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android / platform / external / qemu / donut-release / . / distrib / sdl-1.2.12 / src / video / ps2gs / SDL_gsevents.c
blob: 13f96b5d2db12fef9bc8eee0f59ee8f5da36ea2c [file] [log] [blame]
/*
SDL - Simple DirectMedia Layer
Copyright (C) 1997-2006 Sam Lantinga
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
Sam Lantinga
slouken@libsdl.org
*/
#include "SDL_config.h"
/* Handle the event stream, converting console events into SDL events */
#include <sys/types.h>
#include <sys/time.h>
#include <sys/ioctl.h>
#include <unistd.h>
#include <fcntl.h>
#include <errno.h>
#include <limits.h>
/* For parsing /proc */
#include <dirent.h>
#include <ctype.h>
#include <linux/vt.h>
#include <linux/kd.h>
#include <linux/keyboard.h>
#include "SDL_mutex.h"
#include "../SDL_sysvideo.h"
#include "../../events/SDL_sysevents.h"
#include "../../events/SDL_events_c.h"
#include "SDL_gsvideo.h"
#include "SDL_gsevents_c.h"
#include "SDL_gskeys.h"
#ifndef GPM_NODE_FIFO
#define GPM_NODE_FIFO "/dev/gpmdata"
#endif
/* The translation tables from a console scancode to a SDL keysym */
#define NUM_VGAKEYMAPS (1<<KG_CAPSSHIFT)
static Uint16 vga_keymap[NUM_VGAKEYMAPS][NR_KEYS];
static SDLKey keymap[128];
static Uint16 keymap_temp[128]; /* only used at startup */
static SDL_keysym *TranslateKey(int scancode, SDL_keysym *keysym);
/* Ugh, we have to duplicate the kernel's keysym mapping code...
Oh, it's not so bad. :-)
FIXME: Add keyboard LED handling code
*/
static void GS_vgainitkeymaps(int fd)
{
struct kbentry entry;
int map, i;
/* Don't do anything if we are passed a closed keyboard */
if ( fd < 0 ) {
return;
}
/* Load all the keysym mappings */
for ( map=0; map<NUM_VGAKEYMAPS; ++map ) {
SDL_memset(vga_keymap[map], 0, NR_KEYS*sizeof(Uint16));
for ( i=0; i<NR_KEYS; ++i ) {
entry.kb_table = map;
entry.kb_index = i;
if ( ioctl(fd, KDGKBENT, &entry) == 0 ) {
/* fill keytemp. This replaces SDL_fbkeys.h */
if ( (map == 0) && (i<128) ) {
keymap_temp[i] = entry.kb_value;
}
/* The "Enter" key is a special case */
if ( entry.kb_value == K_ENTER ) {
entry.kb_value = K(KT_ASCII,13);
}
/* Handle numpad specially as well */
if ( KTYP(entry.kb_value) == KT_PAD ) {
switch ( entry.kb_value ) {
case K_P0:
case K_P1:
case K_P2:
case K_P3:
case K_P4:
case K_P5:
case K_P6:
case K_P7:
case K_P8:
case K_P9:
vga_keymap[map][i]=entry.kb_value;
vga_keymap[map][i]+= '0';
break;
case K_PPLUS:
vga_keymap[map][i]=K(KT_ASCII,'+');
break;
case K_PMINUS:
vga_keymap[map][i]=K(KT_ASCII,'-');
break;
case K_PSTAR:
vga_keymap[map][i]=K(KT_ASCII,'*');
break;
case K_PSLASH:
vga_keymap[map][i]=K(KT_ASCII,'/');
break;
case K_PENTER:
vga_keymap[map][i]=K(KT_ASCII,'\r');
break;
case K_PCOMMA:
vga_keymap[map][i]=K(KT_ASCII,',');
break;
case K_PDOT:
vga_keymap[map][i]=K(KT_ASCII,'.');
break;
default:
break;
}
}
/* Do the normal key translation */
if ( (KTYP(entry.kb_value) == KT_LATIN) ||
(KTYP(entry.kb_value) == KT_ASCII) ||
(KTYP(entry.kb_value) == KT_LETTER) ) {
vga_keymap[map][i] = entry.kb_value;
}
}
}
}
}
int GS_InGraphicsMode(_THIS)
{
return((keyboard_fd >= 0) && (saved_kbd_mode >= 0));
}
int GS_EnterGraphicsMode(_THIS)
{
struct termios keyboard_termios;
/* Set medium-raw keyboard mode */
if ( (keyboard_fd >= 0) && !GS_InGraphicsMode(this) ) {
/* Switch to the correct virtual terminal */
if ( current_vt > 0 ) {
struct vt_stat vtstate;
if ( ioctl(keyboard_fd, VT_GETSTATE, &vtstate) == 0 ) {
saved_vt = vtstate.v_active;
}
if ( ioctl(keyboard_fd, VT_ACTIVATE, current_vt) == 0 ) {
ioctl(keyboard_fd, VT_WAITACTIVE, current_vt);
}
}
/* Set the terminal input mode */
if ( tcgetattr(keyboard_fd, &saved_kbd_termios) < 0 ) {
SDL_SetError("Unable to get terminal attributes");
if ( keyboard_fd > 0 ) {
close(keyboard_fd);
}
keyboard_fd = -1;
return(-1);
}
if ( ioctl(keyboard_fd, KDGKBMODE, &saved_kbd_mode) < 0 ) {
SDL_SetError("Unable to get current keyboard mode");
if ( keyboard_fd > 0 ) {
close(keyboard_fd);
}
keyboard_fd = -1;
return(-1);
}
keyboard_termios = saved_kbd_termios;
keyboard_termios.c_lflag &= ~(ICANON | ECHO | ISIG);
keyboard_termios.c_iflag &= ~(ISTRIP | IGNCR | ICRNL | INLCR | IXOFF | IXON);
keyboard_termios.c_cc[VMIN] = 0;
keyboard_termios.c_cc[VTIME] = 0;
if (tcsetattr(keyboard_fd, TCSAFLUSH, &keyboard_termios) < 0) {
GS_CloseKeyboard(this);
SDL_SetError("Unable to set terminal attributes");
return(-1);
}
/* This will fail if we aren't root or this isn't our tty */
if ( ioctl(keyboard_fd, KDSKBMODE, K_MEDIUMRAW) < 0 ) {
GS_CloseKeyboard(this);
SDL_SetError("Unable to set keyboard in raw mode");
return(-1);
}
if ( ioctl(keyboard_fd, KDSETMODE, KD_GRAPHICS) < 0 ) {
GS_CloseKeyboard(this);
SDL_SetError("Unable to set keyboard in graphics mode");
return(-1);
}
}
return(keyboard_fd);
}
void GS_LeaveGraphicsMode(_THIS)
{
if ( GS_InGraphicsMode(this) ) {
ioctl(keyboard_fd, KDSETMODE, KD_TEXT);
ioctl(keyboard_fd, KDSKBMODE, saved_kbd_mode);
tcsetattr(keyboard_fd, TCSAFLUSH, &saved_kbd_termios);
saved_kbd_mode = -1;
/* Head back over to the original virtual terminal */
if ( saved_vt > 0 ) {
ioctl(keyboard_fd, VT_ACTIVATE, saved_vt);
}
}
}
void GS_CloseKeyboard(_THIS)
{
if ( keyboard_fd >= 0 ) {
GS_LeaveGraphicsMode(this);
if ( keyboard_fd > 0 ) {
close(keyboard_fd);
}
}
keyboard_fd = -1;
}
int GS_OpenKeyboard(_THIS)
{
/* Open only if not already opened */
if ( keyboard_fd < 0 ) {
char *tty0[] = { "/dev/tty0", "/dev/vc/0", NULL };
char *vcs[] = { "/dev/vc/%d", "/dev/tty%d", NULL };
int i, tty0_fd;
/* Try to query for a free virtual terminal */
tty0_fd = -1;
for ( i=0; tty0[i] && (tty0_fd < 0); ++i ) {
tty0_fd = open(tty0[i], O_WRONLY, 0);
}
if ( tty0_fd < 0 ) {
tty0_fd = dup(0); /* Maybe stdin is a VT? */
}
ioctl(tty0_fd, VT_OPENQRY, &current_vt);
close(tty0_fd);
if ( (geteuid() == 0) && (current_vt > 0) ) {
for ( i=0; vcs[i] && (keyboard_fd < 0); ++i ) {
char vtpath[12];
SDL_snprintf(vtpath, SDL_arraysize(vtpath), vcs[i], current_vt);
keyboard_fd = open(vtpath, O_RDWR, 0);
#ifdef DEBUG_KEYBOARD
fprintf(stderr, "vtpath = %s, fd = %d\n",
vtpath, keyboard_fd);
#endif /* DEBUG_KEYBOARD */
/* This needs to be our controlling tty
so that the kernel ioctl() calls work
*/
if ( keyboard_fd >= 0 ) {
tty0_fd = open("/dev/tty", O_RDWR, 0);
if ( tty0_fd >= 0 ) {
ioctl(tty0_fd, TIOCNOTTY, 0);
close(tty0_fd);
}
}
}
}
if ( keyboard_fd < 0 ) {
/* Last resort, maybe our tty is a usable VT */
current_vt = 0;
keyboard_fd = open("/dev/tty", O_RDWR);
}
#ifdef DEBUG_KEYBOARD
fprintf(stderr, "Current VT: %d\n", current_vt);
#endif
saved_kbd_mode = -1;
/* Make sure that our input is a console terminal */
{ int dummy;
if ( ioctl(keyboard_fd, KDGKBMODE, &dummy) < 0 ) {
close(keyboard_fd);
keyboard_fd = -1;
SDL_SetError("Unable to open a console terminal");
}
}
/* Set up keymap */
GS_vgainitkeymaps(keyboard_fd);
}
return(keyboard_fd);
}
static enum {
MOUSE_NONE = -1,
MOUSE_GPM, /* Note: GPM uses the MSC protocol */
MOUSE_PS2,
MOUSE_IMPS2,
MOUSE_MS,
MOUSE_BM,
NUM_MOUSE_DRVS
} mouse_drv = MOUSE_NONE;
void GS_CloseMouse(_THIS)
{
if ( mouse_fd > 0 ) {
close(mouse_fd);
}
mouse_fd = -1;
}
/* Returns processes listed in /proc with the desired name */
static int find_pid(DIR *proc, const char *wanted_name)
{
struct dirent *entry;
int pid;
/* First scan proc for the gpm process */
pid = 0;
while ( (pid == 0) && ((entry=readdir(proc)) != NULL) ) {
if ( isdigit(entry->d_name[0]) ) {
FILE *status;
char path[PATH_MAX];
char name[PATH_MAX];
SDL_snprintf(path, SDL_arraysize(path), "/proc/%s/status", entry->d_name);
status=fopen(path, "r");
if ( status ) {
name[0] = '\0';
fscanf(status, "Name: %s", name);
if ( SDL_strcmp(name, wanted_name) == 0 ) {
pid = atoi(entry->d_name);
}
fclose(status);
}
}
}
return pid;
}
/* Returns true if /dev/gpmdata is being written to by gpm */
static int gpm_available(void)
{
int available;
DIR *proc;
int pid;
int cmdline, len, arglen;
char path[PATH_MAX];
char args[PATH_MAX], *arg;
/* Don't bother looking if the fifo isn't there */
if ( access(GPM_NODE_FIFO, F_OK) < 0 ) {
return(0);
}
available = 0;
proc = opendir("/proc");
if ( proc ) {
while ( (pid=find_pid(proc, "gpm")) > 0 ) {
SDL_snprintf(path, SDL_arraysize(path), "/proc/%d/cmdline", pid);
cmdline = open(path, O_RDONLY, 0);
if ( cmdline >= 0 ) {
len = read(cmdline, args, sizeof(args));
arg = args;
while ( len > 0 ) {
if ( SDL_strcmp(arg, "-R") == 0 ) {
available = 1;
}
arglen = SDL_strlen(arg)+1;
len -= arglen;
arg += arglen;
}
close(cmdline);
}
}
closedir(proc);
}
return available;
}
/* rcg06112001 Set up IMPS/2 mode, if possible. This gives
* us access to the mousewheel, etc. Returns zero if
* writes to device failed, but you still need to query the
* device to see which mode it's actually in.
*/
static int set_imps2_mode(int fd)
{
/* If you wanted to control the mouse mode (and we do :) ) ...
Set IMPS/2 protocol:
{0xf3,200,0xf3,100,0xf3,80}
Reset mouse device:
{0xFF}
*/
Uint8 set_imps2[] = {0xf3, 200, 0xf3, 100, 0xf3, 80};
Uint8 reset = 0xff;
fd_set fdset;
struct timeval tv;
int retval = 0;
if ( write(fd, &set_imps2, sizeof(set_imps2)) == sizeof(set_imps2) ) {
if (write(fd, &reset, sizeof (reset)) == sizeof (reset) ) {
retval = 1;
}
}
/* Get rid of any chatter from the above */
FD_ZERO(&fdset);
FD_SET(fd, &fdset);
tv.tv_sec = 0;
tv.tv_usec = 0;
while ( select(fd+1, &fdset, 0, 0, &tv) > 0 ) {
char temp[32];
read(fd, temp, sizeof(temp));
}
return retval;
}
/* Returns true if the mouse uses the IMPS/2 protocol */
static int detect_imps2(int fd)
{
int imps2;
imps2 = 0;
if ( SDL_getenv("SDL_MOUSEDEV_IMPS2") ) {
imps2 = 1;
}
if ( ! imps2 ) {
Uint8 query_ps2 = 0xF2;
fd_set fdset;
struct timeval tv;
/* Get rid of any mouse motion noise */
FD_ZERO(&fdset);
FD_SET(fd, &fdset);
tv.tv_sec = 0;
tv.tv_usec = 0;
while ( select(fd+1, &fdset, 0, 0, &tv) > 0 ) {
char temp[32];
read(fd, temp, sizeof(temp));
}
/* Query for the type of mouse protocol */
if ( write(fd, &query_ps2, sizeof (query_ps2)) == sizeof (query_ps2)) {
Uint8 ch = 0;
/* Get the mouse protocol response */
do {
FD_ZERO(&fdset);
FD_SET(fd, &fdset);
tv.tv_sec = 1;
tv.tv_usec = 0;
if ( select(fd+1, &fdset, 0, 0, &tv) < 1 ) {
break;
}
} while ( (read(fd, &ch, sizeof (ch)) == sizeof (ch)) &&
((ch == 0xFA) || (ch == 0xAA)) );
/* Experimental values (Logitech wheelmouse) */
#ifdef DEBUG_MOUSE
fprintf(stderr, "Last mouse mode: 0x%x\n", ch);
#endif
if ( ch == 3 ) {
imps2 = 1;
}
}
}
return imps2;
}
int GS_OpenMouse(_THIS)
{
int i;
const char *mousedev;
const char *mousedrv;
mousedrv = SDL_getenv("SDL_MOUSEDRV");
mousedev = SDL_getenv("SDL_MOUSEDEV");
mouse_fd = -1;
/* STD MICE */
if ( mousedev == NULL ) {
/* FIXME someday... allow multiple mice in this driver */
char *ps2mice[] = {
"/dev/input/mice", "/dev/usbmouse", "/dev/psaux", NULL
};
/* First try to use GPM in repeater mode */
if ( mouse_fd < 0 ) {
if ( gpm_available() ) {
mouse_fd = open(GPM_NODE_FIFO, O_RDONLY, 0);
if ( mouse_fd >= 0 ) {
#ifdef DEBUG_MOUSE
fprintf(stderr, "Using GPM mouse\n");
#endif
mouse_drv = MOUSE_GPM;
}
}
}
/* Now try to use a modern PS/2 mouse */
for ( i=0; (mouse_fd < 0) && ps2mice[i]; ++i ) {
mouse_fd = open(ps2mice[i], O_RDWR, 0);
if (mouse_fd < 0) {
mouse_fd = open(ps2mice[i], O_RDONLY, 0);
}
if (mouse_fd >= 0) {
/* rcg06112001 Attempt to set IMPS/2 mode */
if ( i == 0 ) {
set_imps2_mode(mouse_fd);
}
if (detect_imps2(mouse_fd)) {
#ifdef DEBUG_MOUSE
fprintf(stderr, "Using IMPS2 mouse\n");
#endif
mouse_drv = MOUSE_IMPS2;
} else {
mouse_drv = MOUSE_PS2;
#ifdef DEBUG_MOUSE
fprintf(stderr, "Using PS2 mouse\n");
#endif
}
}
}
/* Next try to use a PPC ADB port mouse */
if ( mouse_fd < 0 ) {
mouse_fd = open("/dev/adbmouse", O_RDONLY, 0);
if ( mouse_fd >= 0 ) {
#ifdef DEBUG_MOUSE
fprintf(stderr, "Using ADB mouse\n");
#endif
mouse_drv = MOUSE_BM;
}
}
}
/* Default to a serial Microsoft mouse */
if ( mouse_fd < 0 ) {
if ( mousedev == NULL ) {
mousedev = "/dev/mouse";
}
mouse_fd = open(mousedev, O_RDONLY, 0);
if ( mouse_fd >= 0 ) {
struct termios mouse_termios;
/* Set the sampling speed to 1200 baud */
tcgetattr(mouse_fd, &mouse_termios);
mouse_termios.c_iflag = IGNBRK | IGNPAR;
mouse_termios.c_oflag = 0;
mouse_termios.c_lflag = 0;
mouse_termios.c_line = 0;
mouse_termios.c_cc[VTIME] = 0;
mouse_termios.c_cc[VMIN] = 1;
mouse_termios.c_cflag = CREAD | CLOCAL | HUPCL;
mouse_termios.c_cflag |= CS8;
mouse_termios.c_cflag |= B1200;
tcsetattr(mouse_fd, TCSAFLUSH, &mouse_termios);
#ifdef DEBUG_MOUSE
fprintf(stderr, "Using Microsoft mouse on %s\n", mousedev);
#endif
mouse_drv = MOUSE_MS;
}
}
if ( mouse_fd < 0 ) {
mouse_drv = MOUSE_NONE;
}
return(mouse_fd);
}
static int posted = 0;
void GS_vgamousecallback(int button, int dx, int dy)
{
int button_1, button_3;
int button_state;
int state_changed;
int i;
Uint8 state;
if ( dx || dy ) {
posted += SDL_PrivateMouseMotion(0, 1, dx, dy);
}
/* Swap button 1 and 3 */
button_1 = (button & 0x04) >> 2;
button_3 = (button & 0x01) << 2;
button &= ~0x05;
button |= (button_1|button_3);
/* See what changed */
button_state = SDL_GetMouseState(NULL, NULL);
state_changed = button_state ^ button;
for ( i=0; i<8; ++i ) {
if ( state_changed & (1<<i) ) {
if ( button & (1<<i) ) {
state = SDL_PRESSED;
} else {
state = SDL_RELEASED;
}
posted += SDL_PrivateMouseButton(state, i+1, 0, 0);
}
}
}
/* For now, use GPM, PS/2, and MS protocols
Driver adapted from the SVGAlib mouse driver code (taken from gpm, etc.)
*/
static void handle_mouse(_THIS)
{
static int start = 0;
static unsigned char mousebuf[BUFSIZ];
int i, nread;
int button = 0;
int dx = 0, dy = 0;
int packetsize = 0;
/* Figure out the mouse packet size */
switch (mouse_drv) {
case MOUSE_NONE:
/* Ack! */
read(mouse_fd, mousebuf, BUFSIZ);
return;
case MOUSE_GPM:
packetsize = 5;
break;
case MOUSE_IMPS2:
packetsize = 4;
break;
case MOUSE_PS2:
case MOUSE_MS:
case MOUSE_BM:
packetsize = 3;
break;
case NUM_MOUSE_DRVS:
/* Uh oh.. */
packetsize = 0;
break;
}
/* Read as many packets as possible */
nread = read(mouse_fd, &mousebuf[start], BUFSIZ-start);
if ( nread < 0 ) {
return;
}
nread += start;
#ifdef DEBUG_MOUSE
fprintf(stderr, "Read %d bytes from mouse, start = %d\n", nread, start);
#endif
for ( i=0; i<(nread-(packetsize-1)); i += packetsize ) {
switch (mouse_drv) {
case MOUSE_NONE:
break;
case MOUSE_GPM:
/* GPM protocol has 0x80 in high byte */
if ( (mousebuf[i] & 0xF8) != 0x80 ) {
/* Go to next byte */
i -= (packetsize-1);
continue;
}
/* Get current mouse state */
button = (~mousebuf[i]) & 0x07;
dx = (signed char)(mousebuf[i+1]) +
(signed char)(mousebuf[i+3]);
dy = -((signed char)(mousebuf[i+2]) +
(signed char)(mousebuf[i+4]));
break;
case MOUSE_PS2:
/* PS/2 protocol has nothing in high byte */
if ( (mousebuf[i] & 0xC0) != 0 ) {
/* Go to next byte */
i -= (packetsize-1);
continue;
}
/* Get current mouse state */
button = (mousebuf[i] & 0x04) >> 1 | /*Middle*/
(mousebuf[i] & 0x02) >> 1 | /*Right*/
(mousebuf[i] & 0x01) << 2; /*Left*/
dx = (mousebuf[i] & 0x10) ?
mousebuf[i+1] - 256 : mousebuf[i+1];
dy = (mousebuf[i] & 0x20) ?
-(mousebuf[i+2] - 256) : -mousebuf[i+2];
break;
case MOUSE_IMPS2:
/* Get current mouse state */
button = (mousebuf[i] & 0x04) >> 1 | /*Middle*/
(mousebuf[i] & 0x02) >> 1 | /*Right*/
(mousebuf[i] & 0x01) << 2 | /*Left*/
(mousebuf[i] & 0x40) >> 3 | /* 4 */
(mousebuf[i] & 0x80) >> 3; /* 5 */
dx = (mousebuf[i] & 0x10) ?
mousebuf[i+1] - 256 : mousebuf[i+1];
dy = (mousebuf[i] & 0x20) ?
-(mousebuf[i+2] - 256) : -mousebuf[i+2];
switch (mousebuf[i+3]&0x0F) {
case 0x0E: /* DX = +1 */
case 0x02: /* DX = -1 */
break;
case 0x0F: /* DY = +1 (map button 4) */
FB_vgamousecallback(button | (1<<3),
1, 0, 0);
break;
case 0x01: /* DY = -1 (map button 5) */
FB_vgamousecallback(button | (1<<4),
1, 0, 0);
break;
}
break;
case MOUSE_MS:
/* Microsoft protocol has 0x40 in high byte */
if ( (mousebuf[i] & 0x40) != 0x40 ) {
/* Go to next byte */
i -= (packetsize-1);
continue;
}
/* Get current mouse state */
button = ((mousebuf[i] & 0x20) >> 3) |
((mousebuf[i] & 0x10) >> 4);
dx = (signed char)(((mousebuf[i] & 0x03) << 6) |
(mousebuf[i + 1] & 0x3F));
dy = (signed char)(((mousebuf[i] & 0x0C) << 4) |
(mousebuf[i + 2] & 0x3F));
break;
case MOUSE_BM:
/* BusMouse protocol has 0xF8 in high byte */
if ( (mousebuf[i] & 0xF8) != 0x80 ) {
/* Go to next byte */
i -= (packetsize-1);
continue;
}
/* Get current mouse state */
button = (~mousebuf[i]) & 0x07;
dx = (signed char)mousebuf[i+1];
dy = -(signed char)mousebuf[i+2];
break;
case NUM_MOUSE_DRVS:
/* Uh oh.. */
dx = 0;
dy = 0;
break;
}
GS_vgamousecallback(button, dx, dy);
}
if ( i < nread ) {
SDL_memcpy(mousebuf, &mousebuf[i], (nread-i));
start = (nread-i);
} else {
start = 0;
}
return;
}
static void handle_keyboard(_THIS)
{
unsigned char keybuf[BUFSIZ];
int i, nread;
int pressed;
int scancode;
SDL_keysym keysym;
nread = read(keyboard_fd, keybuf, BUFSIZ);
for ( i=0; i<nread; ++i ) {
scancode = keybuf[i] & 0x7F;
if ( keybuf[i] & 0x80 ) {
pressed = SDL_RELEASED;
} else {
pressed = SDL_PRESSED;
}
TranslateKey(scancode, &keysym);
posted += SDL_PrivateKeyboard(pressed, &keysym);
}
}
void GS_PumpEvents(_THIS)
{
fd_set fdset;
int max_fd;
static struct timeval zero;
do {
posted = 0;
FD_ZERO(&fdset);
max_fd = 0;
if ( keyboard_fd >= 0 ) {
FD_SET(keyboard_fd, &fdset);
if ( max_fd < keyboard_fd ) {
max_fd = keyboard_fd;
}
}
if ( mouse_fd >= 0 ) {
FD_SET(mouse_fd, &fdset);
if ( max_fd < mouse_fd ) {
max_fd = mouse_fd;
}
}
if ( select(max_fd+1, &fdset, NULL, NULL, &zero) > 0 ) {
if ( keyboard_fd >= 0 ) {
if ( FD_ISSET(keyboard_fd, &fdset) ) {
handle_keyboard(this);
}
}
if ( mouse_fd >= 0 ) {
if ( FD_ISSET(mouse_fd, &fdset) ) {
handle_mouse(this);
}
}
}
} while ( posted );
}
void GS_InitOSKeymap(_THIS)
{
int i;
/* Initialize the Linux key translation table */
/* First get the ascii keys and others not well handled */
for (i=0; i<SDL_arraysize(keymap); ++i) {
switch(i) {
/* These aren't handled by the x86 kernel keymapping (?) */
case SCANCODE_PRINTSCREEN:
keymap[i] = SDLK_PRINT;
break;
case SCANCODE_BREAK:
keymap[i] = SDLK_BREAK;
break;
case SCANCODE_BREAK_ALTERNATIVE:
keymap[i] = SDLK_PAUSE;
break;
case SCANCODE_LEFTSHIFT:
keymap[i] = SDLK_LSHIFT;
break;
case SCANCODE_RIGHTSHIFT:
keymap[i] = SDLK_RSHIFT;
break;
case SCANCODE_LEFTCONTROL:
keymap[i] = SDLK_LCTRL;
break;
case SCANCODE_RIGHTCONTROL:
keymap[i] = SDLK_RCTRL;
break;
case SCANCODE_RIGHTWIN:
keymap[i] = SDLK_RSUPER;
break;
case SCANCODE_LEFTWIN:
keymap[i] = SDLK_LSUPER;
break;
case 127:
keymap[i] = SDLK_MENU;
break;
/* this should take care of all standard ascii keys */
default:
keymap[i] = KVAL(vga_keymap[0][i]);
break;
}
}
for (i=0; i<SDL_arraysize(keymap); ++i) {
switch(keymap_temp[i]) {
case K_F1: keymap[i] = SDLK_F1; break;
case K_F2: keymap[i] = SDLK_F2; break;
case K_F3: keymap[i] = SDLK_F3; break;
case K_F4: keymap[i] = SDLK_F4; break;
case K_F5: keymap[i] = SDLK_F5; break;
case K_F6: keymap[i] = SDLK_F6; break;
case K_F7: keymap[i] = SDLK_F7; break;
case K_F8: keymap[i] = SDLK_F8; break;
case K_F9: keymap[i] = SDLK_F9; break;
case K_F10: keymap[i] = SDLK_F10; break;
case K_F11: keymap[i] = SDLK_F11; break;
case K_F12: keymap[i] = SDLK_F12; break;
case K_DOWN: keymap[i] = SDLK_DOWN; break;
case K_LEFT: keymap[i] = SDLK_LEFT; break;
case K_RIGHT: keymap[i] = SDLK_RIGHT; break;
case K_UP: keymap[i] = SDLK_UP; break;
case K_P0: keymap[i] = SDLK_KP0; break;
case K_P1: keymap[i] = SDLK_KP1; break;
case K_P2: keymap[i] = SDLK_KP2; break;
case K_P3: keymap[i] = SDLK_KP3; break;
case K_P4: keymap[i] = SDLK_KP4; break;
case K_P5: keymap[i] = SDLK_KP5; break;
case K_P6: keymap[i] = SDLK_KP6; break;
case K_P7: keymap[i] = SDLK_KP7; break;
case K_P8: keymap[i] = SDLK_KP8; break;
case K_P9: keymap[i] = SDLK_KP9; break;
case K_PPLUS: keymap[i] = SDLK_KP_PLUS; break;
case K_PMINUS: keymap[i] = SDLK_KP_MINUS; break;
case K_PSTAR: keymap[i] = SDLK_KP_MULTIPLY; break;
case K_PSLASH: keymap[i] = SDLK_KP_DIVIDE; break;
case K_PENTER: keymap[i] = SDLK_KP_ENTER; break;
case K_PDOT: keymap[i] = SDLK_KP_PERIOD; break;
case K_SHIFT: if ( keymap[i] != SDLK_RSHIFT )
keymap[i] = SDLK_LSHIFT;
break;
case K_SHIFTL: keymap[i] = SDLK_LSHIFT; break;
case K_SHIFTR: keymap[i] = SDLK_RSHIFT; break;
case K_CTRL: if ( keymap[i] != SDLK_RCTRL )
keymap[i] = SDLK_LCTRL;
break;
case K_CTRLL: keymap[i] = SDLK_LCTRL; break;
case K_CTRLR: keymap[i] = SDLK_RCTRL; break;
case K_ALT: keymap[i] = SDLK_LALT; break;
case K_ALTGR: keymap[i] = SDLK_RALT; break;
case K_INSERT: keymap[i] = SDLK_INSERT; break;
case K_REMOVE: keymap[i] = SDLK_DELETE; break;
case K_PGUP: keymap[i] = SDLK_PAGEUP; break;
case K_PGDN: keymap[i] = SDLK_PAGEDOWN; break;
case K_FIND: keymap[i] = SDLK_HOME; break;
case K_SELECT: keymap[i] = SDLK_END; break;
case K_NUM: keymap[i] = SDLK_NUMLOCK; break;
case K_CAPS: keymap[i] = SDLK_CAPSLOCK; break;
case K_F13: keymap[i] = SDLK_PRINT; break;
case K_HOLD: keymap[i] = SDLK_SCROLLOCK; break;
case K_PAUSE: keymap[i] = SDLK_PAUSE; break;
case 127: keymap[i] = SDLK_BACKSPACE; break;
default: break;
}
}
}
static SDL_keysym *TranslateKey(int scancode, SDL_keysym *keysym)
{
/* Set the keysym information */
keysym->scancode = scancode;
keysym->sym = keymap[scancode];
keysym->mod = KMOD_NONE;
/* If UNICODE is on, get the UNICODE value for the key */
keysym->unicode = 0;
if ( SDL_TranslateUNICODE ) {
int map;
SDLMod modstate;
modstate = SDL_GetModState();
map = 0;
if ( modstate & KMOD_SHIFT ) {
map |= (1<<KG_SHIFT);
}
if ( modstate & KMOD_CTRL ) {
map |= (1<<KG_CTRL);
}
if ( modstate & KMOD_ALT ) {
map |= (1<<KG_ALT);
}
if ( modstate & KMOD_MODE ) {
map |= (1<<KG_ALTGR);
}
if ( KTYP(vga_keymap[map][scancode]) == KT_LETTER ) {
if ( modstate & KMOD_CAPS ) {
map ^= (1<<KG_SHIFT);
}
}
if ( KTYP(vga_keymap[map][scancode]) == KT_PAD ) {
if ( modstate & KMOD_NUM ) {
keysym->unicode=KVAL(vga_keymap[map][scancode]);
}
} else {
keysym->unicode = KVAL(vga_keymap[map][scancode]);
}
}
return(keysym);
}