (highest = smallest
number ) . Return 8 if no irq */
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static inline int get_priority ( PicState * s , int mask )
{
int priority ;
if ( mask = = 0 )
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return 8 ;
priority = 0 ;
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while ( ( mask & ( 1 < < ( ( priority + s - > priority_add ) & 7 ) ) ) = = 0 )
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priority + + ;
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return priority ;
}
/* return the pic wanted interrupt. return -1 if none */
static int pic_get_irq ( PicState * s )
{
int mask , cur_priority , priority ;
mask = s - > irr & ~ s - > imr ;
priority = get_priority ( s , mask ) ;
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if ( priority = = 8 )
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return - 1 ;
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/* compute current priority. If special fully nested mode on the
master , the IRQ coming from the slave is not taken into account
for the priority computation . */
mask = s - > isr ;
if ( s - > special_fully_nested_mode & & s = = & pics [ 0 ] )
mask & = ~ ( 1 < < 2 ) ;
cur_priority = get_priority ( s , mask ) ;
if ( priority < cur_priority ) {
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/* higher priority found: an irq should be generated */
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return ( priority + s - > priority_add ) & 7 ;
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} else {
return - 1 ;
}
}
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/* raise irq to CPU if necessary. must be called every time the active
irq may change */
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void pic_update_irq ( void )
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{
int irq2 , irq ;
/* first look at slave pic */
irq2 = pic_get_irq ( & pics [ 1 ] ) ;
if ( irq2 > = 0 ) {
/* if irq request by slave pic, signal master PIC */
pic_set_irq1 ( & pics [ 0 ] , 2 , 1 ) ;
pic_set_irq1 ( & pics [ 0 ] , 2 , 0 ) ;
}
/* look at requested irq */
irq = pic_get_irq ( & pics [ 0 ] ) ;
if ( irq > = 0 ) {
if ( irq = = 2 ) {
/* from slave pic */
pic_irq_requested = 8 + irq2 ;
} else {
/* from master pic */
pic_irq_requested = irq ;
}
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# if defined(DEBUG_PIC)
{
int i ;
for ( i = 0 ; i < 2 ; i + + ) {
printf ( " pic%d: imr=%x irr=%x padd=%d \n " ,
i , pics [ i ] . imr , pics [ i ] . irr , pics [ i ] . priority_add ) ;
}
}
printf ( " pic: cpu_interrupt req=%d \n " , pic_irq_requested ) ;
# endif
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cpu_interrupt ( global_env , CPU_INTERRUPT_HARD ) ;
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}
}
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# ifdef DEBUG_IRQ_LATENCY
int64_t irq_time [ 16 ] ;
int64_t cpu_get_ticks ( void ) ;
# endif
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# if defined(DEBUG_PIC)
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int irq_level [ 16 ] ;
# endif
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void pic_set_irq ( int irq , int level )
{
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# if defined(DEBUG_PIC)
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if ( level ! = irq_level [ irq ] ) {
printf ( " pic_set_irq: irq=%d level=%d \n " , irq , level ) ;
irq_level [ irq ] = level ;
}
# endif
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# ifdef DEBUG_IRQ_LATENCY
if ( level ) {
irq_time [ irq ] = cpu_get_ticks ( ) ;
}
# endif
pic_set_irq1 ( & pics [ irq > > 3 ] , irq & 7 , level ) ;
pic_update_irq ( ) ;
}
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/* acknowledge interrupt 'irq' */
static inline void pic_intack ( PicState * s , int irq )
{
if ( s - > auto_eoi ) {
if ( s - > rotate_on_auto_eoi )
s - > priority_add = ( irq + 1 ) & 7 ;
} else {
s - > isr | = ( 1 < < irq ) ;
}
s - > irr & = ~ ( 1 < < irq ) ;
}
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int cpu_x86_get_pic_interrupt ( CPUState * env )
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{
int irq , irq2 , intno ;
/* signal the pic that the irq was acked by the CPU */
irq = pic_irq_requested ;
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# ifdef DEBUG_IRQ_LATENCY
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printf ( " IRQ%d latency=%0.3fus \n " ,
irq ,
( double ) ( cpu_get_ticks ( ) - irq_time [ irq ] ) * 1000000.0 / ticks_per_sec ) ;
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# endif
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# if defined(DEBUG_PIC)
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printf ( " pic_interrupt: irq=%d \n " , irq ) ;
# endif
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if ( irq > = 8 ) {
irq2 = irq & 7 ;
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pic_intack ( & pics [ 1 ] , irq2 ) ;
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irq = 2 ;
intno = pics [ 1 ] . irq_base + irq2 ;
} else {
intno = pics [ 0 ] . irq_base + irq ;
}
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pic_intack ( & pics [ 0 ] , irq ) ;
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return intno ;
}
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void pic_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
PicState * s ;
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int priority , cmd , irq ;
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# ifdef DEBUG_PIC
printf ( " pic_write: addr=0x%02x val=0x%02x \n " , addr , val ) ;
# endif
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s = & pics [ addr > > 7 ] ;
addr & = 1 ;
if ( addr = = 0 ) {
if ( val & 0x10 ) {
/* init */
memset ( s , 0 , sizeof ( PicState ) ) ;
s - > init_state = 1 ;
s - > init4 = val & 1 ;
if ( val & 0x02 )
hw_error ( " single mode not supported " ) ;
if ( val & 0x08 )
hw_error ( " level sensitive irq not supported " ) ;
} else if ( val & 0x08 ) {
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if ( val & 0x04 )
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s - > poll = 1 ;
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if ( val & 0x02 )
s - > read_reg_select = val & 1 ;
if ( val & 0x40 )
s - > special_mask = ( val > > 5 ) & 1 ;
} else {
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cmd = val > > 5 ;
switch ( cmd ) {
case 0 :
case 4 :
s - > rotate_on_auto_eoi = cmd > > 2 ;
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break ;
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case 1 : /* end of interrupt */
case 5 :
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priority = get_priority ( s , s - > isr ) ;
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if ( priority ! = 8 ) {
irq = ( priority + s - > priority_add ) & 7 ;
s - > isr & = ~ ( 1 < < irq ) ;
if ( cmd = = 5 )
s - > priority_add = ( irq + 1 ) & 7 ;
pic_update_irq ( ) ;
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}
break ;
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case 3 :
irq = val & 7 ;
s - > isr & = ~ ( 1 < < irq ) ;
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pic_update_irq ( ) ;
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break ;
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case 6 :
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s - > priority_add = ( val + 1 ) & 7 ;
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pic_update_irq ( ) ;
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break ;
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case 7 :
irq = val & 7 ;
s - > isr & = ~ ( 1 < < irq ) ;
s - > priority_add = ( irq + 1 ) & 7 ;
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pic_update_irq ( ) ;
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break ;
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default :
/* no operation */
break ;
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}
}
} else {
switch ( s - > init_state ) {
case 0 :
/* normal mode */
s - > imr = val ;
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pic_update_irq ( ) ;
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break ;
case 1 :
s - > irq_base = val & 0xf8 ;
s - > init_state = 2 ;
break ;
case 2 :
if ( s - > init4 ) {
s - > init_state = 3 ;
} else {
s - > init_state = 0 ;
}
break ;
case 3 :
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s - > special_fully_nested_mode = ( val > > 4 ) & 1 ;
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s - > auto_eoi = ( val > > 1 ) & 1 ;
s - > init_state = 0 ;
break ;
}
}
}
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static uint32_t pic_poll_read ( PicState * s , uint32_t addr1 )
{
int ret ;
ret = pic_get_irq ( s ) ;
if ( ret > = 0 ) {
if ( addr1 > > 7 ) {
pics [ 0 ] . isr & = ~ ( 1 < < 2 ) ;
pics [ 0 ] . irr & = ~ ( 1 < < 2 ) ;
}
s - > irr & = ~ ( 1 < < ret ) ;
s - > isr & = ~ ( 1 < < ret ) ;
if ( addr1 > > 7 | | ret ! = 2 )
pic_update_irq ( ) ;
} else {
ret = 0x07 ;
pic_update_irq ( ) ;
}
return ret ;
}
uint32_t pic_ioport_read ( CPUState * env , uint32_t addr1 )
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{
PicState * s ;
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unsigned int addr ;
int ret ;
addr = addr1 ;
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s = & pics [ addr > > 7 ] ;
addr & = 1 ;
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if ( s - > poll ) {
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ret = pic_poll_read ( s , addr1 ) ;
s - > poll = 0 ;
} else {
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if ( addr = = 0 ) {
if ( s - > read_reg_select )
ret = s - > isr ;
else
ret = s - > irr ;
} else {
ret = s - > imr ;
}
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}
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# ifdef DEBUG_PIC
printf ( " pic_read: addr=0x%02x val=0x%02x \n " , addr1 , ret ) ;
# endif
return ret ;
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}
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/* memory mapped interrupt status */
uint32_t pic_intack_read ( CPUState * env )
{
int ret ;
ret = pic_poll_read ( & pics [ 0 ] , 0x00 ) ;
if ( ret = = 2 )
ret = pic_poll_read ( & pics [ 1 ] , 0x80 ) + 8 ;
/* Prepare for ISR read */
pics [ 0 ] . read_reg_select = 1 ;
return ret ;
}
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void pic_init ( void )
{
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# if defined (TARGET_I386) || defined (TARGET_PPC)
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register_ioport_write ( 0x20 , 2 , pic_ioport_write , 1 ) ;
register_ioport_read ( 0x20 , 2 , pic_ioport_read , 1 ) ;
register_ioport_write ( 0xa0 , 2 , pic_ioport_write , 1 ) ;
register_ioport_read ( 0xa0 , 2 , pic_ioport_read , 1 ) ;
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# endif
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}
/***********************************************************/
/* 8253 PIT emulation */
# define PIT_FREQ 1193182
# define RW_STATE_LSB 0
# define RW_STATE_MSB 1
# define RW_STATE_WORD0 2
# define RW_STATE_WORD1 3
# define RW_STATE_LATCHED_WORD0 4
# define RW_STATE_LATCHED_WORD1 5
typedef struct PITChannelState {
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int count ; /* can be 65536 */
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uint16_t latched_count ;
uint8_t rw_state ;
uint8_t mode ;
uint8_t bcd ; /* not supported */
uint8_t gate ; /* timer start */
int64_t count_load_time ;
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int64_t count_last_edge_check_time ;
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} PITChannelState ;
PITChannelState pit_channels [ 3 ] ;
int speaker_data_on ;
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int dummy_refresh_clock ;
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int pit_min_timer_count = 0 ;
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# if defined(__powerpc__)
static inline uint32_t get_tbl ( void )
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{
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uint32_t tbl ;
asm volatile ( " mftb %0 " : " =r " ( tbl ) ) ;
return tbl ;
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}
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static inline uint32_t get_tbu ( void )
{
uint32_t tbl ;
asm volatile ( " mftbu %0 " : " =r " ( tbl ) ) ;
return tbl ;
}
int64_t cpu_get_real_ticks ( void )
{
uint32_t l , h , h1 ;
/* NOTE: we test if wrapping has occurred */
do {
h = get_tbu ( ) ;
l = get_tbl ( ) ;
h1 = get_tbu ( ) ;
} while ( h ! = h1 ) ;
return ( ( int64_t ) h < < 32 ) | l ;
}
# elif defined(__i386__)
int64_t cpu_get_real_ticks ( void )
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{
int64_t val ;
asm ( " rdtsc " : " =A " ( val ) ) ;
return val ;
}
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# else
# error unsupported CPU
# endif
static int64_t cpu_ticks_offset ;
static int64_t cpu_ticks_last ;
int64_t cpu_get_ticks ( void )
{
return cpu_get_real_ticks ( ) + cpu_ticks_offset ;
}
/* enable cpu_get_ticks() */
void cpu_enable_ticks ( void )
{
cpu_ticks_offset = cpu_ticks_last - cpu_get_real_ticks ( ) ;
}
/* disable cpu_get_ticks() : the clock is stopped. You must not call
cpu_get_ticks ( ) after that . */
void cpu_disable_ticks ( void )
{
cpu_ticks_last = cpu_get_ticks ( ) ;
}
int64_t get_clock ( void )
{
struct timeval tv ;
gettimeofday ( & tv , NULL ) ;
return tv . tv_sec * 1000000LL + tv . tv_usec ;
}
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void cpu_calibrate_ticks ( void )
{
int64_t usec , ticks ;
usec = get_clock ( ) ;
ticks = cpu_get_ticks ( ) ;
usleep ( 50 * 1000 ) ;
usec = get_clock ( ) - usec ;
ticks = cpu_get_ticks ( ) - ticks ;
ticks_per_sec = ( ticks * 1000000LL + ( usec > > 1 ) ) / usec ;
}
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/* compute with 96 bit intermediate result: (a*b)/c */
static uint64_t muldiv64 ( uint64_t a , uint32_t b , uint32_t c )
{
union {
uint64_t ll ;
struct {
# ifdef WORDS_BIGENDIAN
uint32_t high , low ;
# else
uint32_t low , high ;
# endif
} l ;
} u , res ;
uint64_t rl , rh ;
u . ll = a ;
rl = ( uint64_t ) u . l . low * ( uint64_t ) b ;
rh = ( uint64_t ) u . l . high * ( uint64_t ) b ;
rh + = ( rl > > 32 ) ;
res . l . high = rh / c ;
res . l . low = ( ( ( rh % c ) < < 32 ) + ( rl & 0xffffffff ) ) / c ;
return res . ll ;
}
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static int pit_get_count ( PITChannelState * s )
{
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uint64_t d ;
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int counter ;
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d = muldiv64 ( cpu_get_ticks ( ) - s - > count_load_time , PIT_FREQ , ticks_per_sec ) ;
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switch ( s - > mode ) {
case 0 :
case 1 :
case 4 :
case 5 :
counter = ( s - > count - d ) & 0xffff ;
break ;
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case 3 :
/* XXX: may be incorrect for odd counts */
counter = s - > count - ( ( 2 * d ) % s - > count ) ;
break ;
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default :
counter = s - > count - ( d % s - > count ) ;
break ;
}
return counter ;
}
/* get pit output bit */
static int pit_get_out ( PITChannelState * s )
{
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uint64_t d ;
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int out ;
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d = muldiv64 ( cpu_get_ticks ( ) - s - > count_load_time , PIT_FREQ , ticks_per_sec ) ;
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switch ( s - > mode ) {
default :
case 0 :
out = ( d > = s - > count ) ;
break ;
case 1 :
out = ( d < s - > count ) ;
break ;
case 2 :
if ( ( d % s - > count ) = = 0 & & d ! = 0 )
out = 1 ;
else
out = 0 ;
break ;
case 3 :
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out = ( d % s - > count ) < ( ( s - > count + 1 ) > > 1 ) ;
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break ;
case 4 :
case 5 :
out = ( d = = s - > count ) ;
break ;
}
return out ;
}
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/* get the number of 0 to 1 transitions we had since we call this
function */
/* XXX: maybe better to use ticks precision to avoid getting edges
twice if checks are done at very small intervals */
static int pit_get_out_edges ( PITChannelState * s )
{
uint64_t d1 , d2 ;
int64_t ticks ;
int ret , v ;
ticks = cpu_get_ticks ( ) ;
d1 = muldiv64 ( s - > count_last_edge_check_time - s - > count_load_time ,
PIT_FREQ , ticks_per_sec ) ;
d2 = muldiv64 ( ticks - s - > count_load_time ,
PIT_FREQ , ticks_per_sec ) ;
s - > count_last_edge_check_time = ticks ;
switch ( s - > mode ) {
default :
case 0 :
if ( d1 < s - > count & & d2 > = s - > count )
ret = 1 ;
else
ret = 0 ;
break ;
case 1 :
ret = 0 ;
break ;
case 2 :
d1 / = s - > count ;
d2 / = s - > count ;
ret = d2 - d1 ;
break ;
case 3 :
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v = s - > count - ( ( s - > count + 1 ) > > 1 ) ;
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d1 = ( d1 + v ) / s - > count ;
d2 = ( d2 + v ) / s - > count ;
ret = d2 - d1 ;
break ;
case 4 :
case 5 :
if ( d1 < s - > count & & d2 > = s - > count )
ret = 1 ;
else
ret = 0 ;
break ;
}
return ret ;
}
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/* val must be 0 or 1 */
static inline void pit_set_gate ( PITChannelState * s , int val )
{
switch ( s - > mode ) {
default :
case 0 :
case 4 :
/* XXX: just disable/enable counting */
break ;
case 1 :
case 5 :
if ( s - > gate < val ) {
/* restart counting on rising edge */
s - > count_load_time = cpu_get_ticks ( ) ;
s - > count_last_edge_check_time = s - > count_load_time ;
}
break ;
case 2 :
case 3 :
if ( s - > gate < val ) {
/* restart counting on rising edge */
s - > count_load_time = cpu_get_ticks ( ) ;
s - > count_last_edge_check_time = s - > count_load_time ;
}
/* XXX: disable/enable counting */
break ;
}
s - > gate = val ;
}
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static inline void pit_load_count ( PITChannelState * s , int val )
{
if ( val = = 0 )
val = 0x10000 ;
s - > count_load_time = cpu_get_ticks ( ) ;
s - > count_last_edge_check_time = s - > count_load_time ;
s - > count = val ;
if ( s = = & pit_channels [ 0 ] & & val < = pit_min_timer_count ) {
fprintf ( stderr ,
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" \n WARNING: qemu: on your system, accurate timer emulation is impossible if its frequency is more than %d Hz. If using a 2.6 guest Linux kernel, you must patch asm/param.h to change HZ from 1000 to 100. \n \n " ,
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PIT_FREQ / pit_min_timer_count ) ;
}
}
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void pit_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
int channel , access ;
PITChannelState * s ;
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addr & = 3 ;
if ( addr = = 3 ) {
channel = val > > 6 ;
if ( channel = = 3 )
return ;
s = & pit_channels [ channel ] ;
access = ( val > > 4 ) & 3 ;
switch ( access ) {
case 0 :
s - > latched_count = pit_get_count ( s ) ;
s - > rw_state = RW_STATE_LATCHED_WORD0 ;
break ;
default :
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s - > mode = ( val > > 1 ) & 7 ;
s - > bcd = val & 1 ;
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s - > rw_state = access - 1 + RW_STATE_LSB ;
break ;
}
} else {
s = & pit_channels [ addr ] ;
switch ( s - > rw_state ) {
case RW_STATE_LSB :
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pit_load_count ( s , val ) ;
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break ;
case RW_STATE_MSB :
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pit_load_count ( s , val < < 8 ) ;
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break ;
case RW_STATE_WORD0 :
case RW_STATE_WORD1 :
if ( s - > rw_state & 1 ) {
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pit_load_count ( s , ( s - > latched_count & 0xff ) | ( val < < 8 ) ) ;
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} else {
s - > latched_count = val ;
}
s - > rw_state ^ = 1 ;
break ;
}
}
}
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uint32_t pit_ioport_read ( CPUState * env , uint32_t addr )
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{
int ret , count ;
PITChannelState * s ;
addr & = 3 ;
s = & pit_channels [ addr ] ;
switch ( s - > rw_state ) {
case RW_STATE_LSB :
case RW_STATE_MSB :
case RW_STATE_WORD0 :
case RW_STATE_WORD1 :
count = pit_get_count ( s ) ;
if ( s - > rw_state & 1 )
ret = ( count > > 8 ) & 0xff ;
else
ret = count & 0xff ;
if ( s - > rw_state & 2 )
s - > rw_state ^ = 1 ;
break ;
default :
case RW_STATE_LATCHED_WORD0 :
case RW_STATE_LATCHED_WORD1 :
if ( s - > rw_state & 1 )
ret = s - > latched_count > > 8 ;
else
ret = s - > latched_count & 0xff ;
s - > rw_state ^ = 1 ;
break ;
}
return ret ;
}
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# if defined (TARGET_I386)
void speaker_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
speaker_data_on = ( val > > 1 ) & 1 ;
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pit_set_gate ( & pit_channels [ 2 ] , val & 1 ) ;
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}
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uint32_t speaker_ioport_read ( CPUState * env , uint32_t addr )
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{
int out ;
out = pit_get_out ( & pit_channels [ 2 ] ) ;
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dummy_refresh_clock ^ = 1 ;
return ( speaker_data_on < < 1 ) | pit_channels [ 2 ] . gate | ( out < < 5 ) |
( dummy_refresh_clock < < 4 ) ;
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}
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# endif
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void pit_init ( void )
{
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PITChannelState * s ;
int i ;
cpu_calibrate_ticks ( ) ;
for ( i = 0 ; i < 3 ; i + + ) {
s = & pit_channels [ i ] ;
s - > mode = 3 ;
s - > gate = ( i ! = 2 ) ;
pit_load_count ( s , 0 ) ;
}
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register_ioport_write ( 0x40 , 4 , pit_ioport_write , 1 ) ;
register_ioport_read ( 0x40 , 3 , pit_ioport_read , 1 ) ;
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# if defined (TARGET_I386)
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register_ioport_read ( 0x61 , 1 , speaker_ioport_read , 1 ) ;
register_ioport_write ( 0x61 , 1 , speaker_ioport_write , 1 ) ;
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# endif
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}
/***********************************************************/
/* serial port emulation */
# define UART_IRQ 4
# define UART_LCR_DLAB 0x80 /* Divisor latch access bit */
# define UART_IER_MSI 0x08 /* Enable Modem status interrupt */
# define UART_IER_RLSI 0x04 /* Enable receiver line status interrupt */
# define UART_IER_THRI 0x02 /* Enable Transmitter holding register int. */
# define UART_IER_RDI 0x01 /* Enable receiver data interrupt */
# define UART_IIR_NO_INT 0x01 /* No interrupts pending */
# define UART_IIR_ID 0x06 /* Mask for the interrupt ID */
# define UART_IIR_MSI 0x00 /* Modem status interrupt */
# define UART_IIR_THRI 0x02 /* Transmitter holding register empty */
# define UART_IIR_RDI 0x04 /* Receiver data interrupt */
# define UART_IIR_RLSI 0x06 /* Receiver line status interrupt */
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/*
* These are the definitions for the Modem Control Register
*/
# define UART_MCR_LOOP 0x10 /* Enable loopback test mode */
# define UART_MCR_OUT2 0x08 /* Out2 complement */
# define UART_MCR_OUT1 0x04 /* Out1 complement */
# define UART_MCR_RTS 0x02 /* RTS complement */
# define UART_MCR_DTR 0x01 /* DTR complement */
/*
* These are the definitions for the Modem Status Register
*/
# define UART_MSR_DCD 0x80 /* Data Carrier Detect */
# define UART_MSR_RI 0x40 /* Ring Indicator */
# define UART_MSR_DSR 0x20 /* Data Set Ready */
# define UART_MSR_CTS 0x10 /* Clear to Send */
# define UART_MSR_DDCD 0x08 /* Delta DCD */
# define UART_MSR_TERI 0x04 /* Trailing edge ring indicator */
# define UART_MSR_DDSR 0x02 /* Delta DSR */
# define UART_MSR_DCTS 0x01 /* Delta CTS */
# define UART_MSR_ANY_DELTA 0x0F /* Any of the delta bits! */
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# define UART_LSR_TEMT 0x40 /* Transmitter empty */
# define UART_LSR_THRE 0x20 /* Transmit-hold-register empty */
# define UART_LSR_BI 0x10 /* Break interrupt indicator */
# define UART_LSR_FE 0x08 /* Frame error indicator */
# define UART_LSR_PE 0x04 /* Parity error indicator */
# define UART_LSR_OE 0x02 /* Overrun error indicator */
# define UART_LSR_DR 0x01 /* Receiver data ready */
typedef struct SerialState {
uint8_t divider ;
uint8_t rbr ; /* receive register */
uint8_t ier ;
uint8_t iir ; /* read only */
uint8_t lcr ;
uint8_t mcr ;
uint8_t lsr ; /* read only */
uint8_t msr ;
uint8_t scr ;
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/* NOTE: this hidden state is necessary for tx irq generation as
it can be reset while reading iir */
int thr_ipending ;
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} SerialState ;
SerialState serial_ports [ 1 ] ;
void serial_update_irq ( void )
{
SerialState * s = & serial_ports [ 0 ] ;
if ( ( s - > lsr & UART_LSR_DR ) & & ( s - > ier & UART_IER_RDI ) ) {
s - > iir = UART_IIR_RDI ;
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} else if ( s - > thr_ipending & & ( s - > ier & UART_IER_THRI ) ) {
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s - > iir = UART_IIR_THRI ;
} else {
s - > iir = UART_IIR_NO_INT ;
}
if ( s - > iir ! = UART_IIR_NO_INT ) {
pic_set_irq ( UART_IRQ , 1 ) ;
} else {
pic_set_irq ( UART_IRQ , 0 ) ;
}
}
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void serial_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
SerialState * s = & serial_ports [ 0 ] ;
unsigned char ch ;
int ret ;
addr & = 7 ;
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# ifdef DEBUG_SERIAL
printf ( " serial: write addr=0x%02x val=0x%02x \n " , addr , val ) ;
# endif
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switch ( addr ) {
default :
case 0 :
if ( s - > lcr & UART_LCR_DLAB ) {
s - > divider = ( s - > divider & 0xff00 ) | val ;
} else {
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s - > thr_ipending = 0 ;
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s - > lsr & = ~ UART_LSR_THRE ;
serial_update_irq ( ) ;
ch = val ;
do {
ret = write ( 1 , & ch , 1 ) ;
} while ( ret ! = 1 ) ;
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s - > thr_ipending = 1 ;
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s - > lsr | = UART_LSR_THRE ;
s - > lsr | = UART_LSR_TEMT ;
serial_update_irq ( ) ;
}
break ;
case 1 :
if ( s - > lcr & UART_LCR_DLAB ) {
s - > divider = ( s - > divider & 0x00ff ) | ( val < < 8 ) ;
} else {
s - > ier = val ;
serial_update_irq ( ) ;
}
break ;
case 2 :
break ;
case 3 :
s - > lcr = val ;
break ;
case 4 :
s - > mcr = val ;
break ;
case 5 :
break ;
case 6 :
s - > msr = val ;
break ;
case 7 :
s - > scr = val ;
break ;
}
}
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uint32_t serial_ioport_read ( CPUState * env , uint32_t addr )
2003-06-24 15:42:40 +02:00
{
SerialState * s = & serial_ports [ 0 ] ;
uint32_t ret ;
addr & = 7 ;
switch ( addr ) {
default :
case 0 :
if ( s - > lcr & UART_LCR_DLAB ) {
ret = s - > divider & 0xff ;
} else {
ret = s - > rbr ;
s - > lsr & = ~ ( UART_LSR_DR | UART_LSR_BI ) ;
serial_update_irq ( ) ;
}
break ;
case 1 :
if ( s - > lcr & UART_LCR_DLAB ) {
ret = ( s - > divider > > 8 ) & 0xff ;
} else {
ret = s - > ier ;
}
break ;
case 2 :
ret = s - > iir ;
2003-11-16 16:59:30 +01:00
/* reset THR pending bit */
if ( ( ret & 0x7 ) = = UART_IIR_THRI )
s - > thr_ipending = 0 ;
serial_update_irq ( ) ;
2003-06-24 15:42:40 +02:00
break ;
case 3 :
ret = s - > lcr ;
break ;
case 4 :
ret = s - > mcr ;
break ;
case 5 :
ret = s - > lsr ;
break ;
case 6 :
2003-11-16 16:59:30 +01:00
if ( s - > mcr & UART_MCR_LOOP ) {
/* in loopback, the modem output pins are connected to the
inputs */
ret = ( s - > mcr & 0x0c ) < < 4 ;
ret | = ( s - > mcr & 0x02 ) < < 3 ;
ret | = ( s - > mcr & 0x01 ) < < 5 ;
} else {
ret = s - > msr ;
}
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break ;
case 7 :
ret = s - > scr ;
break ;
}
2003-11-16 16:59:30 +01:00
# ifdef DEBUG_SERIAL
printf ( " serial: read addr=0x%02x val=0x%02x \n " , addr , ret ) ;
# endif
2003-06-24 15:42:40 +02:00
return ret ;
}
# define TERM_ESCAPE 0x01 /* ctrl-a is used for escape */
2004-01-05 01:02:06 +01:00
static int term_got_escape , term_command ;
static unsigned char term_cmd_buf [ 128 ] ;
typedef struct term_cmd_t {
const unsigned char * name ;
void ( * handler ) ( unsigned char * params ) ;
} term_cmd_t ;
static void do_change_cdrom ( unsigned char * params ) ;
static void do_change_fd0 ( unsigned char * params ) ;
static void do_change_fd1 ( unsigned char * params ) ;
static term_cmd_t term_cmds [ ] = {
{ " changecd " , & do_change_cdrom , } ,
{ " changefd0 " , & do_change_fd0 , } ,
{ " changefd1 " , & do_change_fd1 , } ,
{ NULL , NULL , } ,
} ;
2003-06-24 15:42:40 +02:00
void term_print_help ( void )
{
printf ( " \n "
" C-a h print this help \n "
" C-a x exit emulatior \n "
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" C-a d switch on/off debug log \n "
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" C-a s save disk data back to file (if -snapshot) \n "
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" C-a b send break (magic sysrq) \n "
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" C-a c send qemu internal command \n "
2003-06-24 15:42:40 +02:00
" C-a C-a send C-a \n "
) ;
}
2004-01-05 01:02:06 +01:00
static void do_change_cdrom ( unsigned char * params )
{
/* Dunno how to do it... */
}
static void do_change_fd ( int fd , unsigned char * params )
{
unsigned char * name_start , * name_end , * ros ;
int ro ;
for ( name_start = params ;
isspace ( * name_start ) ; name_start + + )
continue ;
if ( * name_start = = ' \0 ' )
return ;
for ( name_end = name_start ;
! isspace ( * name_end ) & & * name_end ! = ' \0 ' ; name_end + + )
continue ;
for ( ros = name_end + 1 ; isspace ( * ros ) ; ros + + )
continue ;
if ( ros [ 0 ] = = ' r ' & & ros [ 1 ] = = ' o ' )
ro = 1 ;
else
ro = 0 ;
* name_end = ' \0 ' ;
printf ( " Change fd %d to %s (%s) \n " , fd , name_start , params ) ;
fdctrl_disk_change ( fd , name_start , ro ) ;
}
static void do_change_fd0 ( unsigned char * params )
{
do_change_fd ( 0 , params ) ;
}
static void do_change_fd1 ( unsigned char * params )
{
do_change_fd ( 1 , params ) ;
}
static void serial_treat_command ( )
{
unsigned char * cmd_start , * cmd_end ;
int i ;
for ( cmd_start = term_cmd_buf ; isspace ( * cmd_start ) ; cmd_start + + )
continue ;
for ( cmd_end = cmd_start ;
! isspace ( * cmd_end ) & & * cmd_end ! = ' \0 ' ; cmd_end + + )
continue ;
for ( i = 0 ; term_cmds [ i ] . name ! = NULL ; i + + ) {
if ( strlen ( term_cmds [ i ] . name ) = = ( cmd_end - cmd_start ) & &
memcmp ( term_cmds [ i ] . name , cmd_start , cmd_end - cmd_start ) = = 0 ) {
( * term_cmds [ i ] . handler ) ( cmd_end + 1 ) ;
return ;
}
}
* cmd_end = ' \0 ' ;
printf ( " Unknown term command: %s \n " , cmd_start ) ;
}
extern FILE * logfile ;
2003-06-24 15:42:40 +02:00
/* called when a char is received */
void serial_received_byte ( SerialState * s , int ch )
{
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if ( term_command ) {
if ( ch = = ' \n ' | | ch = = ' \r ' | | term_command = = 127 ) {
printf ( " \n " ) ;
serial_treat_command ( ) ;
term_command = 0 ;
} else {
if ( ch = = 0x7F | | ch = = 0x08 ) {
if ( term_command > 1 ) {
term_cmd_buf [ - - term_command - 1 ] = ' \0 ' ;
printf ( " \r "
" " ) ;
printf ( " \r > %s " , term_cmd_buf ) ;
}
} else if ( ch > 0x1f ) {
term_cmd_buf [ term_command + + - 1 ] = ch ;
term_cmd_buf [ term_command - 1 ] = ' \0 ' ;
printf ( " \r > %s " , term_cmd_buf ) ;
}
fflush ( stdout ) ;
}
} else if ( term_got_escape ) {
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term_got_escape = 0 ;
switch ( ch ) {
case ' h ' :
term_print_help ( ) ;
break ;
case ' x ' :
exit ( 0 ) ;
break ;
2003-07-06 19:15:21 +02:00
case ' s ' :
{
int i ;
for ( i = 0 ; i < MAX_DISKS ; i + + ) {
if ( bs_table [ i ] )
bdrv_commit ( bs_table [ i ] ) ;
}
}
break ;
2003-06-24 15:42:40 +02:00
case ' b ' :
/* send break */
s - > rbr = 0 ;
s - > lsr | = UART_LSR_BI | UART_LSR_DR ;
serial_update_irq ( ) ;
break ;
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case ' c ' :
printf ( " > " ) ;
fflush ( stdout ) ;
term_command = 1 ;
2003-12-02 23:18:10 +01:00
break ;
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case ' d ' :
cpu_set_log ( CPU_LOG_ALL ) ;
break ;
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case TERM_ESCAPE :
goto send_char ;
}
} else if ( ch = = TERM_ESCAPE ) {
term_got_escape = 1 ;
} else {
send_char :
s - > rbr = ch ;
s - > lsr | = UART_LSR_DR ;
serial_update_irq ( ) ;
}
}
void serial_init ( void )
{
SerialState * s = & serial_ports [ 0 ] ;
s - > lsr = UART_LSR_TEMT | UART_LSR_THRE ;
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s - > iir = UART_IIR_NO_INT ;
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# if defined(TARGET_I386) || defined (TARGET_PPC)
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register_ioport_write ( 0x3f8 , 8 , serial_ioport_write , 1 ) ;
register_ioport_read ( 0x3f8 , 8 , serial_ioport_read , 1 ) ;
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# endif
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}
2003-06-25 02:07:40 +02:00
/***********************************************************/
/* ne2000 emulation */
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# if defined (TARGET_I386)
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# define NE2000_IOPORT 0x300
# define NE2000_IRQ 9
# define MAX_ETH_FRAME_SIZE 1514
# define E8390_CMD 0x00 /* The command register (for all pages) */
/* Page 0 register offsets. */
# define EN0_CLDALO 0x01 /* Low byte of current local dma addr RD */
# define EN0_STARTPG 0x01 /* Starting page of ring bfr WR */
# define EN0_CLDAHI 0x02 /* High byte of current local dma addr RD */
# define EN0_STOPPG 0x02 /* Ending page +1 of ring bfr WR */
# define EN0_BOUNDARY 0x03 /* Boundary page of ring bfr RD WR */
# define EN0_TSR 0x04 /* Transmit status reg RD */
# define EN0_TPSR 0x04 /* Transmit starting page WR */
# define EN0_NCR 0x05 /* Number of collision reg RD */
# define EN0_TCNTLO 0x05 /* Low byte of tx byte count WR */
# define EN0_FIFO 0x06 /* FIFO RD */
# define EN0_TCNTHI 0x06 /* High byte of tx byte count WR */
# define EN0_ISR 0x07 /* Interrupt status reg RD WR */
# define EN0_CRDALO 0x08 /* low byte of current remote dma address RD */
# define EN0_RSARLO 0x08 /* Remote start address reg 0 */
# define EN0_CRDAHI 0x09 /* high byte, current remote dma address RD */
# define EN0_RSARHI 0x09 /* Remote start address reg 1 */
# define EN0_RCNTLO 0x0a /* Remote byte count reg WR */
# define EN0_RCNTHI 0x0b /* Remote byte count reg WR */
# define EN0_RSR 0x0c /* rx status reg RD */
# define EN0_RXCR 0x0c /* RX configuration reg WR */
# define EN0_TXCR 0x0d /* TX configuration reg WR */
# define EN0_COUNTER0 0x0d /* Rcv alignment error counter RD */
# define EN0_DCFG 0x0e /* Data configuration reg WR */
# define EN0_COUNTER1 0x0e /* Rcv CRC error counter RD */
# define EN0_IMR 0x0f /* Interrupt mask reg WR */
# define EN0_COUNTER2 0x0f /* Rcv missed frame error counter RD */
# define EN1_PHYS 0x11
# define EN1_CURPAG 0x17
# define EN1_MULT 0x18
/* Register accessed at EN_CMD, the 8390 base addr. */
# define E8390_STOP 0x01 /* Stop and reset the chip */
# define E8390_START 0x02 /* Start the chip, clear reset */
# define E8390_TRANS 0x04 /* Transmit a frame */
# define E8390_RREAD 0x08 /* Remote read */
# define E8390_RWRITE 0x10 /* Remote write */
# define E8390_NODMA 0x20 /* Remote DMA */
# define E8390_PAGE0 0x00 /* Select page chip registers */
# define E8390_PAGE1 0x40 /* using the two high-order bits */
# define E8390_PAGE2 0x80 /* Page 3 is invalid. */
/* Bits in EN0_ISR - Interrupt status register */
# define ENISR_RX 0x01 /* Receiver, no error */
# define ENISR_TX 0x02 /* Transmitter, no error */
# define ENISR_RX_ERR 0x04 /* Receiver, with error */
# define ENISR_TX_ERR 0x08 /* Transmitter, with error */
# define ENISR_OVER 0x10 /* Receiver overwrote the ring */
# define ENISR_COUNTERS 0x20 /* Counters need emptying */
# define ENISR_RDC 0x40 /* remote dma complete */
# define ENISR_RESET 0x80 /* Reset completed */
# define ENISR_ALL 0x3f /* Interrupts we will enable */
/* Bits in received packet status byte and EN0_RSR*/
# define ENRSR_RXOK 0x01 /* Received a good packet */
# define ENRSR_CRC 0x02 /* CRC error */
# define ENRSR_FAE 0x04 /* frame alignment error */
# define ENRSR_FO 0x08 /* FIFO overrun */
# define ENRSR_MPA 0x10 /* missed pkt */
# define ENRSR_PHY 0x20 /* physical/multicast address */
# define ENRSR_DIS 0x40 /* receiver disable. set in monitor mode */
# define ENRSR_DEF 0x80 /* deferring */
/* Transmitted packet status, EN0_TSR. */
# define ENTSR_PTX 0x01 /* Packet transmitted without error */
# define ENTSR_ND 0x02 /* The transmit wasn't deferred. */
# define ENTSR_COL 0x04 /* The transmit collided at least once. */
# define ENTSR_ABT 0x08 /* The transmit collided 16 times, and was deferred. */
# define ENTSR_CRS 0x10 /* The carrier sense was lost. */
# define ENTSR_FU 0x20 /* A "FIFO underrun" occurred during transmit. */
# define ENTSR_CDH 0x40 /* The collision detect "heartbeat" signal was lost. */
# define ENTSR_OWC 0x80 /* There was an out-of-window collision. */
# define NE2000_MEM_SIZE 32768
typedef struct NE2000State {
uint8_t cmd ;
uint32_t start ;
uint32_t stop ;
uint8_t boundary ;
uint8_t tsr ;
uint8_t tpsr ;
uint16_t tcnt ;
uint16_t rcnt ;
uint32_t rsar ;
uint8_t isr ;
uint8_t dcfg ;
uint8_t imr ;
uint8_t phys [ 6 ] ; /* mac address */
uint8_t curpag ;
uint8_t mult [ 8 ] ; /* multicast mask array */
uint8_t mem [ NE2000_MEM_SIZE ] ;
} NE2000State ;
NE2000State ne2000_state ;
int net_fd = - 1 ;
char network_script [ 1024 ] ;
void ne2000_reset ( void )
{
NE2000State * s = & ne2000_state ;
int i ;
s - > isr = ENISR_RESET ;
s - > mem [ 0 ] = 0x52 ;
s - > mem [ 1 ] = 0x54 ;
s - > mem [ 2 ] = 0x00 ;
s - > mem [ 3 ] = 0x12 ;
s - > mem [ 4 ] = 0x34 ;
s - > mem [ 5 ] = 0x56 ;
s - > mem [ 14 ] = 0x57 ;
s - > mem [ 15 ] = 0x57 ;
/* duplicate prom data */
for ( i = 15 ; i > = 0 ; i - - ) {
s - > mem [ 2 * i ] = s - > mem [ i ] ;
s - > mem [ 2 * i + 1 ] = s - > mem [ i ] ;
}
}
void ne2000_update_irq ( NE2000State * s )
{
int isr ;
isr = s - > isr & s - > imr ;
if ( isr )
pic_set_irq ( NE2000_IRQ , 1 ) ;
else
pic_set_irq ( NE2000_IRQ , 0 ) ;
}
int net_init ( void )
{
struct ifreq ifr ;
int fd , ret , pid , status ;
fd = open ( " /dev/net/tun " , O_RDWR ) ;
if ( fd < 0 ) {
fprintf ( stderr , " warning: could not open /dev/net/tun: no virtual network emulation \n " ) ;
return - 1 ;
}
memset ( & ifr , 0 , sizeof ( ifr ) ) ;
ifr . ifr_flags = IFF_TAP | IFF_NO_PI ;
pstrcpy ( ifr . ifr_name , IFNAMSIZ , " tun%d " ) ;
ret = ioctl ( fd , TUNSETIFF , ( void * ) & ifr ) ;
if ( ret ! = 0 ) {
fprintf ( stderr , " warning: could not configure /dev/net/tun: no virtual network emulation \n " ) ;
close ( fd ) ;
return - 1 ;
}
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printf ( " Connected to host network interface: %s \n " , ifr . ifr_name ) ;
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fcntl ( fd , F_SETFL , O_NONBLOCK ) ;
net_fd = fd ;
/* try to launch network init script */
pid = fork ( ) ;
if ( pid > = 0 ) {
if ( pid = = 0 ) {
execl ( network_script , network_script , ifr . ifr_name , NULL ) ;
exit ( 1 ) ;
}
while ( waitpid ( pid , & status , 0 ) ! = pid ) ;
if ( ! WIFEXITED ( status ) | |
WEXITSTATUS ( status ) ! = 0 ) {
fprintf ( stderr , " %s: could not launch network script for '%s' \n " ,
network_script , ifr . ifr_name ) ;
}
}
return 0 ;
}
void net_send_packet ( NE2000State * s , const uint8_t * buf , int size )
{
# ifdef DEBUG_NE2000
printf ( " NE2000: sending packet size=%d \n " , size ) ;
# endif
write ( net_fd , buf , size ) ;
}
/* return true if the NE2000 can receive more data */
int ne2000_can_receive ( NE2000State * s )
{
int avail , index , boundary ;
if ( s - > cmd & E8390_STOP )
return 0 ;
index = s - > curpag < < 8 ;
boundary = s - > boundary < < 8 ;
if ( index < boundary )
avail = boundary - index ;
else
avail = ( s - > stop - s - > start ) - ( index - boundary ) ;
if ( avail < ( MAX_ETH_FRAME_SIZE + 4 ) )
return 0 ;
return 1 ;
}
void ne2000_receive ( NE2000State * s , uint8_t * buf , int size )
{
uint8_t * p ;
int total_len , next , avail , len , index ;
# if defined(DEBUG_NE2000)
printf ( " NE2000: received len=%d \n " , size ) ;
# endif
index = s - > curpag < < 8 ;
/* 4 bytes for header */
total_len = size + 4 ;
/* address for next packet (4 bytes for CRC) */
next = index + ( ( total_len + 4 + 255 ) & ~ 0xff ) ;
if ( next > = s - > stop )
next - = ( s - > stop - s - > start ) ;
/* prepare packet header */
p = s - > mem + index ;
p [ 0 ] = ENRSR_RXOK ; /* receive status */
p [ 1 ] = next > > 8 ;
p [ 2 ] = total_len ;
p [ 3 ] = total_len > > 8 ;
index + = 4 ;
/* write packet data */
while ( size > 0 ) {
avail = s - > stop - index ;
len = size ;
if ( len > avail )
len = avail ;
memcpy ( s - > mem + index , buf , len ) ;
buf + = len ;
index + = len ;
if ( index = = s - > stop )
index = s - > start ;
size - = len ;
}
s - > curpag = next > > 8 ;
/* now we can signal we have receive something */
s - > isr | = ENISR_RX ;
ne2000_update_irq ( s ) ;
}
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void ne2000_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
NE2000State * s = & ne2000_state ;
int offset , page ;
addr & = 0xf ;
# ifdef DEBUG_NE2000
printf ( " NE2000: write addr=0x%x val=0x%02x \n " , addr , val ) ;
# endif
if ( addr = = E8390_CMD ) {
/* control register */
s - > cmd = val ;
if ( val & E8390_START ) {
/* test specific case: zero length transfert */
if ( ( val & ( E8390_RREAD | E8390_RWRITE ) ) & &
s - > rcnt = = 0 ) {
s - > isr | = ENISR_RDC ;
ne2000_update_irq ( s ) ;
}
if ( val & E8390_TRANS ) {
net_send_packet ( s , s - > mem + ( s - > tpsr < < 8 ) , s - > tcnt ) ;
/* signal end of transfert */
s - > tsr = ENTSR_PTX ;
s - > isr | = ENISR_TX ;
ne2000_update_irq ( s ) ;
}
}
} else {
page = s - > cmd > > 6 ;
offset = addr | ( page < < 4 ) ;
switch ( offset ) {
case EN0_STARTPG :
s - > start = val < < 8 ;
break ;
case EN0_STOPPG :
s - > stop = val < < 8 ;
break ;
case EN0_BOUNDARY :
s - > boundary = val ;
break ;
case EN0_IMR :
s - > imr = val ;
ne2000_update_irq ( s ) ;
break ;
case EN0_TPSR :
s - > tpsr = val ;
break ;
case EN0_TCNTLO :
s - > tcnt = ( s - > tcnt & 0xff00 ) | val ;
break ;
case EN0_TCNTHI :
s - > tcnt = ( s - > tcnt & 0x00ff ) | ( val < < 8 ) ;
break ;
case EN0_RSARLO :
s - > rsar = ( s - > rsar & 0xff00 ) | val ;
break ;
case EN0_RSARHI :
s - > rsar = ( s - > rsar & 0x00ff ) | ( val < < 8 ) ;
break ;
case EN0_RCNTLO :
s - > rcnt = ( s - > rcnt & 0xff00 ) | val ;
break ;
case EN0_RCNTHI :
s - > rcnt = ( s - > rcnt & 0x00ff ) | ( val < < 8 ) ;
break ;
case EN0_DCFG :
s - > dcfg = val ;
break ;
case EN0_ISR :
s - > isr & = ~ val ;
ne2000_update_irq ( s ) ;
break ;
case EN1_PHYS . . . EN1_PHYS + 5 :
s - > phys [ offset - EN1_PHYS ] = val ;
break ;
case EN1_CURPAG :
s - > curpag = val ;
break ;
case EN1_MULT . . . EN1_MULT + 7 :
s - > mult [ offset - EN1_MULT ] = val ;
break ;
}
}
}
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uint32_t ne2000_ioport_read ( CPUState * env , uint32_t addr )
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{
NE2000State * s = & ne2000_state ;
int offset , page , ret ;
addr & = 0xf ;
if ( addr = = E8390_CMD ) {
ret = s - > cmd ;
} else {
page = s - > cmd > > 6 ;
offset = addr | ( page < < 4 ) ;
switch ( offset ) {
case EN0_TSR :
ret = s - > tsr ;
break ;
case EN0_BOUNDARY :
ret = s - > boundary ;
break ;
case EN0_ISR :
ret = s - > isr ;
break ;
case EN1_PHYS . . . EN1_PHYS + 5 :
ret = s - > phys [ offset - EN1_PHYS ] ;
break ;
case EN1_CURPAG :
ret = s - > curpag ;
break ;
case EN1_MULT . . . EN1_MULT + 7 :
ret = s - > mult [ offset - EN1_MULT ] ;
break ;
default :
ret = 0x00 ;
break ;
}
}
# ifdef DEBUG_NE2000
printf ( " NE2000: read addr=0x%x val=%02x \n " , addr , ret ) ;
# endif
return ret ;
}
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void ne2000_asic_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
NE2000State * s = & ne2000_state ;
uint8_t * p ;
# ifdef DEBUG_NE2000
printf ( " NE2000: asic write val=0x%04x \n " , val ) ;
# endif
p = s - > mem + s - > rsar ;
if ( s - > dcfg & 0x01 ) {
/* 16 bit access */
p [ 0 ] = val ;
p [ 1 ] = val > > 8 ;
s - > rsar + = 2 ;
s - > rcnt - = 2 ;
} else {
/* 8 bit access */
p [ 0 ] = val ;
s - > rsar + + ;
s - > rcnt - - ;
}
/* wrap */
if ( s - > rsar = = s - > stop )
s - > rsar = s - > start ;
if ( s - > rcnt = = 0 ) {
/* signal end of transfert */
s - > isr | = ENISR_RDC ;
ne2000_update_irq ( s ) ;
}
}
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uint32_t ne2000_asic_ioport_read ( CPUState * env , uint32_t addr )
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{
NE2000State * s = & ne2000_state ;
uint8_t * p ;
int ret ;
p = s - > mem + s - > rsar ;
if ( s - > dcfg & 0x01 ) {
/* 16 bit access */
ret = p [ 0 ] | ( p [ 1 ] < < 8 ) ;
s - > rsar + = 2 ;
s - > rcnt - = 2 ;
} else {
/* 8 bit access */
ret = p [ 0 ] ;
s - > rsar + + ;
s - > rcnt - - ;
}
/* wrap */
if ( s - > rsar = = s - > stop )
s - > rsar = s - > start ;
if ( s - > rcnt = = 0 ) {
/* signal end of transfert */
s - > isr | = ENISR_RDC ;
ne2000_update_irq ( s ) ;
}
# ifdef DEBUG_NE2000
printf ( " NE2000: asic read val=0x%04x \n " , ret ) ;
# endif
return ret ;
}
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void ne2000_reset_ioport_write ( CPUState * env , uint32_t addr , uint32_t val )
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{
/* nothing to do (end of reset pulse) */
}
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uint32_t ne2000_reset_ioport_read ( CPUState * env , uint32_t addr )
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{
ne2000_reset ( ) ;
return 0 ;
}
void ne2000_init ( void )
{
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register_ioport_write ( NE2000_IOPORT , 16 , ne2000_ioport_write , 1 ) ;
register_ioport_read ( NE2000_IOPORT , 16 , ne2000_ioport_read , 1 ) ;
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register_ioport_write ( NE2000_IOPORT + 0x10 , 1 , ne2000_asic_ioport_write , 1 ) ;
register_ioport_read ( NE2000_IOPORT + 0x10 , 1 , ne2000_asic_ioport_read , 1 ) ;
register_ioport_write ( NE2000_IOPORT + 0x10 , 2 , ne2000_asic_ioport_write , 2 ) ;
register_ioport_read ( NE2000_IOPORT + 0x10 , 2 , ne2000_asic_ioport_read , 2 ) ;
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register_ioport_write ( NE2000_IOPORT + 0x1f , 1 , ne2000_reset_ioport_write , 1 ) ;
register_ioport_read ( NE2000_IOPORT + 0x1f , 1 , ne2000_reset_ioport_read , 1 ) ;
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ne2000_reset ( ) ;
}
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# endif
/***********************************************************/
/* PC floppy disk controler emulation glue */
# define PC_FDC_DMA 0x2
# define PC_FDC_IRQ 0x6
# define PC_FDC_BASE 0x3F0
static void fdctrl_register ( unsigned char * * disknames , int ro ,
char boot_device )
{
int i ;
fdctrl_init ( PC_FDC_IRQ , PC_FDC_DMA , 0 , PC_FDC_BASE , boot_device ) ;
for ( i = 0 ; i < MAX_FD ; i + + ) {
if ( disknames [ i ] ! = NULL )
fdctrl_disk_change ( i , disknames [ i ] , ro ) ;
}
}
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/***********************************************************/
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/* keyboard emulation */
/* Keyboard Controller Commands */
# define KBD_CCMD_READ_MODE 0x20 /* Read mode bits */
# define KBD_CCMD_WRITE_MODE 0x60 /* Write mode bits */
# define KBD_CCMD_GET_VERSION 0xA1 /* Get controller version */
# define KBD_CCMD_MOUSE_DISABLE 0xA7 /* Disable mouse interface */
# define KBD_CCMD_MOUSE_ENABLE 0xA8 /* Enable mouse interface */
# define KBD_CCMD_TEST_MOUSE 0xA9 /* Mouse interface test */
# define KBD_CCMD_SELF_TEST 0xAA /* Controller self test */
# define KBD_CCMD_KBD_TEST 0xAB /* Keyboard interface test */
# define KBD_CCMD_KBD_DISABLE 0xAD /* Keyboard interface disable */
# define KBD_CCMD_KBD_ENABLE 0xAE /* Keyboard interface enable */
# define KBD_CCMD_READ_INPORT 0xC0 /* read input port */
# define KBD_CCMD_READ_OUTPORT 0xD0 /* read output port */
# define KBD_CCMD_WRITE_OUTPORT 0xD1 /* write output port */
# define KBD_CCMD_WRITE_OBUF 0xD2
# define KBD_CCMD_WRITE_AUX_OBUF 0xD3 / * Write to output buffer as if
initiated by the auxiliary device */
# define KBD_CCMD_WRITE_MOUSE 0xD4 /* Write the following byte to the mouse */
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# define KBD_CCMD_DISABLE_A20 0xDD /* HP vectra only ? */
# define KBD_CCMD_ENABLE_A20 0xDF /* HP vectra only ? */
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# define KBD_CCMD_RESET 0xFE
/* Keyboard Commands */
# define KBD_CMD_SET_LEDS 0xED /* Set keyboard leds */
# define KBD_CMD_ECHO 0xEE
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# define KBD_CMD_GET_ID 0xF2 /* get keyboard ID */
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# define KBD_CMD_SET_RATE 0xF3 /* Set typematic rate */
# define KBD_CMD_ENABLE 0xF4 /* Enable scanning */
# define KBD_CMD_RESET_DISABLE 0xF5 /* reset and disable scanning */
# define KBD_CMD_RESET_ENABLE 0xF6 /* reset and enable scanning */
# define KBD_CMD_RESET 0xFF /* Reset */
/* Keyboard Replies */
# define KBD_REPLY_POR 0xAA /* Power on reset */
# define KBD_REPLY_ACK 0xFA /* Command ACK */
# define KBD_REPLY_RESEND 0xFE /* Command NACK, send the cmd again */
/* Status Register Bits */
# define KBD_STAT_OBF 0x01 /* Keyboard output buffer full */
# define KBD_STAT_IBF 0x02 /* Keyboard input buffer full */
# define KBD_STAT_SELFTEST 0x04 /* Self test successful */
# define KBD_STAT_CMD 0x08 /* Last write was a command write (0=data) */
# define KBD_STAT_UNLOCKED 0x10 /* Zero if keyboard locked */
# define KBD_STAT_MOUSE_OBF 0x20 /* Mouse output buffer full */
# define KBD_STAT_GTO 0x40 /* General receive/xmit timeout */
# define KBD_STAT_PERR 0x80 /* Parity error */
/* Controller Mode Register Bits */
# define KBD_MODE_KBD_INT 0x01 /* Keyboard data generate IRQ1 */
# define KBD_MODE_MOUSE_INT 0x02 /* Mouse data generate IRQ12 */
# define KBD_MODE_SYS 0x04 /* The system flag (?) */
# define KBD_MODE_NO_KEYLOCK 0x08 /* The keylock doesn't affect the keyboard if set */
# define KBD_MODE_DISABLE_KBD 0x10 /* Disable keyboard interface */
# define KBD_MODE_DISABLE_MOUSE 0x20 /* Disable mouse interface */
# define KBD_MODE_KCC 0x40 /* Scan code conversion to PC format */
# define KBD_MODE_RFU 0x80
/* Mouse Commands */
# define AUX_SET_SCALE11 0xE6 /* Set 1:1 scaling */
# define AUX_SET_SCALE21 0xE7 /* Set 2:1 scaling */
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# define AUX_SET_RES 0xE8 /* Set resolution */
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# define AUX_GET_SCALE 0xE9 /* Get scaling factor */
# define AUX_SET_STREAM 0xEA /* Set stream mode */
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# define AUX_POLL 0xEB /* Poll */
# define AUX_RESET_WRAP 0xEC /* Reset wrap mode */
# define AUX_SET_WRAP 0xEE /* Set wrap mode */
# define AUX_SET_REMOTE 0xF0 /* Set remote mode */
# define AUX_GET_TYPE 0xF2 /* Get type */
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# define AUX_SET_SAMPLE 0xF3 /* Set sample rate */
# define AUX_ENABLE_DEV 0xF4 /* Enable aux device */
# define AUX_DISABLE_DEV 0xF5 /* Disable aux device */
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# define AUX_SET_DEFAULT 0xF6
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# define AUX_RESET 0xFF /* Reset aux device */
# define AUX_ACK 0xFA /* Command byte ACK. */
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# define MOUSE_STATUS_REMOTE 0x40
# define MOUSE_STATUS_ENABLED 0x20
# define MOUSE_STATUS_SCALE21 0x10
# define KBD_QUEUE_SIZE 256
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typedef struct {
uint8_t data [ KBD_QUEUE_SIZE ] ;
int rptr , wptr , count ;
} KBDQueue ;
typedef struct KBDState {
KBDQueue queues [ 2 ] ;
uint8_t write_cmd ; /* if non zero, write data to port 60 is expected */
uint8_t status ;
uint8_t mode ;
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/* keyboard state */
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int kbd_write_cmd ;
int scan_enabled ;
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/* mouse state */
int mouse_write_cmd ;
uint8_t mouse_status ;
uint8_t mouse_resolution ;
uint8_t mouse_sample_rate ;
uint8_t mouse_wrap ;
uint8_t mouse_type ; /* 0 = PS2, 3 = IMPS/2, 4 = IMEX */
uint8_t mouse_detect_state ;
int mouse_dx ; /* current values, needed for 'poll' mode */
int mouse_dy ;
int mouse_dz ;
uint8_t mouse_buttons ;
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} KBDState ;
KBDState kbd_state ;
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int reset_requested ;
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/* update irq and KBD_STAT_[MOUSE_]OBF */
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/* XXX: not generating the irqs if KBD_MODE_DISABLE_KBD is set may be
incorrect , but it avoids having to simulate exact delays */
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static void kbd_update_irq ( KBDState * s )
{
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int irq12_level , irq1_level ;
irq1_level = 0 ;
irq12_level = 0 ;
s - > status & = ~ ( KBD_STAT_OBF | KBD_STAT_MOUSE_OBF ) ;
if ( s - > queues [ 0 ] . count ! = 0 | |
s - > queues [ 1 ] . count ! = 0 ) {
s - > status | = KBD_STAT_OBF ;
if ( s - > queues [ 1 ] . count ! = 0 ) {
s - > status | = KBD_STAT_MOUSE_OBF ;
if ( s - > mode & KBD_MODE_MOUSE_INT )
irq12_level = 1 ;
} else {
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if ( ( s - > mode & KBD_MODE_KBD_INT ) & &
! ( s - > mode & KBD_MODE_DISABLE_KBD ) )
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irq1_level = 1 ;
}
}
pic_set_irq ( 1 , irq1_level ) ;
pic_set_irq ( 12 , irq12_level ) ;
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}
static void kbd_queue ( KBDState * s , int b , int aux )
{
KBDQueue * q = & kbd_state . queues [ aux ] ;
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# if defined(DEBUG_MOUSE) || defined(DEBUG_KBD)
if ( aux )
printf ( " mouse event: 0x%02x \n " , b ) ;
# ifdef DEBUG_KBD
else
printf ( " kbd event: 0x%02x \n " , b ) ;
# endif
# endif
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if ( q - > count > = KBD_QUEUE_SIZE )
return ;
q - > data [ q - > wptr ] = b ;
if ( + + q - > wptr = = KBD_QUEUE_SIZE )
q - > wptr = 0 ;
q - > count + + ;
kbd_update_irq ( s ) ;
}
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void kbd_put_keycode ( int keycode )
{
KBDState * s = & kbd_state ;
kbd_queue ( s , keycode , 0 ) ;
}
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uint32_t kbd_read_status ( CPUState * env , uint32_t addr )
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{
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KBDState * s = & kbd_state ;
int val ;
val = s - > status ;
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# if defined(DEBUG_KBD)
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printf ( " kbd: read status=0x%02x \n " , val ) ;
# endif
return val ;
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}
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void kbd_write_command ( CPUState * env , uint32_t addr , uint32_t val )
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{
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KBDState * s = & kbd_state ;
# ifdef DEBUG_KBD
printf ( " kbd: write cmd=0x%02x \n " , val ) ;
# endif
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switch ( val ) {
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case KBD_CCMD_READ_MODE :
kbd_queue ( s , s - > mode , 0 ) ;
break ;
case KBD_CCMD_WRITE_MODE :
case KBD_CCMD_WRITE_OBUF :
case KBD_CCMD_WRITE_AUX_OBUF :
case KBD_CCMD_WRITE_MOUSE :
case KBD_CCMD_WRITE_OUTPORT :
s - > write_cmd = val ;
break ;
case KBD_CCMD_MOUSE_DISABLE :
s - > mode | = KBD_MODE_DISABLE_MOUSE ;
break ;
case KBD_CCMD_MOUSE_ENABLE :
s - > mode & = ~ KBD_MODE_DISABLE_MOUSE ;
break ;
case KBD_CCMD_TEST_MOUSE :
kbd_queue ( s , 0x00 , 0 ) ;
break ;
case KBD_CCMD_SELF_TEST :
s - > status | = KBD_STAT_SELFTEST ;
kbd_queue ( s , 0x55 , 0 ) ;
break ;
case KBD_CCMD_KBD_TEST :
kbd_queue ( s , 0x00 , 0 ) ;
break ;
case KBD_CCMD_KBD_DISABLE :
s - > mode | = KBD_MODE_DISABLE_KBD ;
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kbd_update_irq ( s ) ;
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break ;
case KBD_CCMD_KBD_ENABLE :
s - > mode & = ~ KBD_MODE_DISABLE_KBD ;
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kbd_update_irq ( s ) ;
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break ;
case KBD_CCMD_READ_INPORT :
kbd_queue ( s , 0x00 , 0 ) ;
break ;
case KBD_CCMD_READ_OUTPORT :
/* XXX: check that */
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# ifdef TARGET_I386
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val = 0x01 | ( ( ( cpu_single_env - > a20_mask > > 20 ) & 1 ) < < 1 ) ;
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# else
val = 0x01 ;
# endif
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if ( s - > status & KBD_STAT_OBF )
val | = 0x10 ;
if ( s - > status & KBD_STAT_MOUSE_OBF )
val | = 0x20 ;
kbd_queue ( s , val , 0 ) ;
break ;
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# ifdef TARGET_I386
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case KBD_CCMD_ENABLE_A20 :
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cpu_x86_set_a20 ( env , 1 ) ;
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break ;
case KBD_CCMD_DISABLE_A20 :
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cpu_x86_set_a20 ( env , 0 ) ;
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break ;
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# endif
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case KBD_CCMD_RESET :
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reset_requested = 1 ;
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cpu_interrupt ( global_env , CPU_INTERRUPT_EXIT ) ;
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break ;
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case 0xff :
/* ignore that - I don't know what is its use */
break ;
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default :
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fprintf ( stderr , " qemu: unsupported keyboard cmd=0x%02x \n " , val ) ;
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break ;
}
}
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uint32_t kbd_read_data ( CPUState * env , uint32_t addr )
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{
KBDState * s = & kbd_state ;
KBDQueue * q ;
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int val , index ;
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q = & s - > queues [ 0 ] ; /* first check KBD data */
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if ( q - > count = = 0 )
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q = & s - > queues [ 1 ] ; /* then check AUX data */
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if ( q - > count = = 0 ) {
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/* NOTE: if no data left, we return the last keyboard one
( needed for EMM386 ) */
/* XXX: need a timer to do things correctly */
q = & s - > queues [ 0 ] ;
index = q - > rptr - 1 ;
if ( index < 0 )
index = KBD_QUEUE_SIZE - 1 ;
val = q - > data [ index ] ;
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} else {
val = q - > data [ q - > rptr ] ;
if ( + + q - > rptr = = KBD_QUEUE_SIZE )
q - > rptr = 0 ;
q - > count - - ;
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/* reading deasserts IRQ */
if ( q = = & s - > queues [ 0 ] )
pic_set_irq ( 1 , 0 ) ;
else
pic_set_irq ( 12 , 0 ) ;
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}
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/* reassert IRQs if data left */
kbd_update_irq ( s ) ;
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# ifdef DEBUG_KBD
printf ( " kbd: read data=0x%02x \n " , val ) ;
# endif
return val ;
}
static void kbd_reset_keyboard ( KBDState * s )
{
s - > scan_enabled = 1 ;
}
static void kbd_write_keyboard ( KBDState * s , int val )
{
switch ( s - > kbd_write_cmd ) {
default :
case - 1 :
switch ( val ) {
case 0x00 :
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
break ;
case 0x05 :
kbd_queue ( s , KBD_REPLY_RESEND , 0 ) ;
break ;
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case KBD_CMD_GET_ID :
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
kbd_queue ( s , 0xab , 0 ) ;
kbd_queue ( s , 0x83 , 0 ) ;
break ;
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case KBD_CMD_ECHO :
kbd_queue ( s , KBD_CMD_ECHO , 0 ) ;
break ;
case KBD_CMD_ENABLE :
s - > scan_enabled = 1 ;
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
break ;
case KBD_CMD_SET_LEDS :
case KBD_CMD_SET_RATE :
s - > kbd_write_cmd = val ;
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kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
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break ;
case KBD_CMD_RESET_DISABLE :
kbd_reset_keyboard ( s ) ;
s - > scan_enabled = 0 ;
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
break ;
case KBD_CMD_RESET_ENABLE :
kbd_reset_keyboard ( s ) ;
s - > scan_enabled = 1 ;
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
break ;
case KBD_CMD_RESET :
kbd_reset_keyboard ( s ) ;
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
kbd_queue ( s , KBD_REPLY_POR , 0 ) ;
break ;
default :
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
break ;
}
break ;
case KBD_CMD_SET_LEDS :
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
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s - > kbd_write_cmd = - 1 ;
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break ;
case KBD_CMD_SET_RATE :
kbd_queue ( s , KBD_REPLY_ACK , 0 ) ;
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s - > kbd_write_cmd = - 1 ;
break ;
}
}
static void kbd_mouse_send_packet ( KBDState * s )
{
unsigned int b ;
int dx1 , dy1 , dz1 ;
dx1 = s - > mouse_dx ;
dy1 = s - > mouse_dy ;
dz1 = s - > mouse_dz ;
/* XXX: increase range to 8 bits ? */
if ( dx1 > 127 )
dx1 = 127 ;
else if ( dx1 < - 127 )
dx1 = - 127 ;
if ( dy1 > 127 )
dy1 = 127 ;
else if ( dy1 < - 127 )
dy1 = - 127 ;
b = 0x08 | ( ( dx1 < 0 ) < < 4 ) | ( ( dy1 < 0 ) < < 5 ) | ( s - > mouse_buttons & 0x07 ) ;
kbd_queue ( s , b , 1 ) ;
kbd_queue ( s , dx1 & 0xff , 1 ) ;
kbd_queue ( s , dy1 & 0xff , 1 ) ;
/* extra byte for IMPS/2 or IMEX */
switch ( s - > mouse_type ) {
default :
break ;
case 3 :
if ( dz1 > 127 )
dz1 = 127 ;
else if ( dz1 < - 127 )
dz1 = - 127 ;
kbd_queue ( s , dz1 & 0xff , 1 ) ;
break ;
case 4 :
if ( dz1 > 7 )
dz1 = 7 ;
else if ( dz1 < - 7 )
dz1 = - 7 ;
b = ( dz1 & 0x0f ) | ( ( s - > mouse_buttons & 0x18 ) < < 1 ) ;
kbd_queue ( s , b , 1 ) ;
break ;
}
/* update deltas */
s - > mouse_dx - = dx1 ;
s - > mouse_dy - = dy1 ;
s - > mouse_dz - = dz1 ;
}
void kbd_mouse_event ( int dx , int dy , int dz , int buttons_state )
{
KBDState * s = & kbd_state ;
/* check if deltas are recorded when disabled */
if ( ! ( s - > mouse_status & MOUSE_STATUS_ENABLED ) )
return ;
s - > mouse_dx + = dx ;
s - > mouse_dy - = dy ;
s - > mouse_dz + = dz ;
s - > mouse_buttons = buttons_state ;
if ( ! ( s - > mouse_status & MOUSE_STATUS_REMOTE ) & &
( s - > queues [ 1 ] . count < ( KBD_QUEUE_SIZE - 16 ) ) ) {
for ( ; ; ) {
/* if not remote, send event. Multiple events are sent if
too big deltas */
kbd_mouse_send_packet ( s ) ;
if ( s - > mouse_dx = = 0 & & s - > mouse_dy = = 0 & & s - > mouse_dz = = 0 )
break ;
}
}
}
static void kbd_write_mouse ( KBDState * s , int val )
{
# ifdef DEBUG_MOUSE
printf ( " kbd: write mouse 0x%02x \n " , val ) ;
# endif
switch ( s - > mouse_write_cmd ) {
default :
case - 1 :
/* mouse command */
if ( s - > mouse_wrap ) {
if ( val = = AUX_RESET_WRAP ) {
s - > mouse_wrap = 0 ;
kbd_queue ( s , AUX_ACK , 1 ) ;
return ;
} else if ( val ! = AUX_RESET ) {
kbd_queue ( s , val , 1 ) ;
return ;
}
}
switch ( val ) {
case AUX_SET_SCALE11 :
s - > mouse_status & = ~ MOUSE_STATUS_SCALE21 ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_SET_SCALE21 :
s - > mouse_status | = MOUSE_STATUS_SCALE21 ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_SET_STREAM :
s - > mouse_status & = ~ MOUSE_STATUS_REMOTE ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_SET_WRAP :
s - > mouse_wrap = 1 ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_SET_REMOTE :
s - > mouse_status | = MOUSE_STATUS_REMOTE ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_GET_TYPE :
kbd_queue ( s , AUX_ACK , 1 ) ;
kbd_queue ( s , s - > mouse_type , 1 ) ;
break ;
case AUX_SET_RES :
case AUX_SET_SAMPLE :
s - > mouse_write_cmd = val ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_GET_SCALE :
kbd_queue ( s , AUX_ACK , 1 ) ;
kbd_queue ( s , s - > mouse_status , 1 ) ;
kbd_queue ( s , s - > mouse_resolution , 1 ) ;
kbd_queue ( s , s - > mouse_sample_rate , 1 ) ;
break ;
case AUX_POLL :
kbd_queue ( s , AUX_ACK , 1 ) ;
kbd_mouse_send_packet ( s ) ;
break ;
case AUX_ENABLE_DEV :
s - > mouse_status | = MOUSE_STATUS_ENABLED ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_DISABLE_DEV :
s - > mouse_status & = ~ MOUSE_STATUS_ENABLED ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_SET_DEFAULT :
s - > mouse_sample_rate = 100 ;
s - > mouse_resolution = 2 ;
s - > mouse_status = 0 ;
kbd_queue ( s , AUX_ACK , 1 ) ;
break ;
case AUX_RESET :
s - > mouse_sample_rate = 100 ;
s - > mouse_resolution = 2 ;
s - > mouse_status = 0 ;
kbd_queue ( s , AUX_ACK , 1 ) ;
kbd_queue ( s , 0xaa , 1 ) ;
kbd_queue ( s , s - > mouse_type , 1 ) ;
break ;
default :
break ;
}
break ;
case AUX_SET_SAMPLE :
s - > mouse_sample_rate = val ;
#if 0
/* detect IMPS/2 or IMEX */
switch ( s - > mouse_detect_state ) {
default :
case 0 :
if ( val = = 200 )
s - > mouse_detect_state = 1 ;
break ;
case 1 :
if ( val = = 100 )
s - > mouse_detect_state = 2 ;
else if ( val = = 200 )
s - > mouse_detect_state = 3 ;
else
s - > mouse_detect_state = 0 ;
break ;
case 2 :
if ( val = = 80 )
s - > mouse_type = 3 ; /* IMPS/2 */
s - > mouse_detect_state = 0 ;
break ;
case 3 :
if ( val = = 80 )
s - > mouse_type = 4 ; /* IMEX */
s - > mouse_detect_state = 0 ;
break ;
}
# endif
kbd_queue ( s , AUX_ACK , 1 ) ;
s - > mouse_write_cmd = - 1 ;
break ;
case AUX_SET_RES :
s - > mouse_resolution = val ;
kbd_queue ( s , AUX_ACK , 1 ) ;
s - > mouse_write_cmd = - 1 ;
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break ;
}
}
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void kbd_write_data ( CPUState * env , uint32_t addr , uint32_t val )
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{
KBDState * s = & kbd_state ;
# ifdef DEBUG_KBD
printf ( " kbd: write data=0x%02x \n " , val ) ;
# endif
switch ( s - > write_cmd ) {
case 0 :
kbd_write_keyboard ( s , val ) ;
break ;
case KBD_CCMD_WRITE_MODE :
s - > mode = val ;
kbd_update_irq ( s ) ;
break ;
case KBD_CCMD_WRITE_OBUF :
kbd_queue ( s , val , 0 ) ;
break ;
case KBD_CCMD_WRITE_AUX_OBUF :
kbd_queue ( s , val , 1 ) ;
break ;
case KBD_CCMD_WRITE_OUTPORT :
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# ifdef TARGET_I386
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cpu_x86_set_a20 ( env , ( val > > 1 ) & 1 ) ;
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# endif
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if ( ! ( val & 1 ) ) {
reset_requested = 1 ;
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cpu_interrupt ( global_env , CPU_INTERRUPT_EXIT ) ;
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}
break ;
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case KBD_CCMD_WRITE_MOUSE :
kbd_write_mouse ( s , val ) ;
break ;
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default :
break ;
}
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s - > write_cmd = 0 ;
}
void kbd_reset ( KBDState * s )
{
KBDQueue * q ;
int i ;
s - > kbd_write_cmd = - 1 ;
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s - > mouse_write_cmd = - 1 ;
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s - > mode = KBD_MODE_KBD_INT | KBD_MODE_MOUSE_INT ;
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s - > status = KBD_STAT_CMD | KBD_STAT_UNLOCKED ;
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for ( i = 0 ; i < 2 ; i + + ) {
q = & s - > queues [ i ] ;
q - > rptr = 0 ;
q - > wptr = 0 ;
q - > count = 0 ;
}
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}
void kbd_init ( void )
{
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kbd_reset ( & kbd_state ) ;
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# if defined (TARGET_I386) || defined (TARGET_PPC)
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register_ioport_read ( 0x60 , 1 , kbd_read_data , 1 ) ;
register_ioport_write ( 0x60 , 1 , kbd_write_data , 1 ) ;
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register_ioport_read ( 0x64 , 1 , kbd_read_status , 1 ) ;
register_ioport_write ( 0x64 , 1 , kbd_write_command , 1 ) ;
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# endif
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}
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/***********************************************************/
/* Bochs BIOS debug ports */
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# ifdef TARGET_I386
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void bochs_bios_write ( CPUX86State * env , uint32_t addr , uint32_t val )
{
switch ( addr ) {
/* Bochs BIOS messages */
case 0x400 :
case 0x401 :
fprintf ( stderr , " BIOS panic at rombios.c, line %d \n " , val ) ;
exit ( 1 ) ;
case 0x402 :
case 0x403 :
# ifdef DEBUG_BIOS
fprintf ( stderr , " %c " , val ) ;
# endif
break ;
/* LGPL'ed VGA BIOS messages */
case 0x501 :
case 0x502 :
fprintf ( stderr , " VGA BIOS panic, line %d \n " , val ) ;
exit ( 1 ) ;
case 0x500 :
case 0x503 :
# ifdef DEBUG_BIOS
fprintf ( stderr , " %c " , val ) ;
# endif
break ;
}
}
void bochs_bios_init ( void )
{
register_ioport_write ( 0x400 , 1 , bochs_bios_write , 2 ) ;
register_ioport_write ( 0x401 , 1 , bochs_bios_write , 2 ) ;
register_ioport_write ( 0x402 , 1 , bochs_bios_write , 1 ) ;
register_ioport_write ( 0x403 , 1 , bochs_bios_write , 1 ) ;
register_ioport_write ( 0x501 , 1 , bochs_bios_write , 2 ) ;
register_ioport_write ( 0x502 , 1 , bochs_bios_write , 2 ) ;
register_ioport_write ( 0x500 , 1 , bochs_bios_write , 1 ) ;
register_ioport_write ( 0x503 , 1 , bochs_bios_write , 1 ) ;
}
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# endif
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/***********************************************************/
/* dumb display */
/* init terminal so that we can grab keys */
static struct termios oldtty ;
static void term_exit ( void )
{
tcsetattr ( 0 , TCSANOW , & oldtty ) ;
}
static void term_init ( void )
{
struct termios tty ;
tcgetattr ( 0 , & tty ) ;
oldtty = tty ;
tty . c_iflag & = ~ ( IGNBRK | BRKINT | PARMRK | ISTRIP
| INLCR | IGNCR | ICRNL | IXON ) ;
tty . c_oflag | = OPOST ;
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tty . c_lflag & = ~ ( ECHO | ECHONL | ICANON | IEXTEN ) ;
/* if graphical mode, we allow Ctrl-C handling */
if ( nographic )
tty . c_lflag & = ~ ISIG ;
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tty . c_cflag & = ~ ( CSIZE | PARENB ) ;
tty . c_cflag | = CS8 ;
tty . c_cc [ VMIN ] = 1 ;
tty . c_cc [ VTIME ] = 0 ;
tcsetattr ( 0 , TCSANOW , & tty ) ;
atexit ( term_exit ) ;
fcntl ( 0 , F_SETFL , O_NONBLOCK ) ;
}
static void dumb_update ( DisplayState * ds , int x , int y , int w , int h )
{
}
static void dumb_resize ( DisplayState * ds , int w , int h )
{
}
static void dumb_refresh ( DisplayState * ds )
{
vga_update_display ( ) ;
}
void dumb_display_init ( DisplayState * ds )
{
ds - > data = NULL ;
ds - > linesize = 0 ;
ds - > depth = 0 ;
ds - > dpy_update = dumb_update ;
ds - > dpy_resize = dumb_resize ;
ds - > dpy_refresh = dumb_refresh ;
}
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# if !defined(CONFIG_SOFTMMU)
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/***********************************************************/
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/* cpu signal handler */
static void host_segv_handler ( int host_signum , siginfo_t * info ,
void * puc )
{
if ( cpu_signal_handler ( host_signum , info , puc ) )
return ;
term_exit ( ) ;
abort ( ) ;
}
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# endif
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static int timer_irq_pending ;
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static int timer_irq_count ;
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static int timer_ms ;
static int gui_refresh_pending , gui_refresh_count ;
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static void host_alarm_handler ( int host_signum , siginfo_t * info ,
void * puc )
{
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/* NOTE: since usually the OS asks a 100 Hz clock, there can be
some drift between cpu_get_ticks ( ) and the interrupt time . So
we queue some interrupts to avoid missing some */
timer_irq_count + = pit_get_out_edges ( & pit_channels [ 0 ] ) ;
if ( timer_irq_count ) {
if ( timer_irq_count > 2 )
timer_irq_count = 2 ;
timer_irq_count - - ;
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timer_irq_pending = 1 ;
}
gui_refresh_count + = timer_ms ;
if ( gui_refresh_count > = GUI_REFRESH_INTERVAL ) {
gui_refresh_count = 0 ;
gui_refresh_pending = 1 ;
}
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/* XXX: seems dangerous to run that here. */
DMA_run ( ) ;
SB16_run ( ) ;
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if ( gui_refresh_pending | | timer_irq_pending ) {
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/* just exit from the cpu to have a chance to handle timers */
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cpu_interrupt ( global_env , CPU_INTERRUPT_EXIT ) ;
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}
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}
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/* main execution loop */
CPUState * cpu_gdbstub_get_env ( void * opaque )
{
return global_env ;
}
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int main_loop ( void * opaque )
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{
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struct pollfd ufds [ 3 ] , * pf , * serial_ufd , * gdb_ufd ;
# if defined (TARGET_I386)
struct pollfd * net_ufd ;
# endif
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int ret , n , timeout , serial_ok ;
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uint8_t ch ;
CPUState * env = global_env ;
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if ( ! term_inited ) {
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/* initialize terminal only there so that the user has a
chance to stop QEMU with Ctrl - C before the gdb connection
is launched */
term_inited = 1 ;
term_init ( ) ;
}
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serial_ok = 1 ;
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cpu_enable_ticks ( ) ;
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for ( ; ; ) {
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# if defined (DO_TB_FLUSH)
tb_flush ( ) ;
# endif
ret = cpu_exec ( env ) ;
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if ( reset_requested ) {
ret = EXCP_INTERRUPT ;
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break ;
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}
if ( ret = = EXCP_DEBUG ) {
ret = EXCP_DEBUG ;
break ;
}
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/* if hlt instruction, we wait until the next IRQ */
if ( ret = = EXCP_HLT )
timeout = 10 ;
else
timeout = 0 ;
/* poll any events */
serial_ufd = NULL ;
pf = ufds ;
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if ( serial_ok & & ! ( serial_ports [ 0 ] . lsr & UART_LSR_DR ) ) {
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serial_ufd = pf ;
pf - > fd = 0 ;
pf - > events = POLLIN ;
pf + + ;
}
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# if defined (TARGET_I386)
2003-06-27 19:34:32 +02:00
net_ufd = NULL ;
if ( net_fd > 0 & & ne2000_can_receive ( & ne2000_state ) ) {
net_ufd = pf ;
pf - > fd = net_fd ;
pf - > events = POLLIN ;
pf + + ;
}
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# endif
2003-06-27 19:34:32 +02:00
gdb_ufd = NULL ;
if ( gdbstub_fd > 0 ) {
gdb_ufd = pf ;
pf - > fd = gdbstub_fd ;
pf - > events = POLLIN ;
pf + + ;
}
ret = poll ( ufds , pf - ufds , timeout ) ;
if ( ret > 0 ) {
if ( serial_ufd & & ( serial_ufd - > revents & POLLIN ) ) {
n = read ( 0 , & ch , 1 ) ;
if ( n = = 1 ) {
serial_received_byte ( & serial_ports [ 0 ] , ch ) ;
2003-09-30 23:40:47 +02:00
} else {
/* Closed, stop polling. */
serial_ok = 0 ;
2003-06-27 19:34:32 +02:00
}
}
2004-01-05 01:02:06 +01:00
# if defined (TARGET_I386)
2003-06-27 19:34:32 +02:00
if ( net_ufd & & ( net_ufd - > revents & POLLIN ) ) {
uint8_t buf [ MAX_ETH_FRAME_SIZE ] ;
n = read ( net_fd , buf , MAX_ETH_FRAME_SIZE ) ;
if ( n > 0 ) {
if ( n < 60 ) {
memset ( buf + n , 0 , 60 - n ) ;
n = 60 ;
}
ne2000_receive ( & ne2000_state , buf , n ) ;
}
}
2004-01-05 01:02:06 +01:00
# endif
2003-06-27 19:34:32 +02:00
if ( gdb_ufd & & ( gdb_ufd - > revents & POLLIN ) ) {
uint8_t buf [ 1 ] ;
/* stop emulation if requested by gdb */
n = read ( gdbstub_fd , buf , 1 ) ;
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if ( n = = 1 ) {
ret = EXCP_INTERRUPT ;
2003-06-27 19:34:32 +02:00
break ;
2003-10-05 16:28:56 +02:00
}
2003-06-27 19:34:32 +02:00
}
}
/* timer IRQ */
if ( timer_irq_pending ) {
2004-01-05 01:02:06 +01:00
# if defined (TARGET_I386)
2003-06-27 19:34:32 +02:00
pic_set_irq ( 0 , 1 ) ;
pic_set_irq ( 0 , 0 ) ;
timer_irq_pending = 0 ;
2003-11-16 16:59:30 +01:00
/* XXX: RTC test */
2003-11-16 20:46:01 +01:00
if ( cmos_data [ RTC_REG_B ] & 0x50 ) {
2003-11-16 16:59:30 +01:00
pic_set_irq ( 8 , 1 ) ;
}
2004-01-05 01:02:06 +01:00
# endif
2003-06-27 19:34:32 +02:00
}
2003-08-10 23:52:11 +02:00
/* VGA */
if ( gui_refresh_pending ) {
display_state . dpy_refresh ( & display_state ) ;
gui_refresh_pending = 0 ;
}
2003-06-27 19:34:32 +02:00
}
2003-10-05 16:28:56 +02:00
cpu_disable_ticks ( ) ;
return ret ;
2003-06-27 19:34:32 +02:00
}
2003-06-24 15:42:40 +02:00
void help ( void )
{
2003-09-30 23:07:02 +02:00
printf ( " QEMU PC emulator version " QEMU_VERSION " , Copyright (c) 2003 Fabrice Bellard \n "
2003-10-27 22:37:46 +01:00
" usage: %s [options] [disk_image] \n "
2003-06-24 15:42:40 +02:00
" \n "
2003-09-30 23:07:02 +02:00
" 'disk_image' is a raw hard image image for IDE hard disk 0 \n "
2003-06-30 12:03:06 +02:00
" \n "
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" Standard options: \n "
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" -fda/-fdb file use 'file' as floppy disk 0/1 image \n "
2003-11-11 14:36:08 +01:00
" -hda/-hdb file use 'file' as IDE hard disk 0/1 image \n "
" -hdc/-hdd file use 'file' as IDE hard disk 2/3 image \n "
" -cdrom file use 'file' as IDE cdrom 2 image \n "
2004-01-18 22:56:49 +01:00
" -boot [a|b|c|d] boot on floppy (a, b), hard disk (c) or CD-ROM (d) \n "
2003-09-30 23:07:02 +02:00
" -snapshot write to temporary files instead of disk image files \n "
" -m megs set virtual RAM size to megs MB \n "
" -n script set network init script [default=%s] \n "
2003-10-01 00:11:17 +02:00
" -tun-fd fd this fd talks to tap/tun, use it. \n "
2003-09-30 23:07:02 +02:00
" -nographic disable graphical output \n "
" \n "
" Linux boot specific (does not require PC BIOS): \n "
" -kernel bzImage use 'bzImage' as kernel image \n "
" -append cmdline use 'cmdline' as kernel command line \n "
" -initrd file use 'file' as initial ram disk \n "
2003-06-30 12:03:06 +02:00
" \n "
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" Debug/Expert options: \n "
2003-09-30 23:07:02 +02:00
" -s wait gdb connection to port %d \n "
" -p port change gdb connection port \n "
2004-01-18 22:56:49 +01:00
" -d output log to %s \n "
2003-09-30 23:07:02 +02:00
" -hdachs c,h,s force hard disk 0 geometry (usually qemu can guess it) \n "
" -L path set the directory for the BIOS and VGA BIOS \n "
2004-02-16 23:05:46 +01:00
# ifdef USE_CODE_COPY
" -no-code-copy disable code copy acceleration \n "
# endif
2003-06-24 15:42:40 +02:00
" \n "
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" During emulation, use C-a h to get terminal commands: \n " ,
2003-10-27 22:37:46 +01:00
# ifdef CONFIG_SOFTMMU
" qemu " ,
# else
" qemu-fast " ,
# endif
DEFAULT_NETWORK_SCRIPT ,
2004-01-18 22:56:49 +01:00
DEFAULT_GDBSTUB_PORT ,
" /tmp/qemu.log " ) ;
2003-06-24 15:42:40 +02:00
term_print_help ( ) ;
2003-10-27 22:37:46 +01:00
# ifndef CONFIG_SOFTMMU
printf ( " \n "
" NOTE: this version of QEMU is faster but it needs slightly patched OSes to \n "
" work. Please use the 'qemu' executable to have a more accurate (but slower) \n "
" PC emulation. \n " ) ;
# endif
2003-06-24 15:42:40 +02:00
exit ( 1 ) ;
}
2003-06-30 12:03:06 +02:00
struct option long_options [ ] = {
{ " initrd " , 1 , NULL , 0 , } ,
{ " hda " , 1 , NULL , 0 , } ,
{ " hdb " , 1 , NULL , 0 , } ,
2003-07-06 19:15:21 +02:00
{ " snapshot " , 0 , NULL , 0 , } ,
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{ " hdachs " , 1 , NULL , 0 , } ,
2003-09-30 23:07:02 +02:00
{ " nographic " , 0 , NULL , 0 , } ,
{ " kernel " , 1 , NULL , 0 , } ,
{ " append " , 1 , NULL , 0 , } ,
2003-10-01 00:11:17 +02:00
{ " tun-fd " , 1 , NULL , 0 , } ,
2003-11-11 14:36:08 +01:00
{ " hdc " , 1 , NULL , 0 , } ,
{ " hdd " , 1 , NULL , 0 , } ,
{ " cdrom " , 1 , NULL , 0 , } ,
{ " boot " , 1 , NULL , 0 , } ,
2004-01-05 01:02:06 +01:00
{ " fda " , 1 , NULL , 0 , } ,
{ " fdb " , 1 , NULL , 0 , } ,
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{ " no-code-copy " , 0 , NULL , 0 } ,
2003-06-30 12:03:06 +02:00
{ NULL , 0 , NULL , 0 } ,
} ;
2003-09-30 23:07:02 +02:00
# ifdef CONFIG_SDL
/* SDL use the pthreads and they modify sigaction. We don't
want that . */
2004-01-04 19:18:57 +01:00
# if __GLIBC__ > 2 || (__GLIBC__ == 2 && __GLIBC_MINOR__ >= 2)
2003-09-30 23:07:02 +02:00
extern void __libc_sigaction ( ) ;
# define sigaction(sig, act, oact) __libc_sigaction(sig, act, oact)
# else
extern void __sigaction ( ) ;
# define sigaction(sig, act, oact) __sigaction(sig, act, oact)
# endif
# endif /* CONFIG_SDL */
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# if defined (TARGET_I386) && defined(USE_CODE_COPY)
/* this stack is only used during signal handling */
# define SIGNAL_STACK_SIZE 32768
static uint8_t * signal_stack ;
# endif
2003-06-24 15:42:40 +02:00
int main ( int argc , char * * argv )
{
2003-06-30 12:03:06 +02:00
int c , ret , initrd_size , i , use_gdbstub , gdbstub_port , long_index ;
2004-02-06 20:46:14 +01:00
int snapshot , linux_boot ;
2003-06-24 15:42:40 +02:00
struct sigaction act ;
struct itimerval itv ;
2004-01-05 01:02:06 +01:00
CPUState * env ;
2003-10-30 02:11:23 +01:00
const char * initrd_filename ;
2004-01-05 01:02:06 +01:00
const char * hd_filename [ MAX_DISKS ] , * fd_filename [ MAX_FD ] ;
2003-09-30 23:07:02 +02:00
const char * kernel_filename , * kernel_cmdline ;
2004-02-16 23:05:46 +01:00
char buf [ 1024 ] ;
2003-08-10 23:52:11 +02:00
DisplayState * ds = & display_state ;
2003-06-24 15:42:40 +02:00
/* we never want that malloc() uses mmap() */
mallopt ( M_MMAP_THRESHOLD , 4096 * 1024 ) ;
2003-06-30 12:03:06 +02:00
initrd_filename = NULL ;
2004-01-05 01:02:06 +01:00
for ( i = 0 ; i < MAX_FD ; i + + )
fd_filename [ i ] = NULL ;
2003-06-30 12:03:06 +02:00
for ( i = 0 ; i < MAX_DISKS ; i + + )
hd_filename [ i ] = NULL ;
2004-02-06 20:46:14 +01:00
ram_size = 32 * 1024 * 1024 ;
2003-08-10 23:52:11 +02:00
vga_ram_size = VGA_RAM_SIZE ;
2004-01-05 01:02:06 +01:00
# if defined (TARGET_I386)
2003-06-25 02:07:40 +02:00
pstrcpy ( network_script , sizeof ( network_script ) , DEFAULT_NETWORK_SCRIPT ) ;
2004-01-05 01:02:06 +01:00
# endif
2003-06-27 19:34:32 +02:00
use_gdbstub = 0 ;
gdbstub_port = DEFAULT_GDBSTUB_PORT ;
2003-07-06 19:15:21 +02:00
snapshot = 0 ;
2003-09-30 23:07:02 +02:00
nographic = 0 ;
kernel_filename = NULL ;
kernel_cmdline = " " ;
2003-06-24 15:42:40 +02:00
for ( ; ; ) {
2003-07-26 20:11:40 +02:00
c = getopt_long_only ( argc , argv , " hm:dn:sp:L: " , long_options , & long_index ) ;
2003-06-24 15:42:40 +02:00
if ( c = = - 1 )
break ;
switch ( c ) {
2003-06-30 12:03:06 +02:00
case 0 :
switch ( long_index ) {
case 0 :
initrd_filename = optarg ;
break ;
case 1 :
hd_filename [ 0 ] = optarg ;
break ;
case 2 :
hd_filename [ 1 ] = optarg ;
break ;
2003-07-06 19:15:21 +02:00
case 3 :
snapshot = 1 ;
break ;
2003-07-26 20:11:40 +02:00
case 4 :
{
int cyls , heads , secs ;
const char * p ;
p = optarg ;
cyls = strtol ( p , ( char * * ) & p , 0 ) ;
if ( * p ! = ' , ' )
goto chs_fail ;
p + + ;
heads = strtol ( p , ( char * * ) & p , 0 ) ;
if ( * p ! = ' , ' )
goto chs_fail ;
p + + ;
secs = strtol ( p , ( char * * ) & p , 0 ) ;
if ( * p ! = ' \0 ' )
goto chs_fail ;
2003-11-11 14:48:59 +01:00
ide_set_geometry ( 0 , cyls , heads , secs ) ;
2003-07-26 20:11:40 +02:00
chs_fail : ;
}
break ;
2003-08-10 23:52:11 +02:00
case 5 :
2003-09-30 23:07:02 +02:00
nographic = 1 ;
break ;
case 6 :
kernel_filename = optarg ;
break ;
case 7 :
kernel_cmdline = optarg ;
2003-08-10 23:52:11 +02:00
break ;
2004-01-05 01:02:06 +01:00
# if defined (TARGET_I386)
2003-10-01 00:11:17 +02:00
case 8 :
net_fd = atoi ( optarg ) ;
break ;
2004-01-05 01:02:06 +01:00
# endif
2003-11-11 14:36:08 +01:00
case 9 :
hd_filename [ 2 ] = optarg ;
break ;
case 10 :
hd_filename [ 3 ] = optarg ;
break ;
case 11 :
hd_filename [ 2 ] = optarg ;
2003-11-11 14:48:59 +01:00
ide_set_cdrom ( 2 , 1 ) ;
2003-11-11 14:36:08 +01:00
break ;
case 12 :
boot_device = optarg [ 0 ] ;
2004-01-05 01:02:06 +01:00
if ( boot_device ! = ' a ' & & boot_device ! = ' b ' & &
boot_device ! = ' c ' & & boot_device ! = ' d ' ) {
2003-11-11 14:36:08 +01:00
fprintf ( stderr , " qemu: invalid boot device '%c' \n " , boot_device ) ;
exit ( 1 ) ;
}
break ;
2004-01-05 01:02:06 +01:00
case 13 :
fd_filename [ 0 ] = optarg ;
break ;
case 14 :
fd_filename [ 1 ] = optarg ;
break ;
2004-02-16 23:05:46 +01:00
case 15 :
code_copy_enabled = 0 ;
break ;
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}
break ;
2003-06-24 15:42:40 +02:00
case ' h ' :
help ( ) ;
break ;
case ' m ' :
2004-02-06 20:46:14 +01:00
ram_size = atoi ( optarg ) * 1024 * 1024 ;
if ( ram_size < = 0 )
2003-06-24 15:42:40 +02:00
help ( ) ;
2004-02-06 20:46:14 +01:00
if ( ram_size > PHYS_RAM_MAX_SIZE ) {
2003-11-11 14:36:08 +01:00
fprintf ( stderr , " qemu: at most %d MB RAM can be simulated \n " ,
2003-07-01 18:27:45 +02:00
PHYS_RAM_MAX_SIZE / ( 1024 * 1024 ) ) ;
exit ( 1 ) ;
}
2003-06-24 15:42:40 +02:00
break ;
case ' d ' :
2003-10-05 16:28:56 +02:00
cpu_set_log ( CPU_LOG_ALL ) ;
2003-06-24 15:42:40 +02:00
break ;
2004-01-05 01:02:06 +01:00
# if defined (TARGET_I386)
2003-06-25 02:07:40 +02:00
case ' n ' :
pstrcpy ( network_script , sizeof ( network_script ) , optarg ) ;
break ;
2004-01-05 01:02:06 +01:00
# endif
2003-06-27 19:34:32 +02:00
case ' s ' :
use_gdbstub = 1 ;
break ;
case ' p ' :
gdbstub_port = atoi ( optarg ) ;
break ;
2003-07-26 20:11:40 +02:00
case ' L ' :
2003-10-01 02:13:48 +02:00
bios_dir = optarg ;
2003-07-26 20:11:40 +02:00
break ;
2003-06-24 15:42:40 +02:00
}
}
2003-07-26 20:11:40 +02:00
2003-09-30 23:07:02 +02:00
if ( optind < argc ) {
hd_filename [ 0 ] = argv [ optind + + ] ;
}
linux_boot = ( kernel_filename ! = NULL ) ;
2003-07-26 20:11:40 +02:00
2004-01-05 01:02:06 +01:00
if ( ! linux_boot & & hd_filename [ 0 ] = = ' \0 ' & & hd_filename [ 2 ] = = ' \0 ' & &
fd_filename [ 0 ] = = ' \0 ' )
2003-06-24 15:42:40 +02:00
help ( ) ;
2003-11-16 20:46:01 +01:00
/* boot to cd by default if no hard disk */
2004-01-18 23:35:25 +01:00
if ( hd_filename [ 0 ] = = ' \0 ' & & boot_device = = ' c ' ) {
if ( fd_filename [ 0 ] ! = ' \0 ' )
boot_device = ' a ' ;
else
boot_device = ' d ' ;
}
2003-06-24 15:42:40 +02:00
2004-01-04 19:18:57 +01:00
# if !defined(CONFIG_SOFTMMU)
/* must avoid mmap() usage of glibc by setting a buffer "by hand" */
{
static uint8_t stdout_buf [ 4096 ] ;
setvbuf ( stdout , stdout_buf , _IOLBF , sizeof ( stdout_buf ) ) ;
}
# else
2003-07-01 01:36:21 +02:00
setvbuf ( stdout , NULL , _IOLBF , 0 ) ;
2004-01-04 19:18:57 +01:00
# endif
2003-06-24 15:42:40 +02:00
2003-06-25 02:07:40 +02:00
/* init network tun interface */
2004-01-05 01:02:06 +01:00
# if defined (TARGET_I386)
2003-10-01 00:11:17 +02:00
if ( net_fd < 0 )
net_init ( ) ;
2004-01-05 01:02:06 +01:00
# endif
2003-06-25 02:07:40 +02:00
2003-06-24 15:42:40 +02:00
/* init the memory */
2004-02-06 20:46:14 +01:00
phys_ram_size = ram_size + vga_ram_size ;
2003-10-30 02:11:23 +01:00
# ifdef CONFIG_SOFTMMU
2004-02-06 20:46:14 +01:00
phys_ram_base = memalign ( TARGET_PAGE_SIZE , phys_ram_size ) ;
2003-10-30 02:11:23 +01:00
if ( ! phys_ram_base ) {
fprintf ( stderr , " Could not allocate physical memory \n " ) ;
2003-06-24 15:42:40 +02:00
exit ( 1 ) ;
}
2003-10-30 02:11:23 +01:00
# else
/* as we must map the same page at several addresses, we must use
a fd */
{
const char * tmpdir ;
tmpdir = getenv ( " QEMU_TMPDIR " ) ;
if ( ! tmpdir )
tmpdir = " /tmp " ;
snprintf ( phys_ram_file , sizeof ( phys_ram_file ) , " %s/vlXXXXXX " , tmpdir ) ;
if ( mkstemp ( phys_ram_file ) < 0 ) {
fprintf ( stderr , " Could not create temporary memory file '%s' \n " ,
phys_ram_file ) ;
exit ( 1 ) ;
}
phys_ram_fd = open ( phys_ram_file , O_CREAT | O_TRUNC | O_RDWR , 0600 ) ;
if ( phys_ram_fd < 0 ) {
fprintf ( stderr , " Could not open temporary memory file '%s' \n " ,
phys_ram_file ) ;
exit ( 1 ) ;
}
2004-02-06 20:46:14 +01:00
ftruncate ( phys_ram_fd , phys_ram_size ) ;
2003-10-30 02:11:23 +01:00
unlink ( phys_ram_file ) ;
2004-02-06 20:46:14 +01:00
phys_ram_base = mmap ( get_mmap_addr ( phys_ram_size ) ,
phys_ram_size ,
2003-10-30 02:11:23 +01:00
PROT_WRITE | PROT_READ , MAP_SHARED | MAP_FIXED ,
phys_ram_fd , 0 ) ;
if ( phys_ram_base = = MAP_FAILED ) {
fprintf ( stderr , " Could not map physical memory \n " ) ;
exit ( 1 ) ;
}
}
# endif
2003-06-24 15:42:40 +02:00
2003-07-06 19:15:21 +02:00
/* open the virtual block devices */
for ( i = 0 ; i < MAX_DISKS ; i + + ) {
if ( hd_filename [ i ] ) {
bs_table [ i ] = bdrv_open ( hd_filename [ i ] , snapshot ) ;
if ( ! bs_table [ i ] ) {
2003-11-11 14:36:08 +01:00
fprintf ( stderr , " qemu: could not open hard disk image '%s \n " ,
2003-07-06 19:15:21 +02:00
hd_filename [ i ] ) ;
exit ( 1 ) ;
}
}
}
2003-07-26 20:11:40 +02:00
/* init CPU state */
env = cpu_init ( ) ;
global_env = env ;
cpu_single_env = env ;
init_ioports ( ) ;
2003-06-24 15:42:40 +02:00
2003-08-10 23:52:11 +02:00
/* allocate RAM */
2004-02-06 20:46:14 +01:00
cpu_register_physical_memory ( 0 , ram_size , 0 ) ;
2003-08-10 23:52:11 +02:00
2004-02-16 23:05:46 +01:00
# if defined(TARGET_I386)
/* RAW PC boot */
/* BIOS load */
snprintf ( buf , sizeof ( buf ) , " %s/%s " , bios_dir , BIOS_FILENAME ) ;
ret = load_image ( buf , phys_ram_base + 0x000f0000 ) ;
if ( ret ! = 0x10000 ) {
fprintf ( stderr , " qemu: could not load PC bios '%s' \n " , buf ) ;
exit ( 1 ) ;
}
/* VGA BIOS load */
snprintf ( buf , sizeof ( buf ) , " %s/%s " , bios_dir , VGABIOS_FILENAME ) ;
ret = load_image ( buf , phys_ram_base + 0x000c0000 ) ;
/* setup basic memory access */
cpu_register_physical_memory ( 0xc0000 , 0x10000 , 0xc0000 | IO_MEM_ROM ) ;
cpu_register_physical_memory ( 0xf0000 , 0x10000 , 0xf0000 | IO_MEM_ROM ) ;
bochs_bios_init ( ) ;
2003-07-26 20:11:40 +02:00
if ( linux_boot ) {
2004-02-16 23:05:46 +01:00
extern uint8_t linux_boot_start ;
extern uint8_t linux_boot_end ;
if ( bs_table [ 0 ] = = NULL ) {
fprintf ( stderr , " A disk image must be given for 'hda' when booting a Linux kernel \n " ) ;
exit ( 1 ) ;
}
bdrv_set_boot_sector ( bs_table [ 0 ] , & linux_boot_start ,
& linux_boot_end - & linux_boot_start ) ;
2003-07-26 20:11:40 +02:00
/* now we can load the kernel */
2004-02-16 23:05:46 +01:00
ret = load_kernel ( kernel_filename ,
phys_ram_base + KERNEL_LOAD_ADDR ,
phys_ram_base + KERNEL_PARAMS_ADDR ) ;
2003-07-26 20:11:40 +02:00
if ( ret < 0 ) {
2003-11-11 14:36:08 +01:00
fprintf ( stderr , " qemu: could not load kernel '%s' \n " ,
2003-09-30 23:07:02 +02:00
kernel_filename ) ;
2003-06-30 12:03:06 +02:00
exit ( 1 ) ;
}
2003-07-26 20:11:40 +02:00
/* load initrd */
initrd_size = 0 ;
if ( initrd_filename ) {
initrd_size = load_image ( initrd_filename , phys_ram_base + INITRD_LOAD_ADDR ) ;
if ( initrd_size < 0 ) {
2003-11-11 14:36:08 +01:00
fprintf ( stderr , " qemu: could not load initial ram disk '%s' \n " ,
2003-07-26 20:11:40 +02:00
initrd_filename ) ;
exit ( 1 ) ;
}
}
if ( initrd_size > 0 ) {
2004-02-16 23:05:46 +01:00
stl_raw ( phys_ram_base + KERNEL_PARAMS_ADDR + 0x218 , INITRD_LOAD_ADDR ) ;
stl_raw ( phys_ram_base + KERNEL_PARAMS_ADDR + 0x21c , initrd_size ) ;
2003-07-26 20:11:40 +02:00
}
2004-02-16 23:05:46 +01:00
pstrcpy ( phys_ram_base + KERNEL_CMDLINE_ADDR , 4096 ,
kernel_cmdline ) ;
stw_raw ( phys_ram_base + KERNEL_PARAMS_ADDR + 0x20 , 0xA33F ) ;
stw_raw ( phys_ram_base + KERNEL_PARAMS_ADDR + 0x22 ,
KERNEL_CMDLINE_ADDR - KERNEL_PARAMS_ADDR ) ;
/* loader type */
stw_raw ( phys_ram_base + KERNEL_PARAMS_ADDR + 0x210 , 0x01 ) ;
}
2004-01-05 01:02:06 +01:00
# elif defined(TARGET_PPC)
2004-02-16 23:05:46 +01:00
/* allocate ROM */
// snprintf(buf, sizeof(buf), "%s/%s", bios_dir, BIOS_FILENAME);
snprintf ( buf , sizeof ( buf ) , " %s " , BIOS_FILENAME ) ;
printf ( " load BIOS at %p \n " , phys_ram_base + 0x000f0000 ) ;
ret = load_image ( buf , phys_ram_base + 0x000f0000 ) ;
if ( ret ! = 0x10000 ) {
fprintf ( stderr , " qemu: could not load PPC bios '%s' (%d) \n %m \n " ,
buf , ret ) ;
exit ( 1 ) ;
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}
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# endif
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/* terminal init */
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if ( nographic ) {
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dumb_display_init ( ds ) ;
} else {
# ifdef CONFIG_SDL
sdl_display_init ( ds ) ;
# else
dumb_display_init ( ds ) ;
# endif
}
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/* init basic PC hardware */
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register_ioport_write ( 0x80 , 1 , ioport80_write , 1 ) ;
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vga_initialize ( ds , phys_ram_base + ram_size , ram_size ,
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vga_ram_size ) ;
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# if defined (TARGET_I386)
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cmos_init ( ) ;
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# endif
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pic_init ( ) ;
pit_init ( ) ;
serial_init ( ) ;
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# if defined (TARGET_I386)
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ne2000_init ( ) ;
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# endif
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ide_init ( ) ;
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kbd_init ( ) ;
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AUD_init ( ) ;
DMA_init ( ) ;
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# if defined (TARGET_I386)
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SB16_init ( ) ;
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# endif
# if defined (TARGET_PPC)
PPC_end_init ( ) ;
# endif
fdctrl_register ( ( unsigned char * * ) fd_filename , snapshot , boot_device ) ;
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/* setup cpu signal handlers for MMU / self modifying code handling */
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# if !defined(CONFIG_SOFTMMU)
# if defined (TARGET_I386) && defined(USE_CODE_COPY)
{
stack_t stk ;
signal_stack = malloc ( SIGNAL_STACK_SIZE ) ;
stk . ss_sp = signal_stack ;
stk . ss_size = SIGNAL_STACK_SIZE ;
stk . ss_flags = 0 ;
if ( sigaltstack ( & stk , NULL ) < 0 ) {
perror ( " sigaltstack " ) ;
exit ( 1 ) ;
}
}
# endif
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sigfillset ( & act . sa_mask ) ;
act . sa_flags = SA_SIGINFO ;
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# if defined (TARGET_I386) && defined(USE_CODE_COPY)
act . sa_flags | = SA_ONSTACK ;
# endif
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act . sa_sigaction = host_segv_handler ;
sigaction ( SIGSEGV , & act , NULL ) ;
sigaction ( SIGBUS , & act , NULL ) ;
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# if defined (TARGET_I386) && defined(USE_CODE_COPY)
sigaction ( SIGFPE , & act , NULL ) ;
# endif
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# endif
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/* timer signal */
sigfillset ( & act . sa_mask ) ;
act . sa_flags = SA_SIGINFO ;
# if defined (TARGET_I386) && defined(USE_CODE_COPY)
act . sa_flags | = SA_ONSTACK ;
# endif
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act . sa_sigaction = host_alarm_handler ;
sigaction ( SIGALRM , & act , NULL ) ;
itv . it_interval . tv_sec = 0 ;
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itv . it_interval . tv_usec = 1000 ;
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itv . it_value . tv_sec = 0 ;
itv . it_value . tv_usec = 10 * 1000 ;
setitimer ( ITIMER_REAL , & itv , NULL ) ;
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/* we probe the tick duration of the kernel to inform the user if
the emulated kernel requested a too high timer frequency */
getitimer ( ITIMER_REAL , & itv ) ;
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timer_ms = itv . it_interval . tv_usec / 1000 ;
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pit_min_timer_count = ( ( uint64_t ) itv . it_interval . tv_usec * PIT_FREQ ) /
1000000 ;
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if ( use_gdbstub ) {
cpu_gdbstub ( NULL , main_loop , gdbstub_port ) ;
} else {
main_loop ( NULL ) ;
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}
return 0 ;
}