raze-gles/polymer/eduke32/source/jmact/control.c
terminx 3c51265878 Formatting changes to jmact
git-svn-id: https://svn.eduke32.com/eduke32@809 1a8010ca-5511-0410-912e-c29ae57300e0
2008-06-29 10:41:01 +00:00

977 lines
26 KiB
C

/*
* control.c
* MACT library controller handling
*
* Derived from MACT386.LIB disassembly by Jonathon Fowler
*
*/
#include "compat.h"
#include "types.h"
#include "keyboard.h"
#include "mouse.h"
#include "control.h"
#include "_control.h"
#include "util_lib.h"
#include "baselayer.h"
#include "pragmas.h"
boolean CONTROL_JoyPresent = false;
boolean CONTROL_JoystickEnabled = false;
boolean CONTROL_MousePresent = false;
boolean CONTROL_MouseEnabled = false;
uint32 CONTROL_ButtonState1 = 0;
uint32 CONTROL_ButtonHeldState1 = 0;
uint32 CONTROL_ButtonState2 = 0;
uint32 CONTROL_ButtonHeldState2 = 0;
// static int32 CONTROL_UserInputDelay = -1;
static int32 CONTROL_MouseSensitivity = DEFAULTMOUSESENSITIVITY;
static int32 CONTROL_NumMouseButtons = 0;
static int32 CONTROL_NumMouseAxes = 0;
static int32 CONTROL_NumJoyButtons = 0;
static int32 CONTROL_NumJoyAxes = 0;
static controlflags CONTROL_Flags[CONTROL_NUM_FLAGS];
static controlbuttontype CONTROL_MouseButtonMapping[MAXMOUSEBUTTONS],
CONTROL_JoyButtonMapping[MAXJOYBUTTONS];
static controlkeymaptype CONTROL_KeyMapping[CONTROL_NUM_FLAGS];
static controlaxismaptype CONTROL_MouseAxesMap[MAXMOUSEAXES], // maps physical axes onto virtual ones
CONTROL_JoyAxesMap[MAXJOYAXES];
static controlaxistype CONTROL_MouseAxes[MAXMOUSEAXES], // physical axes
CONTROL_JoyAxes[MAXJOYAXES];
static controlaxistype CONTROL_LastMouseAxes[MAXMOUSEAXES],
CONTROL_LastJoyAxes[MAXJOYAXES];
static int32 CONTROL_MouseAxesScale[MAXMOUSEAXES], CONTROL_JoyAxesScale[MAXJOYAXES];
static int32 CONTROL_MouseButtonState[MAXMOUSEBUTTONS], CONTROL_JoyButtonState[MAXJOYBUTTONS];
static int32 CONTROL_MouseButtonClickedTime[MAXMOUSEBUTTONS], CONTROL_JoyButtonClickedTime[MAXJOYBUTTONS];
static boolean CONTROL_MouseButtonClickedState[MAXMOUSEBUTTONS], CONTROL_JoyButtonClickedState[MAXJOYBUTTONS];
static boolean CONTROL_MouseButtonClicked[MAXMOUSEBUTTONS], CONTROL_JoyButtonClicked[MAXJOYBUTTONS];
static byte CONTROL_MouseButtonClickedCount[MAXMOUSEBUTTONS], CONTROL_JoyButtonClickedCount[MAXJOYBUTTONS];
static boolean CONTROL_UserInputCleared[3];
static int32(*GetTime)(void);
static boolean CONTROL_Started = false;
static int32 ticrate;
static int32 CONTROL_DoubleClickSpeed;
void CONTROL_GetMouseDelta(void)
{
int32 x,y;
MOUSE_GetDelta(&x, &y);
/* What in the name of all things sacred is this?
if (labs(*x) > labs(*y)) {
*x /= 3;
} else {
*y /= 3;
}
*y = *y * 96;
*x = (*x * 32 * CONTROL_MouseSensitivity) >> 15;
*/
CONTROL_MouseAxes[0].analog = (x * (CONTROL_MouseSensitivity<<1));
CONTROL_MouseAxes[1].analog = (y * (CONTROL_MouseSensitivity<<1))<<1;
}
int32 CONTROL_GetMouseSensitivity(void)
{
return (CONTROL_MouseSensitivity);
}
void CONTROL_SetMouseSensitivity(int32 newsensitivity)
{
CONTROL_MouseSensitivity = newsensitivity;
}
boolean CONTROL_StartMouse(void)
{
CONTROL_NumMouseButtons = MAXMOUSEBUTTONS;
return MOUSE_Init();
}
void CONTROL_GetJoyAbs(void)
{
}
void CONTROL_FilterJoyDelta(void)
{
}
void CONTROL_GetJoyDelta(void)
{
int32 i;
for (i=0; i<joynumaxes; i++)
CONTROL_JoyAxes[i].analog = joyaxis[i] >> 5;
}
boolean CONTROL_StartJoy(int32 joy)
{
UNREFERENCED_PARAMETER(joy);
return (inputdevices & 4) == 4;
}
void CONTROL_ShutJoy(int32 joy)
{
UNREFERENCED_PARAMETER(joy);
CONTROL_JoyPresent = false;
}
int32 CONTROL_GetTime(void)
{
static int32 t = 0;
t += 5;
return t;
}
boolean CONTROL_CheckRange(int32 which)
{
if ((uint32)which < (uint32)CONTROL_NUM_FLAGS) return false;
//Error("CONTROL_CheckRange: Index %d out of valid range for %d control flags.",
// which, CONTROL_NUM_FLAGS);
return true;
}
void CONTROL_SetFlag(int32 which, boolean active)
{
if (CONTROL_CheckRange(which)) return;
if (CONTROL_Flags[which].toggle == INSTANT_ONOFF)
{
CONTROL_Flags[which].active = active;
}
else
{
if (active)
{
CONTROL_Flags[which].buttonheld = false;
}
else if (CONTROL_Flags[which].buttonheld == false)
{
CONTROL_Flags[which].buttonheld = true;
CONTROL_Flags[which].active = (CONTROL_Flags[which].active ? false : true);
}
}
}
boolean CONTROL_KeyboardFunctionPressed(int32 which)
{
boolean key1 = 0, key2 = 0;
if (CONTROL_CheckRange(which)) return false;
if (!CONTROL_Flags[which].used) return false;
if (CONTROL_KeyMapping[which].key1 != KEYUNDEFINED && !boundkeys[CONTROL_KeyMapping[which].key1].name[0])
key1 = KB_KeyDown[ CONTROL_KeyMapping[which].key1 ] ? true : false;
if (CONTROL_KeyMapping[which].key2 != KEYUNDEFINED && !boundkeys[CONTROL_KeyMapping[which].key1].name[0])
key2 = KB_KeyDown[ CONTROL_KeyMapping[which].key2 ] ? true : false;
return (key1 | key2);
}
void CONTROL_ClearKeyboardFunction(int32 which)
{
if (CONTROL_CheckRange(which)) return;
if (!CONTROL_Flags[which].used) return;
if (CONTROL_KeyMapping[which].key1 != KEYUNDEFINED)
KB_KeyDown[ CONTROL_KeyMapping[which].key1 ] = 0;
if (CONTROL_KeyMapping[which].key2 != KEYUNDEFINED)
KB_KeyDown[ CONTROL_KeyMapping[which].key2 ] = 0;
}
void CONTROL_DefineFlag(int32 which, boolean toggle)
{
if (CONTROL_CheckRange(which)) return;
CONTROL_Flags[which].active = false;
CONTROL_Flags[which].used = true;
CONTROL_Flags[which].toggle = toggle;
CONTROL_Flags[which].buttonheld = false;
CONTROL_Flags[which].cleared = 0;
}
boolean CONTROL_FlagActive(int32 which)
{
if (CONTROL_CheckRange(which)) return false;
return CONTROL_Flags[which].used;
}
void CONTROL_MapKey(int32 which, kb_scancode key1, kb_scancode key2)
{
if (CONTROL_CheckRange(which)) return;
CONTROL_KeyMapping[which].key1 = key1 ? key1 : KEYUNDEFINED;
CONTROL_KeyMapping[which].key2 = key2 ? key2 : KEYUNDEFINED;
}
void CONTROL_PrintKeyMap(void)
{
int32 i;
for (i=0;i<CONTROL_NUM_FLAGS;i++)
{
initprintf("function %2ld key1=%3x key2=%3x\n",
i, CONTROL_KeyMapping[i].key1, CONTROL_KeyMapping[i].key2);
}
}
void CONTROL_PrintControlFlag(int32 which)
{
initprintf("function %2ld active=%d used=%d toggle=%d buttonheld=%d cleared=%d\n",
which, CONTROL_Flags[which].active, CONTROL_Flags[which].used,
CONTROL_Flags[which].toggle, CONTROL_Flags[which].buttonheld,
CONTROL_Flags[which].cleared);
}
void CONTROL_PrintAxes(void)
{
int32 i;
initprintf("nummouseaxes=%d\n", CONTROL_NumMouseAxes);
for (i=0;i<CONTROL_NumMouseAxes;i++)
{
initprintf("axis=%d analog=%d digital1=%d digital2=%d\n",
i, CONTROL_MouseAxesMap[i].analogmap,
CONTROL_MouseAxesMap[i].minmap, CONTROL_MouseAxesMap[i].maxmap);
}
initprintf("numjoyaxes=%d\n", CONTROL_NumJoyAxes);
for (i=0;i<CONTROL_NumJoyAxes;i++)
{
initprintf("axis=%d analog=%d digital1=%d digital2=%d\n",
i, CONTROL_JoyAxesMap[i].analogmap,
CONTROL_JoyAxesMap[i].minmap, CONTROL_JoyAxesMap[i].maxmap);
}
}
void CONTROL_MapButton(int32 whichfunction, int32 whichbutton, boolean doubleclicked, controldevice device)
{
controlbuttontype *set;
if (CONTROL_CheckRange(whichfunction)) whichfunction = BUTTONUNDEFINED;
switch (device)
{
case controldevice_mouse:
if ((uint32)whichbutton >= (uint32)MAXMOUSEBUTTONS)
{
//Error("CONTROL_MapButton: button %d out of valid range for %d mouse buttons.",
// whichbutton, CONTROL_NumMouseButtons);
return;
}
set = CONTROL_MouseButtonMapping;
break;
case controldevice_joystick:
if ((uint32)whichbutton >= (uint32)MAXJOYBUTTONS)
{
//Error("CONTROL_MapButton: button %d out of valid range for %d joystick buttons.",
// whichbutton, CONTROL_NumJoyButtons);
return;
}
set = CONTROL_JoyButtonMapping;
break;
default:
//Error("CONTROL_MapButton: invalid controller device type");
return;
}
if (doubleclicked)
set[whichbutton].doubleclicked = whichfunction;
else
set[whichbutton].singleclicked = whichfunction;
}
void CONTROL_MapAnalogAxis(int32 whichaxis, int32 whichanalog, controldevice device)
{
controlaxismaptype *set;
if ((uint32)whichanalog >= (uint32)analog_maxtype)
{
//Error("CONTROL_MapAnalogAxis: analog function %d out of valid range for %d analog functions.",
// whichanalog, analog_maxtype);
return;
}
switch (device)
{
case controldevice_mouse:
if ((uint32)whichaxis >= (uint32)MAXMOUSEAXES)
{
//Error("CONTROL_MapAnalogAxis: axis %d out of valid range for %d mouse axes.",
// whichaxis, MAXMOUSEAXES);
return;
}
set = CONTROL_MouseAxesMap;
break;
case controldevice_joystick:
if ((uint32)whichaxis >= (uint32)MAXJOYAXES)
{
//Error("CONTROL_MapAnalogAxis: axis %d out of valid range for %d joystick axes.",
// whichaxis, MAXJOYAXES);
return;
}
set = CONTROL_JoyAxesMap;
break;
default:
//Error("CONTROL_MapAnalogAxis: invalid controller device type");
return;
}
set[whichaxis].analogmap = whichanalog;
}
void CONTROL_SetAnalogAxisScale(int32 whichaxis, int32 axisscale, controldevice device)
{
int32 *set;
switch (device)
{
case controldevice_mouse:
if ((uint32)whichaxis >= (uint32)MAXMOUSEAXES)
{
//Error("CONTROL_SetAnalogAxisScale: axis %d out of valid range for %d mouse axes.",
// whichaxis, MAXMOUSEAXES);
return;
}
set = CONTROL_MouseAxesScale;
break;
case controldevice_joystick:
if ((uint32)whichaxis >= (uint32)MAXJOYAXES)
{
//Error("CONTROL_SetAnalogAxisScale: axis %d out of valid range for %d joystick axes.",
// whichaxis, MAXJOYAXES);
return;
}
set = CONTROL_JoyAxesScale;
break;
default:
//Error("CONTROL_SetAnalogAxisScale: invalid controller device type");
return;
}
set[whichaxis] = axisscale;
}
void CONTROL_MapDigitalAxis(int32 whichaxis, int32 whichfunction, int32 direction, controldevice device)
{
controlaxismaptype *set;
if (CONTROL_CheckRange(whichfunction)) whichfunction = AXISUNDEFINED;
switch (device)
{
case controldevice_mouse:
if ((uint32)whichaxis >= (uint32)MAXMOUSEAXES)
{
//Error("CONTROL_MapDigitalAxis: axis %d out of valid range for %d mouse axes.",
// whichaxis, MAXMOUSEAXES);
return;
}
set = CONTROL_MouseAxesMap;
break;
case controldevice_joystick:
if ((uint32)whichaxis >= (uint32)MAXJOYAXES)
{
//Error("CONTROL_MapDigitalAxis: axis %d out of valid range for %d joystick axes.",
// whichaxis, MAXJOYAXES);
return;
}
set = CONTROL_JoyAxesMap;
break;
default:
//Error("CONTROL_MapDigitalAxis: invalid controller device type");
return;
}
switch (direction) // JBF: this is all very much a guess. The ASM puzzles me.
{
case axis_up:
case axis_left:
set[whichaxis].minmap = whichfunction;
break;
case axis_down:
case axis_right:
set[whichaxis].maxmap = whichfunction;
break;
default:
break;
}
}
void CONTROL_ClearFlags(void)
{
int32 i;
for (i=0;i<CONTROL_NUM_FLAGS;i++)
CONTROL_Flags[i].used = false;
}
void CONTROL_ClearAssignments(void)
{
int32 i;
memset(CONTROL_MouseButtonMapping, BUTTONUNDEFINED, sizeof(CONTROL_MouseButtonMapping));
memset(CONTROL_JoyButtonMapping, BUTTONUNDEFINED, sizeof(CONTROL_JoyButtonMapping));
memset(CONTROL_KeyMapping, KEYUNDEFINED, sizeof(CONTROL_KeyMapping));
memset(CONTROL_MouseAxesMap, AXISUNDEFINED, sizeof(CONTROL_MouseAxesMap));
memset(CONTROL_JoyAxesMap, AXISUNDEFINED, sizeof(CONTROL_JoyAxesMap));
memset(CONTROL_MouseAxes, 0, sizeof(CONTROL_MouseAxes));
memset(CONTROL_JoyAxes, 0, sizeof(CONTROL_JoyAxes));
memset(CONTROL_LastMouseAxes, 0, sizeof(CONTROL_LastMouseAxes));
memset(CONTROL_LastJoyAxes, 0, sizeof(CONTROL_LastJoyAxes));
for (i=0;i<MAXMOUSEAXES;i++)
CONTROL_MouseAxesScale[i] = NORMALAXISSCALE;
for (i=0;i<MAXJOYAXES;i++)
CONTROL_JoyAxesScale[i] = NORMALAXISSCALE;
}
static void DoGetDeviceButtons(
int32 buttons, int32 tm,
int32 NumButtons,
int32 *DeviceButtonState,
int32 *ButtonClickedTime,
boolean *ButtonClickedState,
boolean *ButtonClicked,
byte *ButtonClickedCount
)
{
int32 i, bs;
for (i=0;i<NumButtons;i++)
{
bs = (buttons >> i) & 1;
DeviceButtonState[i] = bs;
ButtonClickedState[i] = false;
if (bs)
{
if (ButtonClicked[i] == false)
{
ButtonClicked[i] = true;
if (ButtonClickedCount[i] == 0 || tm > ButtonClickedTime[i])
{
ButtonClickedTime[i] = tm + CONTROL_DoubleClickSpeed;
ButtonClickedCount[i] = 1;
}
else if (tm < ButtonClickedTime[i])
{
ButtonClickedState[i] = true;
ButtonClickedTime[i] = 0;
ButtonClickedCount[i] = 2;
}
}
else if (ButtonClickedCount[i] == 2)
{
ButtonClickedState[i] = true;
}
}
else
{
if (ButtonClickedCount[i] == 2)
ButtonClickedCount[i] = 0;
ButtonClicked[i] = false;
}
}
}
void CONTROL_GetDeviceButtons(void)
{
int32 t;
t = GetTime();
if (CONTROL_MouseEnabled)
{
DoGetDeviceButtons(
MOUSE_GetButtons(), t,
CONTROL_NumMouseButtons,
CONTROL_MouseButtonState,
CONTROL_MouseButtonClickedTime,
CONTROL_MouseButtonClickedState,
CONTROL_MouseButtonClicked,
CONTROL_MouseButtonClickedCount
);
}
if (CONTROL_JoystickEnabled)
{
int32 buttons = joyb;
if (joynumhats > 0 && joyhat[0] != -1)
{
static int32 hatstate[] = { 1, 1|2, 2, 2|4, 4, 4|8, 8, 8|1 };
int val;
// thanks SDL for this much more sensible method
val = ((joyhat[0] + 4500 / 2) % 36000) / 4500;
if (val < 8) buttons |= hatstate[val] << min(MAXJOYBUTTONS,joynumbuttons);
}
DoGetDeviceButtons(
buttons, t,
CONTROL_NumJoyButtons,
CONTROL_JoyButtonState,
CONTROL_JoyButtonClickedTime,
CONTROL_JoyButtonClickedState,
CONTROL_JoyButtonClicked,
CONTROL_JoyButtonClickedCount
);
}
}
void CONTROL_DigitizeAxis(int32 axis, controldevice device)
{
controlaxistype *set, *lastset;
switch (device)
{
case controldevice_mouse:
set = CONTROL_MouseAxes;
lastset = CONTROL_LastMouseAxes;
break;
case controldevice_joystick:
set = CONTROL_JoyAxes;
lastset = CONTROL_LastJoyAxes;
break;
default: return;
}
if (set[axis].analog > 0)
{
if (set[axis].analog > THRESHOLD) // if very much in one direction,
{
set[axis].digital = 1; // set affirmative
}
else
{
if (set[axis].analog > MINTHRESHOLD) // if hanging in limbo,
{
if (lastset[axis].digital == 1) // set if in same direction as last time
set[axis].digital = 1;
}
}
}
else
{
if (set[axis].analog < -THRESHOLD)
{
set[axis].digital = -1;
}
else
{
if (set[axis].analog < -MINTHRESHOLD)
{
if (lastset[axis].digital == -1)
set[axis].digital = -1;
}
}
}
}
void CONTROL_ScaleAxis(int32 axis, controldevice device)
{
controlaxistype *set;
int32 *scale;
switch (device)
{
case controldevice_mouse:
set = CONTROL_MouseAxes;
scale = CONTROL_MouseAxesScale;
break;
case controldevice_joystick:
set = CONTROL_JoyAxes;
scale = CONTROL_JoyAxesScale;
break;
default: return;
}
set[axis].analog = mulscale16(set[axis].analog, scale[axis]);
}
void CONTROL_ApplyAxis(int32 axis, ControlInfo *info, controldevice device)
{
controlaxistype *set;
controlaxismaptype *map;
switch (device)
{
case controldevice_mouse:
set = CONTROL_MouseAxes;
map = CONTROL_MouseAxesMap;
break;
case controldevice_joystick:
set = CONTROL_JoyAxes;
map = CONTROL_JoyAxesMap;
break;
default: return;
}
switch (map[axis].analogmap)
{
case analog_turning: info->dyaw += set[axis].analog; break;
case analog_strafing: info->dx += set[axis].analog; break;
case analog_lookingupanddown: info->dpitch += set[axis].analog; break;
case analog_elevation: info->dy += set[axis].analog; break;
case analog_rolling: info->droll += set[axis].analog; break;
case analog_moving: info->dz += set[axis].analog; break;
default: break;
}
}
void CONTROL_PollDevices(ControlInfo *info)
{
int32 i;
memcpy(CONTROL_LastMouseAxes, CONTROL_MouseAxes, sizeof(CONTROL_MouseAxes));
memcpy(CONTROL_LastJoyAxes, CONTROL_JoyAxes, sizeof(CONTROL_JoyAxes));
memset(CONTROL_MouseAxes, 0, sizeof(CONTROL_MouseAxes));
memset(CONTROL_JoyAxes, 0, sizeof(CONTROL_JoyAxes));
memset(info, 0, sizeof(ControlInfo));
if (CONTROL_MouseEnabled)
{
CONTROL_GetMouseDelta();
for (i=0; i<MAXMOUSEAXES; i++)
{
CONTROL_DigitizeAxis(i, controldevice_mouse);
CONTROL_ScaleAxis(i, controldevice_mouse);
LIMITCONTROL(&CONTROL_MouseAxes[i].analog);
CONTROL_ApplyAxis(i, info, controldevice_mouse);
}
}
if (CONTROL_JoystickEnabled)
{
CONTROL_GetJoyDelta();
// Why?
//CONTROL_Axes[0].analog /= 2;
//CONTROL_Axes[2].analog /= 2;
for (i=0; i<MAXJOYAXES; i++)
{
CONTROL_DigitizeAxis(i, controldevice_joystick);
CONTROL_ScaleAxis(i, controldevice_joystick);
LIMITCONTROL(&CONTROL_JoyAxes[i].analog);
CONTROL_ApplyAxis(i, info, controldevice_joystick);
}
}
CONTROL_GetDeviceButtons();
}
void CONTROL_AxisFunctionState(int32 *p1)
{
int32 i, j;
for (i=0; i<CONTROL_NumMouseAxes; i++)
{
if (!CONTROL_MouseAxes[i].digital) continue;
if (CONTROL_MouseAxes[i].digital < 0)
j = CONTROL_MouseAxesMap[i].minmap;
else
j = CONTROL_MouseAxesMap[i].maxmap;
if (j != AXISUNDEFINED)
p1[j] = 1;
}
for (i=0; i<CONTROL_NumJoyAxes; i++)
{
if (!CONTROL_JoyAxes[i].digital) continue;
if (CONTROL_JoyAxes[i].digital < 0)
j = CONTROL_JoyAxesMap[i].minmap;
else
j = CONTROL_JoyAxesMap[i].maxmap;
if (j != AXISUNDEFINED)
p1[j] = 1;
}
}
void CONTROL_ButtonFunctionState(int32 *p1)
{
int32 i, j;
for (i=0; i<CONTROL_NumMouseButtons; i++)
{
j = CONTROL_MouseButtonMapping[i].doubleclicked;
if (j != KEYUNDEFINED)
p1[j] |= CONTROL_MouseButtonClickedState[i];
j = CONTROL_MouseButtonMapping[i].singleclicked;
if (j != KEYUNDEFINED)
p1[j] |= CONTROL_MouseButtonState[i];
}
for (i=0; i<CONTROL_NumJoyButtons; i++)
{
j = CONTROL_JoyButtonMapping[i].doubleclicked;
if (j != KEYUNDEFINED)
p1[j] |= CONTROL_JoyButtonClickedState[i];
j = CONTROL_JoyButtonMapping[i].singleclicked;
if (j != KEYUNDEFINED)
p1[j] |= CONTROL_JoyButtonState[i];
}
}
/*
void CONTROL_GetUserInput( UserInput *info )
{
ControlInfo ci;
CONTROL_PollDevices( &ci );
info->dir = dir_None;
// checks if CONTROL_UserInputDelay is too far in the future due to clock skew?
if (GetTime() + ((ticrate * USERINPUTDELAY) / 1000) < CONTROL_UserInputDelay)
CONTROL_UserInputDelay = -1;
if (GetTime() >= CONTROL_UserInputDelay) {
if (CONTROL_MouseAxes[1].digital == -1)
info->dir = dir_North;
else if (CONTROL_MouseAxes[1].digital == 1)
info->dir = dir_South;
else if (CONTROL_MouseAxes[0].digital == -1)
info->dir = dir_West;
else if (CONTROL_MouseAxes[0].digital == 1)
info->dir = dir_East;
if (CONTROL_JoyAxes[1].digital == -1)
info->dir = dir_North;
else if (CONTROL_JoyAxes[1].digital == 1)
info->dir = dir_South;
else if (CONTROL_JoyAxes[0].digital == -1)
info->dir = dir_West;
else if (CONTROL_JoyAxes[0].digital == 1)
info->dir = dir_East;
}
info->button0 = CONTROL_MouseButtonState[0] | CONTROL_JoyButtonState[0];
info->button1 = CONTROL_MouseButtonState[1] | CONTROL_JoyButtonState[1];
if (KB_KeyDown[sc_kpad_8] || KB_KeyDown[sc_UpArrow])
info->dir = dir_North;
else if (KB_KeyDown[sc_kpad_2] || KB_KeyDown[sc_DownArrow])
info->dir = dir_South;
else if (KB_KeyDown[sc_kpad_4] || KB_KeyDown[sc_LeftArrow])
info->dir = dir_West;
else if (KB_KeyDown[sc_kpad_6] || KB_KeyDown[sc_RightArrow])
info->dir = dir_East;
if (KB_KeyDown[BUTTON0_SCAN_1] || KB_KeyDown[BUTTON0_SCAN_2] || KB_KeyDown[BUTTON0_SCAN_3])
info->button0 = 1;
if (KB_KeyDown[BUTTON1_SCAN])
info->button1 = 1;
if (CONTROL_UserInputCleared[1]) {
if (!info->button0)
CONTROL_UserInputCleared[1] = false;
else
info->button0 = false;
}
if (CONTROL_UserInputCleared[2]) {
if (!info->button1)
CONTROL_UserInputCleared[2] = false;
else
info->button1 = false;
}
}
void CONTROL_ClearUserInput( UserInput *info )
{
switch (info->dir) {
case dir_North:
case dir_South:
case dir_East:
case dir_West:
CONTROL_UserInputCleared[0] = true;
CONTROL_UserInputDelay = GetTime() + ((ticrate * USERINPUTDELAY) / 1000);
switch (info->dir) {
case dir_North: KB_KeyDown[sc_UpArrow] = KB_KeyDown[sc_kpad_8] = 0; break;
case dir_South: KB_KeyDown[sc_DownArrow] = KB_KeyDown[sc_kpad_2] = 0; break;
case dir_East: KB_KeyDown[sc_LeftArrow] = KB_KeyDown[sc_kpad_4] = 0; break;
case dir_West: KB_KeyDown[sc_RightArrow] = KB_KeyDown[sc_kpad_6] = 0; break;
default: break;
}
break;
default: break;
}
if (info->button0) CONTROL_UserInputCleared[1] = true;
if (info->button1) CONTROL_UserInputCleared[2] = true;
}
*/
void CONTROL_ClearButton(int32 whichbutton)
{
if (CONTROL_CheckRange(whichbutton)) return;
BUTTONCLEAR(whichbutton);
CONTROL_Flags[whichbutton].cleared = true;
}
int extinput[CONTROL_NUM_FLAGS];
keybind boundkeys[MAXBOUNDKEYS];
void CONTROL_ProcessBinds(void)
{
int i;
for (i=0;i<256;i++)
{
if (boundkeys[i].name[0] && KB_KeyPressed(i))
{
if (boundkeys[i].repeat || (boundkeys[i].laststate == 0))
OSD_Dispatch(boundkeys[i].name);
// if (!boundkeys[i].repeat)
// KB_ClearKeyDown(i);
}
boundkeys[i].laststate = KB_KeyPressed(i);
}
}
void CONTROL_GetInput(ControlInfo *info)
{
int32 i, periphs[CONTROL_NUM_FLAGS];
CONTROL_PollDevices(info);
memset(periphs, 0, sizeof(periphs));
CONTROL_ButtonFunctionState(periphs);
CONTROL_AxisFunctionState(periphs);
CONTROL_ButtonHeldState1 = CONTROL_ButtonState1;
CONTROL_ButtonHeldState2 = CONTROL_ButtonState2;
CONTROL_ButtonState1 = CONTROL_ButtonState2 = 0;
CONTROL_ProcessBinds();
for (i=0; i<CONTROL_NUM_FLAGS; i++)
{
CONTROL_SetFlag(i, CONTROL_KeyboardFunctionPressed(i) | periphs[i] | extinput[i]);
if (CONTROL_Flags[i].cleared == false) BUTTONSET(i, CONTROL_Flags[i].active);
else if (CONTROL_Flags[i].active == false) CONTROL_Flags[i].cleared = 0;
}
memset(extinput, 0, sizeof(extinput));
}
void CONTROL_WaitRelease(void)
{
}
void CONTROL_Ack(void)
{
}
boolean CONTROL_Startup(controltype which, int32(*TimeFunction)(void), int32 ticspersecond)
{
int32 i;
UNREFERENCED_PARAMETER(which);
if (CONTROL_Started) return false;
if (TimeFunction) GetTime = TimeFunction;
else GetTime = CONTROL_GetTime;
ticrate = ticspersecond;
CONTROL_DoubleClickSpeed = (ticspersecond*57)/100;
if (CONTROL_DoubleClickSpeed <= 0)
CONTROL_DoubleClickSpeed = 1;
if (initinput()) return true;
CONTROL_MousePresent = CONTROL_MouseEnabled = false;
CONTROL_JoyPresent = CONTROL_JoystickEnabled = false;
CONTROL_NumMouseButtons = CONTROL_NumJoyButtons = 0;
CONTROL_NumMouseAxes = CONTROL_NumJoyAxes = 0;
KB_Startup();
//switch (which) {
// case controltype_keyboard:
// break;
// case controltype_keyboardandmouse:
CONTROL_NumMouseAxes = MAXMOUSEAXES;
CONTROL_NumMouseButtons = MAXMOUSEBUTTONS;
CONTROL_MousePresent = MOUSE_Init();
CONTROL_MouseEnabled = CONTROL_MousePresent;
// break;
// case controltype_keyboardandjoystick:
CONTROL_NumJoyAxes = min(MAXJOYAXES,joynumaxes);
CONTROL_NumJoyButtons = min(MAXJOYBUTTONS,joynumbuttons + 4*(joynumhats>0));
CONTROL_JoyPresent = CONTROL_StartJoy(0);;
CONTROL_JoystickEnabled = CONTROL_JoyPresent;
// break;
//}
if (CONTROL_MousePresent)
initprintf("CONTROL_Startup: Mouse Present\n");
if (CONTROL_JoyPresent)
initprintf("CONTROL_Startup: Joystick Present\n");
CONTROL_ButtonState1 = 0;
CONTROL_ButtonState2 = 0;
CONTROL_ButtonHeldState1 = 0;
CONTROL_ButtonHeldState2 = 0;
memset(CONTROL_UserInputCleared, 0, sizeof(CONTROL_UserInputCleared));
for (i=0; i<CONTROL_NUM_FLAGS; i++)
CONTROL_Flags[i].used = false;
CONTROL_Started = true;
return false;
}
void CONTROL_Shutdown(void)
{
if (!CONTROL_Started) return;
CONTROL_JoyPresent = false;
MOUSE_Shutdown();
uninitinput();
CONTROL_Started = false;
}