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qzdoom/src/p_lnspec.cpp

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/*
** p_lnspec.cpp
** Handles line specials
**
**---------------------------------------------------------------------------
** Copyright 1998-2007 Randy Heit
** All rights reserved.
**
** Redistribution and use in source and binary forms, with or without
** modification, are permitted provided that the following conditions
** are met:
**
** 1. Redistributions of source code must retain the above copyright
** notice, this list of conditions and the following disclaimer.
** 2. Redistributions in binary form must reproduce the above copyright
** notice, this list of conditions and the following disclaimer in the
** documentation and/or other materials provided with the distribution.
** 3. The name of the author may not be used to endorse or promote products
** derived from this software without specific prior written permission.
**
** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
** IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
** INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
** NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
** DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
** THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
** THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
**---------------------------------------------------------------------------
**
** Each function returns true if it caused something to happen
** or false if it could not perform the desired action.
*/
#include "doomstat.h"
#include "p_local.h"
#include "p_lnspec.h"
#include "p_enemy.h"
#include "g_level.h"
#include "v_palette.h"
#include "tables.h"
#include "i_system.h"
#include "a_sharedglobal.h"
#include "a_lightning.h"
#include "statnums.h"
#include "s_sound.h"
#include "templates.h"
#include "a_keys.h"
#include "gi.h"
#include "m_random.h"
#include "p_conversation.h"
#include "a_strifeglobal.h"
#include "r_data/r_translate.h"
#include "p_3dmidtex.h"
#include "d_net.h"
#include "d_event.h"
#include "r_data/colormaps.h"
#define FUNC(a) static int a (line_t *ln, AActor *it, bool backSide, \
int arg0, int arg1, int arg2, int arg3, int arg4)
#define SPEED(a) ((a)*(FRACUNIT/8))
#define TICS(a) (((a)*TICRATE)/35)
#define OCTICS(a) (((a)*TICRATE)/8)
#define BYTEANGLE(a) ((angle_t)((a)<<24))
#define CRUSHTYPE(a) ((a)==1? false : (a)==2? true : gameinfo.gametype == GAME_Hexen)
static FRandom pr_glass ("GlassBreak");
// There are aliases for the ACS specials that take names instead of numbers.
// This table maps them onto the real number-based specials.
BYTE NamedACSToNormalACS[7] =
{
ACS_Execute,
ACS_Suspend,
ACS_Terminate,
ACS_LockedExecute,
ACS_LockedExecuteDoor,
ACS_ExecuteWithResult,
ACS_ExecuteAlways,
};
FName MODtoDamageType (int mod)
{
switch (mod)
{
default: return NAME_None; break;
case 9: return NAME_BFGSplash; break;
case 12: return NAME_Drowning; break;
case 13: return NAME_Slime; break;
case 14: return NAME_Fire; break;
case 15: return NAME_Crush; break;
case 16: return NAME_Telefrag; break;
case 17: return NAME_Falling; break;
case 18: return NAME_Suicide; break;
case 20: return NAME_Exit; break;
case 22: return NAME_Melee; break;
case 23: return NAME_Railgun; break;
case 24: return NAME_Ice; break;
case 25: return NAME_Disintegrate; break;
case 26: return NAME_Poison; break;
case 27: return NAME_Electric; break;
case 1000: return NAME_Massacre; break;
}
}
FUNC(LS_NOP)
{
return false;
}
FUNC(LS_Polyobj_RotateLeft)
// Polyobj_RotateLeft (po, speed, angle)
{
return EV_RotatePoly (ln, arg0, arg1, arg2, 1, false);
}
FUNC(LS_Polyobj_RotateRight)
// Polyobj_rotateRight (po, speed, angle)
{
return EV_RotatePoly (ln, arg0, arg1, arg2, -1, false);
}
FUNC(LS_Polyobj_Move)
// Polyobj_Move (po, speed, angle, distance)
{
return EV_MovePoly (ln, arg0, SPEED(arg1), BYTEANGLE(arg2), arg3 * FRACUNIT, false);
}
FUNC(LS_Polyobj_MoveTimes8)
// Polyobj_MoveTimes8 (po, speed, angle, distance)
{
return EV_MovePoly (ln, arg0, SPEED(arg1), BYTEANGLE(arg2), arg3 * FRACUNIT * 8, false);
}
FUNC(LS_Polyobj_MoveTo)
// Polyobj_MoveTo (po, speed, x, y)
{
return EV_MovePolyTo (ln, arg0, SPEED(arg1), arg2 << FRACBITS, arg3 << FRACBITS, false);
}
FUNC(LS_Polyobj_MoveToSpot)
// Polyobj_MoveToSpot (po, speed, tid)
{
FActorIterator iterator (arg2);
AActor *spot = iterator.Next();
if (spot == NULL) return false;
return EV_MovePolyTo (ln, arg0, SPEED(arg1), spot->x, spot->y, false);
}
FUNC(LS_Polyobj_DoorSwing)
// Polyobj_DoorSwing (po, speed, angle, delay)
{
return EV_OpenPolyDoor (ln, arg0, arg1, BYTEANGLE(arg2), arg3, 0, PODOOR_SWING);
}
FUNC(LS_Polyobj_DoorSlide)
// Polyobj_DoorSlide (po, speed, angle, distance, delay)
{
return EV_OpenPolyDoor (ln, arg0, SPEED(arg1), BYTEANGLE(arg2), arg4, arg3*FRACUNIT, PODOOR_SLIDE);
}
FUNC(LS_Polyobj_OR_RotateLeft)
// Polyobj_OR_RotateLeft (po, speed, angle)
{
return EV_RotatePoly (ln, arg0, arg1, arg2, 1, true);
}
FUNC(LS_Polyobj_OR_RotateRight)
// Polyobj_OR_RotateRight (po, speed, angle)
{
return EV_RotatePoly (ln, arg0, arg1, arg2, -1, true);
}
FUNC(LS_Polyobj_OR_Move)
// Polyobj_OR_Move (po, speed, angle, distance)
{
return EV_MovePoly (ln, arg0, SPEED(arg1), BYTEANGLE(arg2), arg3 * FRACUNIT, true);
}
FUNC(LS_Polyobj_OR_MoveTimes8)
// Polyobj_OR_MoveTimes8 (po, speed, angle, distance)
{
return EV_MovePoly (ln, arg0, SPEED(arg1), BYTEANGLE(arg2), arg3 * FRACUNIT * 8, true);
}
FUNC(LS_Polyobj_OR_MoveTo)
// Polyobj_OR_MoveTo (po, speed, x, y)
{
return EV_MovePolyTo (ln, arg0, SPEED(arg1), arg2 << FRACBITS, arg3 << FRACBITS, true);
}
FUNC(LS_Polyobj_OR_MoveToSpot)
// Polyobj_OR_MoveToSpot (po, speed, tid)
{
FActorIterator iterator (arg2);
AActor *spot = iterator.Next();
if (spot == NULL) return false;
return EV_MovePolyTo (ln, arg0, SPEED(arg1), spot->x, spot->y, true);
}
FUNC(LS_Polyobj_Stop)
// Polyobj_Stop (po)
{
return EV_StopPoly (arg0);
}
FUNC(LS_Door_Close)
// Door_Close (tag, speed, lighttag)
{
return EV_DoDoor (DDoor::doorClose, ln, it, arg0, SPEED(arg1), 0, 0, arg2);
}
FUNC(LS_Door_Open)
// Door_Open (tag, speed, lighttag)
{
return EV_DoDoor (DDoor::doorOpen, ln, it, arg0, SPEED(arg1), 0, 0, arg2);
}
FUNC(LS_Door_Raise)
// Door_Raise (tag, speed, delay, lighttag)
{
return EV_DoDoor (DDoor::doorRaise, ln, it, arg0, SPEED(arg1), TICS(arg2), 0, arg3);
}
FUNC(LS_Door_LockedRaise)
// Door_LockedRaise (tag, speed, delay, lock, lighttag)
{
return EV_DoDoor (arg2 ? DDoor::doorRaise : DDoor::doorOpen, ln, it,
arg0, SPEED(arg1), TICS(arg2), arg3, arg4);
}
FUNC(LS_Door_CloseWaitOpen)
// Door_CloseWaitOpen (tag, speed, delay, lighttag)
{
return EV_DoDoor (DDoor::doorCloseWaitOpen, ln, it, arg0, SPEED(arg1), OCTICS(arg2), 0, arg3);
}
FUNC(LS_Door_Animated)
// Door_Animated (tag, speed, delay, lock)
{
if (arg3 != 0 && !P_CheckKeys (it, arg3, arg0 != 0))
return false;
return EV_SlidingDoor (ln, it, arg0, arg1, arg2);
}
FUNC(LS_Generic_Door)
// Generic_Door (tag, speed, kind, delay, lock)
{
int tag, lightTag;
DDoor::EVlDoor type;
bool boomgen = false;
switch (arg2 & 63)
{
case 0: type = DDoor::doorRaise; break;
case 1: type = DDoor::doorOpen; break;
case 2: type = DDoor::doorCloseWaitOpen; break;
case 3: type = DDoor::doorClose; break;
default: return false;
}
// Boom doesn't allow manual generalized doors to be activated while they move
if (arg2 & 64) boomgen = true;
if (arg2 & 128)
{
// New for 2.0.58: Finally support BOOM's local door light effect
tag = 0;
lightTag = arg0;
}
else
{
tag = arg0;
lightTag = 0;
}
return EV_DoDoor (type, ln, it, tag, SPEED(arg1), OCTICS(arg3), arg4, lightTag, boomgen);
}
FUNC(LS_Floor_LowerByValue)
// Floor_LowerByValue (tag, speed, height)
{
return EV_DoFloor (DFloor::floorLowerByValue, ln, arg0, SPEED(arg1), FRACUNIT*arg2, 0, 0, false);
}
FUNC(LS_Floor_LowerToLowest)
// Floor_LowerToLowest (tag, speed)
{
return EV_DoFloor (DFloor::floorLowerToLowest, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
FUNC(LS_Floor_LowerToHighest)
// Floor_LowerToHighest (tag, speed, adjust, hereticlower)
{
return EV_DoFloor (DFloor::floorLowerToHighest, ln, arg0, SPEED(arg1), (arg2-128)*FRACUNIT, 0, 0, false, arg3==1);
}
FUNC(LS_Floor_LowerToNearest)
// Floor_LowerToNearest (tag, speed)
{
return EV_DoFloor (DFloor::floorLowerToNearest, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
FUNC(LS_Floor_RaiseByValue)
// Floor_RaiseByValue (tag, speed, height)
{
return EV_DoFloor (DFloor::floorRaiseByValue, ln, arg0, SPEED(arg1), FRACUNIT*arg2, 0, 0, false);
}
FUNC(LS_Floor_RaiseToHighest)
// Floor_RaiseToHighest (tag, speed)
{
return EV_DoFloor (DFloor::floorRaiseToHighest, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
FUNC(LS_Floor_RaiseToNearest)
// Floor_RaiseToNearest (tag, speed)
{
return EV_DoFloor (DFloor::floorRaiseToNearest, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
FUNC(LS_Floor_RaiseAndCrush)
// Floor_RaiseAndCrush (tag, speed, crush, crushmode)
{
return EV_DoFloor (DFloor::floorRaiseAndCrush, ln, arg0, SPEED(arg1), 0, arg2, 0, CRUSHTYPE(arg3));
}
FUNC(LS_Floor_RaiseAndCrushDoom)
// Floor_RaiseAndCrushDoom (tag, speed, crush, crushmode)
{
return EV_DoFloor (DFloor::floorRaiseAndCrushDoom, ln, arg0, SPEED(arg1), 0, arg2, 0, CRUSHTYPE(arg3));
}
FUNC(LS_Floor_RaiseByValueTimes8)
// FLoor_RaiseByValueTimes8 (tag, speed, height)
{
return EV_DoFloor (DFloor::floorRaiseByValue, ln, arg0, SPEED(arg1), FRACUNIT*arg2*8, 0, 0, false);
}
FUNC(LS_Floor_LowerByValueTimes8)
// Floor_LowerByValueTimes8 (tag, speed, height)
{
return EV_DoFloor (DFloor::floorLowerByValue, ln, arg0, SPEED(arg1), FRACUNIT*arg2*8, 0, 0, false);
}
FUNC(LS_Floor_CrushStop)
// Floor_CrushStop (tag)
{
return EV_FloorCrushStop (arg0);
}
FUNC(LS_Floor_LowerInstant)
// Floor_LowerInstant (tag, unused, height)
{
return EV_DoFloor (DFloor::floorLowerInstant, ln, arg0, 0, arg2*FRACUNIT*8, 0, 0, false);
}
FUNC(LS_Floor_RaiseInstant)
// Floor_RaiseInstant (tag, unused, height)
{
return EV_DoFloor (DFloor::floorRaiseInstant, ln, arg0, 0, arg2*FRACUNIT*8, 0, 0, false);
}
FUNC(LS_Floor_MoveToValueTimes8)
// Floor_MoveToValueTimes8 (tag, speed, height, negative)
{
return EV_DoFloor (DFloor::floorMoveToValue, ln, arg0, SPEED(arg1),
arg2*FRACUNIT*8*(arg3?-1:1), 0, 0, false);
}
FUNC(LS_Floor_MoveToValue)
// Floor_MoveToValue (tag, speed, height, negative)
{
return EV_DoFloor (DFloor::floorMoveToValue, ln, arg0, SPEED(arg1),
arg2*FRACUNIT*(arg3?-1:1), 0, 0, false);
}
FUNC(LS_Floor_RaiseToLowestCeiling)
// Floor_RaiseToLowestCeiling (tag, speed)
{
return EV_DoFloor (DFloor::floorRaiseToLowestCeiling, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
FUNC(LS_Floor_RaiseByTexture)
// Floor_RaiseByTexture (tag, speed)
{
return EV_DoFloor (DFloor::floorRaiseByTexture, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
FUNC(LS_Floor_RaiseByValueTxTy)
// Floor_RaiseByValueTxTy (tag, speed, height)
{
return EV_DoFloor (DFloor::floorRaiseAndChange, ln, arg0, SPEED(arg1), arg2*FRACUNIT, 0, 0, false);
}
FUNC(LS_Floor_LowerToLowestTxTy)
// Floor_LowerToLowestTxTy (tag, speed)
{
return EV_DoFloor (DFloor::floorLowerAndChange, ln, arg0, SPEED(arg1), arg2*FRACUNIT, 0, 0, false);
}
FUNC(LS_Floor_Waggle)
// Floor_Waggle (tag, amplitude, frequency, delay, time)
{
return EV_StartWaggle (arg0, ln, arg1, arg2, arg3, arg4, false);
}
FUNC(LS_Ceiling_Waggle)
// Ceiling_Waggle (tag, amplitude, frequency, delay, time)
{
return EV_StartWaggle (arg0, ln, arg1, arg2, arg3, arg4, true);
}
FUNC(LS_Floor_TransferTrigger)
// Floor_TransferTrigger (tag)
{
return EV_DoChange (ln, trigChangeOnly, arg0);
}
FUNC(LS_Floor_TransferNumeric)
// Floor_TransferNumeric (tag)
{
return EV_DoChange (ln, numChangeOnly, arg0);
}
FUNC(LS_Floor_Donut)
// Floor_Donut (pillartag, pillarspeed, slimespeed)
{
return EV_DoDonut (arg0, ln, SPEED(arg1), SPEED(arg2));
}
FUNC(LS_Generic_Floor)
// Generic_Floor (tag, speed, height, target, change/model/direct/crush)
{
DFloor::EFloor type;
if (arg4 & 8)
{
switch (arg3)
{
case 1: type = DFloor::floorRaiseToHighest; break;
case 2: type = DFloor::floorRaiseToLowest; break;
case 3: type = DFloor::floorRaiseToNearest; break;
case 4: type = DFloor::floorRaiseToLowestCeiling; break;
case 5: type = DFloor::floorRaiseToCeiling; break;
case 6: type = DFloor::floorRaiseByTexture; break;
default:type = DFloor::floorRaiseByValue; break;
}
}
else
{
switch (arg3)
{
case 1: type = DFloor::floorLowerToHighest; break;
case 2: type = DFloor::floorLowerToLowest; break;
case 3: type = DFloor::floorLowerToNearest; break;
case 4: type = DFloor::floorLowerToLowestCeiling; break;
case 5: type = DFloor::floorLowerToCeiling; break;
case 6: type = DFloor::floorLowerByTexture; break;
default:type = DFloor::floorLowerByValue; break;
}
}
return EV_DoFloor (type, ln, arg0, SPEED(arg1), arg2*FRACUNIT,
(arg4 & 16) ? 20 : -1, arg4 & 7, false);
}
FUNC(LS_Stairs_BuildDown)
// Stair_BuildDown (tag, speed, height, delay, reset)
{
return EV_BuildStairs (arg0, DFloor::buildDown, ln,
arg2 * FRACUNIT, SPEED(arg1), TICS(arg3), arg4, 0, 1);
}
FUNC(LS_Stairs_BuildUp)
// Stairs_BuildUp (tag, speed, height, delay, reset)
{
return EV_BuildStairs (arg0, DFloor::buildUp, ln,
arg2 * FRACUNIT, SPEED(arg1), TICS(arg3), arg4, 0, 1);
}
FUNC(LS_Stairs_BuildDownSync)
// Stairs_BuildDownSync (tag, speed, height, reset)
{
return EV_BuildStairs (arg0, DFloor::buildDown, ln,
arg2 * FRACUNIT, SPEED(arg1), 0, arg3, 0, 2);
}
FUNC(LS_Stairs_BuildUpSync)
// Stairs_BuildUpSync (tag, speed, height, reset)
{
return EV_BuildStairs (arg0, DFloor::buildUp, ln,
arg2 * FRACUNIT, SPEED(arg1), 0, arg3, 0, 2);
}
FUNC(LS_Stairs_BuildUpDoom)
// Stairs_BuildUpDoom (tag, speed, height, delay, reset)
{
return EV_BuildStairs (arg0, DFloor::buildUp, ln,
arg2 * FRACUNIT, SPEED(arg1), TICS(arg3), arg4, 0, 0);
}
FUNC(LS_Generic_Stairs)
// Generic_Stairs (tag, speed, step, dir/igntxt, reset)
{
DFloor::EStair type = (arg3 & 1) ? DFloor::buildUp : DFloor::buildDown;
bool res = EV_BuildStairs (arg0, type, ln,
arg2 * FRACUNIT, SPEED(arg1), 0, arg4, arg3 & 2, 0);
if (res && ln && (ln->flags & ML_REPEAT_SPECIAL) && ln->special == Generic_Stairs)
// Toggle direction of next activation of repeatable stairs
ln->args[3] ^= 1;
return res;
}
FUNC(LS_Pillar_Build)
// Pillar_Build (tag, speed, height)
{
return EV_DoPillar (DPillar::pillarBuild, arg0, SPEED(arg1), arg2*FRACUNIT, 0, -1, false);
}
FUNC(LS_Pillar_BuildAndCrush)
// Pillar_BuildAndCrush (tag, speed, height, crush, crushtype)
{
return EV_DoPillar (DPillar::pillarBuild, arg0, SPEED(arg1), arg2*FRACUNIT, 0, arg3, CRUSHTYPE(arg4));
}
FUNC(LS_Pillar_Open)
// Pillar_Open (tag, speed, f_height, c_height)
{
return EV_DoPillar (DPillar::pillarOpen, arg0, SPEED(arg1), arg2*FRACUNIT, arg3*FRACUNIT, -1, false);
}
FUNC(LS_Ceiling_LowerByValue)
// Ceiling_LowerByValue (tag, speed, height)
{
return EV_DoCeiling (DCeiling::ceilLowerByValue, ln, arg0, SPEED(arg1), 0, arg2*FRACUNIT, -1, 0, 0, false);
}
FUNC(LS_Ceiling_RaiseByValue)
// Ceiling_RaiseByValue (tag, speed, height)
{
return EV_DoCeiling (DCeiling::ceilRaiseByValue, ln, arg0, SPEED(arg1), 0, arg2*FRACUNIT, -1, 0, 0, false);
}
FUNC(LS_Ceiling_LowerByValueTimes8)
// Ceiling_LowerByValueTimes8 (tag, speed, height)
{
return EV_DoCeiling (DCeiling::ceilLowerByValue, ln, arg0, SPEED(arg1), 0, arg2*FRACUNIT*8, -1, 0, 0, false);
}
FUNC(LS_Ceiling_RaiseByValueTimes8)
// Ceiling_RaiseByValueTimes8 (tag, speed, height)
{
return EV_DoCeiling (DCeiling::ceilRaiseByValue, ln, arg0, SPEED(arg1), 0, arg2*FRACUNIT*8, -1, 0, 0, false);
}
FUNC(LS_Ceiling_CrushAndRaise)
// Ceiling_CrushAndRaise (tag, speed, crush, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushAndRaise, ln, arg0, SPEED(arg1), SPEED(arg1)/2, 0, arg2, 0, 0, CRUSHTYPE(arg3));
}
FUNC(LS_Ceiling_LowerAndCrush)
// Ceiling_LowerAndCrush (tag, speed, crush, crushtype)
{
return EV_DoCeiling (DCeiling::ceilLowerAndCrush, ln, arg0, SPEED(arg1), SPEED(arg1), 0, arg2, 0, 0, CRUSHTYPE(arg3));
}
FUNC(LS_Ceiling_LowerAndCrushDist)
// Ceiling_LowerAndCrush (tag, speed, crush, dist, crushtype)
{
return EV_DoCeiling (DCeiling::ceilLowerAndCrushDist, ln, arg0, SPEED(arg1), SPEED(arg1), arg3*FRACUNIT, arg2, 0, 0, CRUSHTYPE(arg4));
}
FUNC(LS_Ceiling_CrushStop)
// Ceiling_CrushStop (tag)
{
return EV_CeilingCrushStop (arg0);
}
FUNC(LS_Ceiling_CrushRaiseAndStay)
// Ceiling_CrushRaiseAndStay (tag, speed, crush, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushRaiseAndStay, ln, arg0, SPEED(arg1), SPEED(arg1)/2, 0, arg2, 0, 0, CRUSHTYPE(arg3));
}
FUNC(LS_Ceiling_MoveToValueTimes8)
// Ceiling_MoveToValueTimes8 (tag, speed, height, negative)
{
return EV_DoCeiling (DCeiling::ceilMoveToValue, ln, arg0, SPEED(arg1), 0,
arg2*FRACUNIT*8*((arg3) ? -1 : 1), -1, 0, 0, false);
}
FUNC(LS_Ceiling_MoveToValue)
// Ceiling_MoveToValue (tag, speed, height, negative)
{
return EV_DoCeiling (DCeiling::ceilMoveToValue, ln, arg0, SPEED(arg1), 0,
arg2*FRACUNIT*((arg3) ? -1 : 1), -1, 0, 0, false);
}
FUNC(LS_Ceiling_LowerToHighestFloor)
// Ceiling_LowerToHighestFloor (tag, speed)
{
return EV_DoCeiling (DCeiling::ceilLowerToHighestFloor, ln, arg0, SPEED(arg1), 0, 0, -1, 0, 0, false);
}
FUNC(LS_Ceiling_LowerInstant)
// Ceiling_LowerInstant (tag, unused, height)
{
return EV_DoCeiling (DCeiling::ceilLowerInstant, ln, arg0, 0, 0, arg2*FRACUNIT*8, -1, 0, 0, false);
}
FUNC(LS_Ceiling_RaiseInstant)
// Ceiling_RaiseInstant (tag, unused, height)
{
return EV_DoCeiling (DCeiling::ceilRaiseInstant, ln, arg0, 0, 0, arg2*FRACUNIT*8, -1, 0, 0, false);
}
FUNC(LS_Ceiling_CrushRaiseAndStayA)
// Ceiling_CrushRaiseAndStayA (tag, dnspeed, upspeed, damage, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushRaiseAndStay, ln, arg0, SPEED(arg1), SPEED(arg2), 0, arg3, 0, 0, CRUSHTYPE(arg4));
}
FUNC(LS_Ceiling_CrushRaiseAndStaySilA)
// Ceiling_CrushRaiseAndStaySilA (tag, dnspeed, upspeed, damage, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushRaiseAndStay, ln, arg0, SPEED(arg1), SPEED(arg2), 0, arg3, 1, 0, CRUSHTYPE(arg4));
}
FUNC(LS_Ceiling_CrushAndRaiseA)
// Ceiling_CrushAndRaiseA (tag, dnspeed, upspeed, damage, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushAndRaise, ln, arg0, SPEED(arg1), SPEED(arg2), 0, arg3, 0, 0, CRUSHTYPE(arg4));
}
FUNC(LS_Ceiling_CrushAndRaiseDist)
// Ceiling_CrushAndRaiseDist (tag, dist, speed, damage, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushAndRaiseDist, ln, arg0, SPEED(arg2), SPEED(arg2), arg1*FRACUNIT, arg3, 0, 0, CRUSHTYPE(arg4));
}
FUNC(LS_Ceiling_CrushAndRaiseSilentA)
// Ceiling_CrushAndRaiseSilentA (tag, dnspeed, upspeed, damage, crushtype)
{
return EV_DoCeiling (DCeiling::ceilCrushAndRaise, ln, arg0, SPEED(arg1), SPEED(arg2), 0, arg3, 1, 0, CRUSHTYPE(arg4));
}
FUNC(LS_Ceiling_RaiseToNearest)
// Ceiling_RaiseToNearest (tag, speed)
{
return EV_DoCeiling (DCeiling::ceilRaiseToNearest, ln, arg0, SPEED(arg1), 0, 0, -1, 0, 0, false);
}
FUNC(LS_Ceiling_LowerToLowest)
// Ceiling_LowerToLowest (tag, speed)
{
return EV_DoCeiling (DCeiling::ceilLowerToLowest, ln, arg0, SPEED(arg1), 0, 0, -1, 0, 0, false);
}
FUNC(LS_Ceiling_LowerToFloor)
// Ceiling_LowerToFloor (tag, speed)
{
return EV_DoCeiling (DCeiling::ceilLowerToFloor, ln, arg0, SPEED(arg1), 0, 0, -1, 0, 0, false);
}
FUNC(LS_Generic_Ceiling)
// Generic_Ceiling (tag, speed, height, target, change/model/direct/crush)
{
DCeiling::ECeiling type;
if (arg4 & 8) {
switch (arg3) {
case 1: type = DCeiling::ceilRaiseToHighest; break;
case 2: type = DCeiling::ceilRaiseToLowest; break;
case 3: type = DCeiling::ceilRaiseToNearest; break;
case 4: type = DCeiling::ceilRaiseToHighestFloor; break;
case 5: type = DCeiling::ceilRaiseToFloor; break;
case 6: type = DCeiling::ceilRaiseByTexture; break;
default: type = DCeiling::ceilRaiseByValue; break;
}
} else {
switch (arg3) {
case 1: type = DCeiling::ceilLowerToHighest; break;
case 2: type = DCeiling::ceilLowerToLowest; break;
case 3: type = DCeiling::ceilLowerToNearest; break;
case 4: type = DCeiling::ceilLowerToHighestFloor; break;
case 5: type = DCeiling::ceilLowerToFloor; break;
case 6: type = DCeiling::ceilLowerByTexture; break;
default: type = DCeiling::ceilLowerByValue; break;
}
}
return EV_DoCeiling (type, ln, arg0, SPEED(arg1), SPEED(arg1), arg2*FRACUNIT,
(arg4 & 16) ? 20 : -1, 0, arg4 & 7, false);
}
FUNC(LS_Generic_Crusher)
// Generic_Crusher (tag, dnspeed, upspeed, silent, damage)
{
return EV_DoCeiling (DCeiling::ceilCrushAndRaise, ln, arg0, SPEED(arg1),
SPEED(arg2), 0, arg4, arg3 ? 2 : 0, 0, false);
}
FUNC(LS_Generic_Crusher2)
// Generic_Crusher2 (tag, dnspeed, upspeed, silent, damage)
{
// same as above but uses Hexen's crushing method.
return EV_DoCeiling (DCeiling::ceilCrushAndRaise, ln, arg0, SPEED(arg1),
SPEED(arg2), 0, arg4, arg3 ? 2 : 0, 0, true);
}
FUNC(LS_Plat_PerpetualRaise)
// Plat_PerpetualRaise (tag, speed, delay)
{
return EV_DoPlat (arg0, ln, DPlat::platPerpetualRaise, 0, SPEED(arg1), TICS(arg2), 8, 0);
}
FUNC(LS_Plat_PerpetualRaiseLip)
// Plat_PerpetualRaiseLip (tag, speed, delay, lip)
{
return EV_DoPlat (arg0, ln, DPlat::platPerpetualRaise, 0, SPEED(arg1), TICS(arg2), arg3, 0);
}
FUNC(LS_Plat_Stop)
// Plat_Stop (tag)
{
EV_StopPlat (arg0);
return true;
}
FUNC(LS_Plat_DownWaitUpStay)
// Plat_DownWaitUpStay (tag, speed, delay)
{
return EV_DoPlat (arg0, ln, DPlat::platDownWaitUpStay, 0, SPEED(arg1), TICS(arg2), 8, 0);
}
FUNC(LS_Plat_DownWaitUpStayLip)
// Plat_DownWaitUpStayLip (tag, speed, delay, lip, floor-sound?)
{
return EV_DoPlat (arg0, ln,
arg4 ? DPlat::platDownWaitUpStayStone : DPlat::platDownWaitUpStay,
0, SPEED(arg1), TICS(arg2), arg3, 0);
}
FUNC(LS_Plat_DownByValue)
// Plat_DownByValue (tag, speed, delay, height)
{
return EV_DoPlat (arg0, ln, DPlat::platDownByValue, FRACUNIT*arg3*8, SPEED(arg1), TICS(arg2), 0, 0);
}
FUNC(LS_Plat_UpByValue)
// Plat_UpByValue (tag, speed, delay, height)
{
return EV_DoPlat (arg0, ln, DPlat::platUpByValue, FRACUNIT*arg3*8, SPEED(arg1), TICS(arg2), 0, 0);
}
FUNC(LS_Plat_UpWaitDownStay)
// Plat_UpWaitDownStay (tag, speed, delay)
{
return EV_DoPlat (arg0, ln, DPlat::platUpWaitDownStay, 0, SPEED(arg1), TICS(arg2), 0, 0);
}
FUNC(LS_Plat_UpNearestWaitDownStay)
// Plat_UpNearestWaitDownStay (tag, speed, delay)
{
return EV_DoPlat (arg0, ln, DPlat::platUpNearestWaitDownStay, 0, SPEED(arg1), TICS(arg2), 0, 0);
}
FUNC(LS_Plat_RaiseAndStayTx0)
// Plat_RaiseAndStayTx0 (tag, speed, lockout)
{
DPlat::EPlatType type;
switch (arg3)
{
case 1:
type = DPlat::platRaiseAndStay;
break;
case 2:
type = DPlat::platRaiseAndStayLockout;
break;
default:
type = gameinfo.gametype == GAME_Heretic? DPlat::platRaiseAndStayLockout : DPlat::platRaiseAndStay;
break;
}
return EV_DoPlat (arg0, ln, type, 0, SPEED(arg1), 0, 0, 1);
}
FUNC(LS_Plat_UpByValueStayTx)
// Plat_UpByValueStayTx (tag, speed, height)
{
return EV_DoPlat (arg0, ln, DPlat::platUpByValueStay, FRACUNIT*arg2*8, SPEED(arg1), 0, 0, 2);
}
FUNC(LS_Plat_ToggleCeiling)
// Plat_ToggleCeiling (tag)
{
return EV_DoPlat (arg0, ln, DPlat::platToggle, 0, 0, 0, 0, 0);
}
FUNC(LS_Generic_Lift)
// Generic_Lift (tag, speed, delay, target, height)
{
DPlat::EPlatType type;
switch (arg3)
{
case 1:
type = DPlat::platDownWaitUpStay;
break;
case 2:
type = DPlat::platDownToNearestFloor;
break;
case 3:
type = DPlat::platDownToLowestCeiling;
break;
case 4:
type = DPlat::platPerpetualRaise;
break;
default:
type = DPlat::platUpByValue;
break;
}
return EV_DoPlat (arg0, ln, type, arg4*8*FRACUNIT, SPEED(arg1), OCTICS(arg2), 0, 0);
}
FUNC(LS_Exit_Normal)
// Exit_Normal (position)
{
if (CheckIfExitIsGood (it, FindLevelInfo(G_GetExitMap())))
{
G_ExitLevel (arg0, false);
return true;
}
return false;
}
FUNC(LS_Exit_Secret)
// Exit_Secret (position)
{
if (CheckIfExitIsGood (it, FindLevelInfo(G_GetSecretExitMap())))
{
G_SecretExitLevel (arg0);
return true;
}
return false;
}
FUNC(LS_Teleport_NewMap)
// Teleport_NewMap (map, position, keepFacing?)
{
if (backSide == 0 || gameinfo.gametype == GAME_Strife)
{
level_info_t *info = FindLevelByNum (arg0);
if (info && CheckIfExitIsGood (it, info))
{
G_ChangeLevel(info->mapname, arg1, arg2 ? CHANGELEVEL_KEEPFACING : 0);
return true;
}
}
return false;
}
FUNC(LS_Teleport)
// Teleport (tid, sectortag, bNoSourceFog)
{
return EV_Teleport (arg0, arg1, ln, backSide, it, true, !arg2, false);
}
FUNC( LS_Teleport_NoStop )
// Teleport_NoStop (tid, sectortag, bNoSourceFog)
{
return EV_Teleport( arg0, arg1, ln, backSide, it, true, !arg2, false, false );
}
FUNC(LS_Teleport_NoFog)
// Teleport_NoFog (tid, useang, sectortag, keepheight)
{
return EV_Teleport (arg0, arg2, ln, backSide, it, false, false, !arg1, true, !!arg3);
}
FUNC(LS_Teleport_ZombieChanger)
// Teleport_ZombieChanger (tid, sectortag)
{
// This is practically useless outside of Strife, but oh well.
if (it != NULL)
{
EV_Teleport (arg0, arg1, ln, backSide, it, false, false, false);
if (it->health >= 0) it->SetState (it->FindState(NAME_Pain));
return true;
}
return false;
}
FUNC(LS_TeleportOther)
// TeleportOther (other_tid, dest_tid, fog?)
{
return EV_TeleportOther (arg0, arg1, arg2?true:false);
}
FUNC(LS_TeleportGroup)
// TeleportGroup (group_tid, source_tid, dest_tid, move_source?, fog?)
{
return EV_TeleportGroup (arg0, it, arg1, arg2, arg3?true:false, arg4?true:false);
}
FUNC(LS_TeleportInSector)
// TeleportInSector (tag, source_tid, dest_tid, bFog, group_tid)
{
return EV_TeleportSector (arg0, arg1, arg2, arg3?true:false, arg4);
}
FUNC(LS_Teleport_EndGame)
// Teleport_EndGame ()
{
if (!backSide && CheckIfExitIsGood (it, NULL))
{
G_ChangeLevel(NULL, 0, 0);
return true;
}
return false;
}
FUNC(LS_Teleport_Line)
// Teleport_Line (thisid, destid, reversed)
{
return EV_SilentLineTeleport (ln, backSide, it, arg1, arg2);
}
static void ThrustThingHelper (AActor *it, angle_t angle, int force, INTBOOL nolimit);
FUNC(LS_ThrustThing)
// ThrustThing (angle, force, nolimit, tid)
{
if (arg3 != 0)
{
FActorIterator iterator (arg3);
while ((it = iterator.Next()) != NULL)
{
ThrustThingHelper (it, BYTEANGLE(arg0), arg1, arg2);
}
return true;
}
else if (it)
{
ThrustThingHelper (it, BYTEANGLE(arg0), arg1, arg2);
return true;
}
return false;
}
static void ThrustThingHelper (AActor *it, angle_t angle, int force, INTBOOL nolimit)
{
angle >>= ANGLETOFINESHIFT;
it->velx += force * finecosine[angle];
it->vely += force * finesine[angle];
if (!nolimit)
{
it->velx = clamp<fixed_t> (it->velx, -MAXMOVE, MAXMOVE);
it->vely = clamp<fixed_t> (it->vely, -MAXMOVE, MAXMOVE);
}
}
FUNC(LS_ThrustThingZ) // [BC]
// ThrustThingZ (tid, zthrust, down/up, set)
{
AActor *victim;
fixed_t thrust = arg1*FRACUNIT/4;
// [BC] Up is default
if (arg2)
thrust = -thrust;
if (arg0 != 0)
{
FActorIterator iterator (arg0);
while ( (victim = iterator.Next ()) )
{
if (!arg3)
victim->velz = thrust;
else
victim->velz += thrust;
}
return true;
}
else if (it)
{
if (!arg3)
it->velz = thrust;
else
it->velz += thrust;
return true;
}
return false;
}
FUNC(LS_Thing_SetSpecial) // [BC]
// Thing_SetSpecial (tid, special, arg1, arg2, arg3)
// [RH] Use the SetThingSpecial ACS command instead.
// It can set all args and not just the first three.
{
if (arg0 == 0)
{
if (it != NULL)
{
it->special = arg1;
it->args[0] = arg2;
it->args[1] = arg3;
it->args[2] = arg4;
}
}
else
{
AActor *actor;
FActorIterator iterator (arg0);
while ( (actor = iterator.Next ()) )
{
actor->special = arg1;
actor->args[0] = arg2;
actor->args[1] = arg3;
actor->args[2] = arg4;
}
}
return true;
}
FUNC(LS_Thing_ChangeTID)
// Thing_ChangeTID (oldtid, newtid)
{
if (arg0 == 0)
{
if (it != NULL && !(it->ObjectFlags & OF_EuthanizeMe))
{
it->RemoveFromHash ();
it->tid = arg1;
it->AddToHash ();
}
}
else
{
FActorIterator iterator (arg0);
AActor *actor, *next;
next = iterator.Next ();
while (next != NULL)
{
actor = next;
next = iterator.Next ();
if (!(actor->ObjectFlags & OF_EuthanizeMe))
{
actor->RemoveFromHash ();
actor->tid = arg1;
actor->AddToHash ();
}
}
}
return true;
}
FUNC(LS_DamageThing)
// DamageThing (damage, mod)
{
if (it)
{
if (arg0 < 0)
{ // Negative damages mean healing
if (it->player)
{
P_GiveBody (it, -arg0);
}
else
{
it->health -= arg0;
if (it->SpawnHealth() < it->health)
it->health = it->SpawnHealth();
}
}
else if (arg0 > 0)
{
P_DamageMobj (it, NULL, NULL, arg0, MODtoDamageType (arg1));
}
else
{ // If zero damage, guarantee a kill
P_DamageMobj (it, NULL, NULL, TELEFRAG_DAMAGE, MODtoDamageType (arg1));
}
}
return it ? true : false;
}
FUNC(LS_HealThing)
// HealThing (amount, max)
{
if (it)
{
int max = arg1;
if (max == 0 || it->player == NULL)
{
P_GiveBody(it, arg0);
return true;
}
else if (max == 1)
{
max = deh.MaxSoulsphere;
}
// If health is already above max, do nothing
if (it->health < max)
{
it->health += arg0;
if (it->health > max && max > 0)
{
it->health = max;
}
if (it->player)
{
it->player->health = it->health;
}
}
}
return it ? true : false;
}
// So that things activated/deactivated by ACS or DECORATE *and* by
// the BUMPSPECIAL or USESPECIAL flags work correctly both ways.
void DoActivateThing(AActor * thing, AActor * activator)
{
if (thing->activationtype & THINGSPEC_Activate)
{
thing->activationtype &= ~THINGSPEC_Activate; // Clear flag
if (thing->activationtype & THINGSPEC_Switch) // Set other flag if switching
thing->activationtype |= THINGSPEC_Deactivate;
}
thing->Activate (activator);
}
void DoDeactivateThing(AActor * thing, AActor * activator)
{
if (thing->activationtype & THINGSPEC_Deactivate)
{
thing->activationtype &= ~THINGSPEC_Deactivate; // Clear flag
if (thing->activationtype & THINGSPEC_Switch) // Set other flag if switching
thing->activationtype |= THINGSPEC_Activate;
}
thing->Deactivate (activator);
}
FUNC(LS_Thing_Activate)
// Thing_Activate (tid)
{
if (arg0 != 0)
{
AActor *actor;
FActorIterator iterator (arg0);
int count = 0;
actor = iterator.Next ();
while (actor)
{
// Actor might remove itself as part of activation, so get next
// one before activating it.
AActor *temp = iterator.Next ();
DoActivateThing(actor, it);
actor = temp;
count++;
}
return count != 0;
}
else if (it != NULL)
{
DoActivateThing(it, it);
return true;
}
return false;
}
FUNC(LS_Thing_Deactivate)
// Thing_Deactivate (tid)
{
if (arg0 != 0)
{
AActor *actor;
FActorIterator iterator (arg0);
int count = 0;
actor = iterator.Next ();
while (actor)
{
// Actor might removes itself as part of deactivation, so get next
// one before we activate it.
AActor *temp = iterator.Next ();
DoDeactivateThing(actor, it);
actor = temp;
count++;
}
return count != 0;
}
else if (it != NULL)
{
DoDeactivateThing(it, it);
return true;
}
return false;
}
FUNC(LS_Thing_Remove)
// Thing_Remove (tid)
{
if (arg0 != 0)
{
FActorIterator iterator (arg0);
AActor *actor;
actor = iterator.Next ();
while (actor)
{
AActor *temp = iterator.Next ();
P_RemoveThing(actor);
actor = temp;
}
}
else if (it != NULL)
{
P_RemoveThing(it);
}
return true;
}
FUNC(LS_Thing_Destroy)
// Thing_Destroy (tid, extreme, tag)
{
AActor *actor;
if (arg0 == 0 && arg2 == 0)
{
P_Massacre ();
}
else if (arg0 == 0)
{
TThinkerIterator<AActor> iterator;
actor = iterator.Next ();
while (actor)
{
AActor *temp = iterator.Next ();
if (actor->flags & MF_SHOOTABLE && actor->Sector->tag == arg2)
P_DamageMobj (actor, NULL, it, arg1 ? TELEFRAG_DAMAGE : actor->health, NAME_None);
actor = temp;
}
}
else
{
FActorIterator iterator (arg0);
actor = iterator.Next ();
while (actor)
{
AActor *temp = iterator.Next ();
if (actor->flags & MF_SHOOTABLE && (arg2 == 0 || actor->Sector->tag == arg2))
P_DamageMobj (actor, NULL, it, arg1 ? TELEFRAG_DAMAGE : actor->health, NAME_None);
actor = temp;
}
}
return true;
}
FUNC(LS_Thing_Damage)
// Thing_Damage (tid, amount, MOD)
{
P_Thing_Damage (arg0, it, arg1, MODtoDamageType (arg2));
return true;
}
FUNC(LS_Thing_Projectile)
// Thing_Projectile (tid, type, angle, speed, vspeed)
{
return P_Thing_Projectile (arg0, it, arg1, NULL, BYTEANGLE(arg2), arg3<<(FRACBITS-3),
arg4<<(FRACBITS-3), 0, NULL, 0, 0, false);
}
FUNC(LS_Thing_ProjectileGravity)
// Thing_ProjectileGravity (tid, type, angle, speed, vspeed)
{
return P_Thing_Projectile (arg0, it, arg1, NULL, BYTEANGLE(arg2), arg3<<(FRACBITS-3),
arg4<<(FRACBITS-3), 0, NULL, 1, 0, false);
}
FUNC(LS_Thing_Hate)
// Thing_Hate (hater, hatee, group/"xray"?)
{
FActorIterator haterIt (arg0);
AActor *hater, *hatee = NULL;
FActorIterator hateeIt (arg1);
bool nothingToHate = false;
if (arg1 != 0)
{
while ((hatee = hateeIt.Next ()))
{
if (hatee->flags & MF_SHOOTABLE && // can't hate nonshootable things
hatee->health > 0 && // can't hate dead things
!(hatee->flags2 & MF2_DORMANT)) // can't target dormant things
{
break;
}
}
if (hatee == NULL)
{ // Nothing to hate
nothingToHate = true;
}
}
if (arg0 == 0)
{
if (it != NULL && it->player != NULL)
{
// Players cannot have their attitudes set
return false;
}
else
{
hater = it;
}
}
else
{
while ((hater = haterIt.Next ()))
{
if (hater->health > 0 && hater->flags & MF_SHOOTABLE)
{
break;
}
}
}
while (hater != NULL)
{
// Can't hate if can't attack.
if (hater->SeeState != NULL)
{
// If hating a group of things, record the TID and NULL
// the target (if its TID doesn't match). A_Look will
// find an appropriate thing to go chase after.
if (arg2 != 0)
{
hater->TIDtoHate = arg1;
hater->LastLookActor = NULL;
// If the TID to hate is 0, then don't forget the target and
// lastenemy fields.
if (arg1 != 0)
{
if (hater->target != NULL && hater->target->tid != arg1)
{
hater->target = NULL;
}
if (hater->lastenemy != NULL && hater->lastenemy->tid != arg1)
{
hater->lastenemy = NULL;
}
}
}
// Hate types for arg2:
//
// 0 - Just hate one specific actor
// 1 - Hate actors with given TID and attack players when shot
// 2 - Same as 1, but will go after enemies without seeing them first
// 3 - Hunt actors with given TID and also players
// 4 - Same as 3, but will go after monsters without seeing them first
// 5 - Hate actors with given TID and ignore player attacks
// 6 - Same as 5, but will go after enemies without seeing them first
// Note here: If you use Thing_Hate (tid, 0, 2), you can make
// a monster go after a player without seeing him first.
if (arg2 == 2 || arg2 == 4 || arg2 == 6)
{
hater->flags3 |= MF3_NOSIGHTCHECK;
}
else
{
hater->flags3 &= ~MF3_NOSIGHTCHECK;
}
if (arg2 == 3 || arg2 == 4)
{
hater->flags3 |= MF3_HUNTPLAYERS;
}
else
{
hater->flags3 &= ~MF3_HUNTPLAYERS;
}
if (arg2 == 5 || arg2 == 6)
{
hater->flags4 |= MF4_NOHATEPLAYERS;
}
else
{
hater->flags4 &= ~MF4_NOHATEPLAYERS;
}
if (arg1 == 0)
{
hatee = it;
}
else if (nothingToHate)
{
hatee = NULL;
}
else if (arg2 != 0)
{
do
{
hatee = hateeIt.Next ();
}
while ( hatee == NULL ||
hatee == hater || // can't hate self
!(hatee->flags & MF_SHOOTABLE) || // can't hate nonshootable things
hatee->health <= 0 || // can't hate dead things
(hatee->flags2 & MF2_DORMANT));
}
if (hatee != NULL && hatee != hater && (arg2 == 0 || (hater->goal != NULL && hater->target != hater->goal)))
{
if (hater->target)
{
hater->lastenemy = hater->target;
}
hater->target = hatee;
if (!(hater->flags2 & MF2_DORMANT))
{
if (hater->health > 0) hater->SetState (hater->SeeState);
}
}
}
if (arg0 != 0)
{
while ((hater = haterIt.Next ()))
{
if (hater->health > 0 && hater->flags & MF_SHOOTABLE)
{
break;
}
}
}
else
{
hater = NULL;
}
}
return true;
}
FUNC(LS_Thing_ProjectileAimed)
// Thing_ProjectileAimed (tid, type, speed, target, newtid)
{
return P_Thing_Projectile (arg0, it, arg1, NULL, 0, arg2<<(FRACBITS-3), 0, arg3, it, 0, arg4, false);
}
FUNC(LS_Thing_ProjectileIntercept)
// Thing_ProjectileIntercept (tid, type, speed, target, newtid)
{
return P_Thing_Projectile (arg0, it, arg1, NULL, 0, arg2<<(FRACBITS-3), 0, arg3, it, 0, arg4, true);
}
// [BC] added newtid for next two
FUNC(LS_Thing_Spawn)
// Thing_Spawn (tid, type, angle, newtid)
{
return P_Thing_Spawn (arg0, it, arg1, BYTEANGLE(arg2), true, arg3);
}
FUNC(LS_Thing_SpawnNoFog)
// Thing_SpawnNoFog (tid, type, angle, newtid)
{
return P_Thing_Spawn (arg0, it, arg1, BYTEANGLE(arg2), false, arg3);
}
FUNC(LS_Thing_SpawnFacing)
// Thing_SpawnFacing (tid, type, nofog, newtid)
{
return P_Thing_Spawn (arg0, it, arg1, ANGLE_MAX, arg2 ? false : true, arg3);
}
FUNC(LS_Thing_Raise)
// Thing_Raise(tid)
{
AActor * target;
bool ok = false;
if (arg0==0)
{
ok = P_Thing_Raise (it);
}
else
{
TActorIterator<AActor> iterator (arg0);
while ( (target = iterator.Next ()) )
{
ok |= P_Thing_Raise(target);
}
}
return ok;
}
FUNC(LS_Thing_Stop)
// Thing_Stop(tid)
{
AActor * target;
bool ok = false;
if (arg0==0)
{
if (it != NULL)
{
it->velx = it->vely = it->velz = 0;
if (it->player != NULL) it->player->velx = it->player->vely = 0;
ok = true;
}
}
else
{
TActorIterator<AActor> iterator (arg0);
while ( (target = iterator.Next ()) )
{
target->velx = target->vely = target->velz = 0;
if (target->player != NULL) target->player->velx = target->player->vely = 0;
ok = true;
}
}
return ok;
}
FUNC(LS_Thing_SetGoal)
// Thing_SetGoal (tid, goal, delay, chasegoal)
{
TActorIterator<AActor> selfiterator (arg0);
NActorIterator goaliterator (NAME_PatrolPoint, arg1);
AActor *self;
AActor *goal = goaliterator.Next ();
bool ok = false;
while ( (self = selfiterator.Next ()) )
{
ok = true;
if (self->flags & MF_SHOOTABLE)
{
self->goal = goal;
if (arg3 == 0) self->flags5 &=~ MF5_CHASEGOAL;
else self->flags5 |= MF5_CHASEGOAL;
if (self->target == NULL)
{
self->reactiontime = arg2 * TICRATE;
}
}
}
return ok;
}
FUNC(LS_Thing_Move) // [BC]
// Thing_Move (tid, mapspot, nofog)
{
return P_Thing_Move (arg0, it, arg1, arg2 ? false : true);
}
FUNC(LS_Thing_SetTranslation)
// Thing_SetTranslation (tid, range)
{
TActorIterator<AActor> iterator (arg0);
int range;
AActor *target;
bool ok = false;
if (arg1 == -1 && it != NULL)
{
range = it->Translation;
}
else if (arg1 >= 1 && arg1 < MAX_ACS_TRANSLATIONS)
{
range = TRANSLATION(TRANSLATION_LevelScripted, (arg1-1));
}
else
{
range = 0;
}
if (arg0 == 0)
{
if (it != NULL)
{
ok = true;
it->Translation = range==0? it->GetDefault()->Translation : range;
}
}
else
{
while ( (target = iterator.Next ()) )
{
ok = true;
target->Translation = range==0? target->GetDefault()->Translation : range;
}
}
return ok;
}
FUNC(LS_ACS_Execute)
// ACS_Execute (script, map, s_arg1, s_arg2, s_arg3)
{
level_info_t *info;
const char *mapname = NULL;
int args[3] = { arg2, arg3, arg4 };
int flags = (backSide ? ACS_BACKSIDE : 0);
if (arg1 == 0)
{
mapname = level.mapname;
}
else if ((info = FindLevelByNum(arg1)) != NULL)
{
mapname = info->mapname;
}
else
{
return false;
}
return P_StartScript(it, ln, arg0, mapname, args, 3, flags);
}
FUNC(LS_ACS_ExecuteAlways)
// ACS_ExecuteAlways (script, map, s_arg1, s_arg2, s_arg3)
{
level_info_t *info;
const char *mapname = NULL;
int args[3] = { arg2, arg3, arg4 };
int flags = (backSide ? ACS_BACKSIDE : 0) | ACS_ALWAYS;
if (arg1 == 0)
{
mapname = level.mapname;
}
else if ((info = FindLevelByNum(arg1)) != NULL)
{
mapname = info->mapname;
}
else
{
return false;
}
return P_StartScript(it, ln, arg0, mapname, args, 3, flags);
}
FUNC(LS_ACS_LockedExecute)
// ACS_LockedExecute (script, map, s_arg1, s_arg2, lock)
{
if (arg4 && !P_CheckKeys (it, arg4, true))
return false;
else
return LS_ACS_Execute (ln, it, backSide, arg0, arg1, arg2, arg3, 0);
}
FUNC(LS_ACS_LockedExecuteDoor)
// ACS_LockedExecuteDoor (script, map, s_arg1, s_arg2, lock)
{
if (arg4 && !P_CheckKeys (it, arg4, false))
return false;
else
return LS_ACS_Execute (ln, it, backSide, arg0, arg1, arg2, arg3, 0);
}
FUNC(LS_ACS_ExecuteWithResult)
// ACS_ExecuteWithResult (script, s_arg1, s_arg2, s_arg3, s_arg4)
{
// This is like ACS_ExecuteAlways, except the script is always run on
// the current map, and the return value is whatever the script sets
// with SetResultValue.
int args[4] = { arg1, arg2, arg3, arg4 };
int flags = (backSide ? ACS_BACKSIDE : 0) | ACS_ALWAYS | ACS_WANTRESULT;
return P_StartScript (it, ln, arg0, level.mapname, args, 4, flags);
}
FUNC(LS_ACS_Suspend)
// ACS_Suspend (script, map)
{
level_info_t *info;
if (arg1 == 0)
P_SuspendScript (arg0, level.mapname);
else if ((info = FindLevelByNum (arg1)) )
P_SuspendScript (arg0, info->mapname);
return true;
}
FUNC(LS_ACS_Terminate)
// ACS_Terminate (script, map)
{
level_info_t *info;
if (arg1 == 0)
P_TerminateScript (arg0, level.mapname);
else if ((info = FindLevelByNum (arg1)) )
P_TerminateScript (arg0, info->mapname);
return true;
}
FUNC(LS_FloorAndCeiling_LowerByValue)
// FloorAndCeiling_LowerByValue (tag, speed, height)
{
return EV_DoElevator (ln, DElevator::elevateLower, SPEED(arg1), arg2*FRACUNIT, arg0);
}
FUNC(LS_FloorAndCeiling_RaiseByValue)
// FloorAndCeiling_RaiseByValue (tag, speed, height)
{
return EV_DoElevator (ln, DElevator::elevateRaise, SPEED(arg1), arg2*FRACUNIT, arg0);
}
FUNC(LS_FloorAndCeiling_LowerRaise)
// FloorAndCeiling_LowerRaise (tag, fspeed, cspeed, boomemu)
{
bool res = EV_DoCeiling (DCeiling::ceilRaiseToHighest, ln, arg0, SPEED(arg2), 0, 0, 0, 0, 0, false);
// The switch based Boom equivalents of FloorandCeiling_LowerRaise do incorrect checks
// which cause the floor only to move when the ceiling fails to do so.
// To avoid problems with maps that have incorrect args this only uses a
// more or less unintuitive value for the fourth arg to trigger Boom's broken behavior
if (arg3 != 1998 || !res) // (1998 for the year in which Boom was released... :P)
{
res |= EV_DoFloor (DFloor::floorLowerToLowest, ln, arg0, SPEED(arg1), 0, 0, 0, false);
}
return res;
}
FUNC(LS_Elevator_MoveToFloor)
// Elevator_MoveToFloor (tag, speed)
{
return EV_DoElevator (ln, DElevator::elevateCurrent, SPEED(arg1), 0, arg0);
}
FUNC(LS_Elevator_RaiseToNearest)
// Elevator_RaiseToNearest (tag, speed)
{
return EV_DoElevator (ln, DElevator::elevateUp, SPEED(arg1), 0, arg0);
}
FUNC(LS_Elevator_LowerToNearest)
// Elevator_LowerToNearest (tag, speed)
{
return EV_DoElevator (ln, DElevator::elevateDown, SPEED(arg1), 0, arg0);
}
FUNC(LS_Light_ForceLightning)
// Light_ForceLightning (mode)
{
P_ForceLightning (arg0);
return true;
}
FUNC(LS_Light_RaiseByValue)
// Light_RaiseByValue (tag, value)
{
EV_LightChange (arg0, arg1);
return true;
}
FUNC(LS_Light_LowerByValue)
// Light_LowerByValue (tag, value)
{
EV_LightChange (arg0, -arg1);
return true;
}
FUNC(LS_Light_ChangeToValue)
// Light_ChangeToValue (tag, value)
{
EV_LightTurnOn (arg0, arg1);
return true;
}
FUNC(LS_Light_Fade)
// Light_Fade (tag, value, tics);
{
EV_StartLightFading (arg0, arg1, TICS(arg2));
return true;
}
FUNC(LS_Light_Glow)
// Light_Glow (tag, upper, lower, tics)
{
EV_StartLightGlowing (arg0, arg1, arg2, TICS(arg3));
return true;
}
FUNC(LS_Light_Flicker)
// Light_Flicker (tag, upper, lower)
{
EV_StartLightFlickering (arg0, arg1, arg2);
return true;
}
FUNC(LS_Light_Strobe)
// Light_Strobe (tag, upper, lower, u-tics, l-tics)
{
EV_StartLightStrobing (arg0, arg1, arg2, TICS(arg3), TICS(arg4));
return true;
}
FUNC(LS_Light_StrobeDoom)
// Light_StrobeDoom (tag, u-tics, l-tics)
{
EV_StartLightStrobing (arg0, TICS(arg1), TICS(arg2));
return true;
}
FUNC(LS_Light_MinNeighbor)
// Light_MinNeighbor (tag)
{
EV_TurnTagLightsOff (arg0);
return true;
}
FUNC(LS_Light_MaxNeighbor)
// Light_MaxNeighbor (tag)
{
EV_LightTurnOn (arg0, -1);
return true;
}
FUNC(LS_Light_Stop)
// Light_Stop (tag)
{
EV_StopLightEffect (arg0);
return true;
}
FUNC(LS_Radius_Quake)
// Radius_Quake (intensity, duration, damrad, tremrad, tid)
{
return P_StartQuake (it, arg4, arg0, arg1, arg2*64, arg3*64, "world/quake");
}
FUNC(LS_UsePuzzleItem)
// UsePuzzleItem (item, script)
{
AInventory *item;
if (!it) return false;
// Check player's inventory for puzzle item
for (item = it->Inventory; item != NULL; item = item->Inventory)
{
if (item->IsKindOf (RUNTIME_CLASS(APuzzleItem)))
{
if (static_cast<APuzzleItem*>(item)->PuzzleItemNumber == arg0)
{
if (it->UseInventory (item))
{
return true;
}
break;
}
}
}
// [RH] Say "hmm" if you don't have the puzzle item
S_Sound (it, CHAN_VOICE, "*puzzfail", 1, ATTN_IDLE);
return false;
}
FUNC(LS_Sector_ChangeSound)
// Sector_ChangeSound (tag, sound)
{
int secNum;
bool rtn;
if (!arg0)
return false;
secNum = -1;
rtn = false;
while ((secNum = P_FindSectorFromTag (arg0, secNum)) >= 0)
{
sectors[secNum].seqType = arg1;
rtn = true;
}
return rtn;
}
FUNC(LS_Sector_ChangeFlags)
// Sector_ChangeFlags (tag, set, clear)
{
int secNum;
bool rtn;
if (!arg0)
return false;
secNum = -1;
rtn = false;
while ((secNum = P_FindSectorFromTag (arg0, secNum)) >= 0)
{
sectors[secNum].Flags = (sectors[secNum].Flags | arg1) & ~arg2;
rtn = true;
}
return rtn;
}
struct FThinkerCollection
{
int RefNum;
DThinker *Obj;
};
static TArray<FThinkerCollection> Collection;
void AdjustPusher (int tag, int magnitude, int angle, DPusher::EPusher type)
{
// Find pushers already attached to the sector, and change their parameters.
{
TThinkerIterator<DPusher> iterator;
FThinkerCollection collect;
while ( (collect.Obj = iterator.Next ()) )
{
if ((collect.RefNum = ((DPusher *)collect.Obj)->CheckForSectorMatch (type, tag)) >= 0)
{
((DPusher *)collect.Obj)->ChangeValues (magnitude, angle);
Collection.Push (collect);
}
}
}
size_t numcollected = Collection.Size ();
int secnum = -1;
// Now create pushers for any sectors that don't already have them.
while ((secnum = P_FindSectorFromTag (tag, secnum)) >= 0)
{
unsigned int i;
for (i = 0; i < numcollected; i++)
{
if (Collection[i].RefNum == sectors[secnum].sectornum)
break;
}
if (i == numcollected)
{
new DPusher (type, NULL, magnitude, angle, NULL, secnum);
}
}
Collection.Clear ();
}
FUNC(LS_Sector_SetWind)
// Sector_SetWind (tag, amount, angle)
{
if (arg3)
return false;
AdjustPusher (arg0, arg1, arg2, DPusher::p_wind);
return true;
}
FUNC(LS_Sector_SetCurrent)
// Sector_SetCurrent (tag, amount, angle)
{
if (arg3)
return false;
AdjustPusher (arg0, arg1, arg2, DPusher::p_current);
return true;
}
FUNC(LS_Sector_SetFriction)
// Sector_SetFriction (tag, amount)
{
P_SetSectorFriction (arg0, arg1, true);
return true;
}
FUNC(LS_Sector_SetTranslucent)
// Sector_SetTranslucent (tag, plane, amount, type)
{
if (arg0 != 0)
{
int secnum = -1;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sectors[secnum].SetAlpha(arg1, Scale(arg2, OPAQUE, 255));
sectors[secnum].ChangeFlags(arg1, ~PLANEF_ADDITIVE, arg3? PLANEF_ADDITIVE:0);
}
return true;
}
return false;
}
FUNC(LS_Sector_SetLink)
// Sector_SetLink (controltag, linktag, floor/ceiling, movetype)
{
if (arg0 != 0) // control tag == 0 is for static initialization and must not be handled here
{
int control = P_FindSectorFromTag(arg0, -1);
if (control >= 0)
{
return P_AddSectorLinks(&sectors[control], arg1, arg2, arg3);
}
}
return false;
}
static void SetWallScroller (int id, int sidechoice, fixed_t dx, fixed_t dy, int Where)
{
Where &=7;
if (Where == 0) return;
if ((dx | dy) == 0)
{
// Special case: Remove the scroller, because the deltas are both 0.
TThinkerIterator<DScroller> iterator (STAT_SCROLLER);
DScroller *scroller;
while ( (scroller = iterator.Next ()) )
{
int wallnum = scroller->GetWallNum ();
if (wallnum >= 0 && sides[wallnum].linedef->id == id &&
int(sides[wallnum].linedef->sidedef[sidechoice] - sides) == wallnum &&
Where == scroller->GetScrollParts())
{
scroller->Destroy ();
}
}
}
else
{
// Find scrollers already attached to the matching walls, and change
// their rates.
{
TThinkerIterator<DScroller> iterator (STAT_SCROLLER);
FThinkerCollection collect;
while ( (collect.Obj = iterator.Next ()) )
{
if ((collect.RefNum = ((DScroller *)collect.Obj)->GetWallNum ()) != -1 &&
sides[collect.RefNum].linedef->id == id &&
int(sides[collect.RefNum].linedef->sidedef[sidechoice] - sides) == collect.RefNum &&
Where == ((DScroller *)collect.Obj)->GetScrollParts())
{
((DScroller *)collect.Obj)->SetRate (dx, dy);
Collection.Push (collect);
}
}
}
size_t numcollected = Collection.Size ();
int linenum = -1;
// Now create scrollers for any walls that don't already have them.
while ((linenum = P_FindLineFromID (id, linenum)) >= 0)
{
if (lines[linenum].sidedef[sidechoice] != NULL)
{
int sidenum = int(lines[linenum].sidedef[sidechoice] - sides);
unsigned int i;
for (i = 0; i < numcollected; i++)
{
if (Collection[i].RefNum == sidenum)
break;
}
if (i == numcollected)
{
new DScroller (DScroller::sc_side, dx, dy, -1, sidenum, 0, Where);
}
}
}
Collection.Clear ();
}
}
FUNC(LS_Scroll_Texture_Both)
// Scroll_Texture_Both (id, left, right, up, down)
{
if (arg0 == 0)
return false;
fixed_t dx = (arg1 - arg2) * (FRACUNIT/64);
fixed_t dy = (arg4 - arg3) * (FRACUNIT/64);
int sidechoice;
if (arg0 < 0)
{
sidechoice = 1;
arg0 = -arg0;
}
else
{
sidechoice = 0;
}
SetWallScroller (arg0, sidechoice, dx, dy, 7);
return true;
}
FUNC(LS_Scroll_Wall)
// Scroll_Wall (id, x, y, side, flags)
{
if (arg0 == 0)
return false;
SetWallScroller (arg0, !!arg3, arg1, arg2, arg4);
return true;
}
static void SetScroller (int tag, DScroller::EScrollType type, fixed_t dx, fixed_t dy)
{
TThinkerIterator<DScroller> iterator (STAT_SCROLLER);
DScroller *scroller;
int i;
// Check if there is already a scroller for this tag
// If at least one sector with this tag is scrolling, then they all are.
// If the deltas are both 0, we don't remove the scroller, because a
// displacement/accelerative scroller might have been set up, and there's
// no way to create one after the level is fully loaded.
i = 0;
while ( (scroller = iterator.Next ()) )
{
if (scroller->IsType (type))
{
if (sectors[scroller->GetAffectee ()].tag == tag)
{
i++;
scroller->SetRate (dx, dy);
}
}
}
if (i > 0 || (dx|dy) == 0)
{
return;
}
// Need to create scrollers for the sector(s)
for (i = -1; (i = P_FindSectorFromTag (tag, i)) >= 0; )
{
new DScroller (type, dx, dy, -1, i, 0);
}
}
// NOTE: For the next two functions, x-move and y-move are
// 0-based, not 128-based as they are if they appear on lines.
// Note also that parameter ordering is different.
FUNC(LS_Scroll_Floor)
// Scroll_Floor (tag, x-move, y-move, s/c)
{
fixed_t dx = arg1 * FRACUNIT/32;
fixed_t dy = arg2 * FRACUNIT/32;
if (arg3 == 0 || arg3 == 2)
{
SetScroller (arg0, DScroller::sc_floor, -dx, dy);
}
else
{
SetScroller (arg0, DScroller::sc_floor, 0, 0);
}
if (arg3 > 0)
{
SetScroller (arg0, DScroller::sc_carry, dx, dy);
}
else
{
SetScroller (arg0, DScroller::sc_carry, 0, 0);
}
return true;
}
FUNC(LS_Scroll_Ceiling)
// Scroll_Ceiling (tag, x-move, y-move, 0)
{
fixed_t dx = arg1 * FRACUNIT/32;
fixed_t dy = arg2 * FRACUNIT/32;
SetScroller (arg0, DScroller::sc_ceiling, -dx, dy);
return true;
}
FUNC(LS_PointPush_SetForce)
// PointPush_SetForce ()
{
return false;
}
FUNC(LS_Sector_SetDamage)
// Sector_SetDamage (tag, amount, mod)
{
// The sector still stores the mod in its old format because
// adding an FName to the sector_t structure might cause
// problems by adding an unwanted constructor.
// Since it doesn't really matter whether the type is translated
// here or in P_PlayerInSpecialSector I think it's the best solution.
int secnum = -1;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0) {
sectors[secnum].damage = arg1;
sectors[secnum].mod = arg2;
}
return true;
}
FUNC(LS_Sector_SetGravity)
// Sector_SetGravity (tag, intpart, fracpart)
{
int secnum = -1;
float gravity;
if (arg2 > 99)
arg2 = 99;
gravity = (float)arg1 + (float)arg2 * 0.01f;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
sectors[secnum].gravity = gravity;
return true;
}
FUNC(LS_Sector_SetColor)
// Sector_SetColor (tag, r, g, b, desaturate)
{
int secnum = -1;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sectors[secnum].SetColor(arg1, arg2, arg3, arg4);
}
return true;
}
FUNC(LS_Sector_SetFade)
// Sector_SetFade (tag, r, g, b)
{
int secnum = -1;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sectors[secnum].SetFade(arg1, arg2, arg3);
}
return true;
}
FUNC(LS_Sector_SetCeilingPanning)
// Sector_SetCeilingPanning (tag, x-int, x-frac, y-int, y-frac)
{
int secnum = -1;
fixed_t xofs = arg1 * FRACUNIT + arg2 * (FRACUNIT/100);
fixed_t yofs = arg3 * FRACUNIT + arg4 * (FRACUNIT/100);
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sectors[secnum].SetXOffset(sector_t::ceiling, xofs);
sectors[secnum].SetYOffset(sector_t::ceiling, yofs);
}
return true;
}
FUNC(LS_Sector_SetFloorPanning)
// Sector_SetFloorPanning (tag, x-int, x-frac, y-int, y-frac)
{
int secnum = -1;
fixed_t xofs = arg1 * FRACUNIT + arg2 * (FRACUNIT/100);
fixed_t yofs = arg3 * FRACUNIT + arg4 * (FRACUNIT/100);
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sectors[secnum].SetXOffset(sector_t::floor, xofs);
sectors[secnum].SetYOffset(sector_t::floor, yofs);
}
return true;
}
FUNC(LS_Sector_SetFloorScale)
// Sector_SetFloorScale (tag, x-int, x-frac, y-int, y-frac)
{
int secnum = -1;
fixed_t xscale = arg1 * FRACUNIT + arg2 * (FRACUNIT/100);
fixed_t yscale = arg3 * FRACUNIT + arg4 * (FRACUNIT/100);
if (xscale)
xscale = FixedDiv (FRACUNIT, xscale);
if (yscale)
yscale = FixedDiv (FRACUNIT, yscale);
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
if (xscale)
sectors[secnum].SetXScale(sector_t::floor, xscale);
if (yscale)
sectors[secnum].SetYScale(sector_t::floor, yscale);
}
return true;
}
FUNC(LS_Sector_SetCeilingScale)
// Sector_SetCeilingScale (tag, x-int, x-frac, y-int, y-frac)
{
int secnum = -1;
fixed_t xscale = arg1 * FRACUNIT + arg2 * (FRACUNIT/100);
fixed_t yscale = arg3 * FRACUNIT + arg4 * (FRACUNIT/100);
if (xscale)
xscale = FixedDiv (FRACUNIT, xscale);
if (yscale)
yscale = FixedDiv (FRACUNIT, yscale);
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
if (xscale)
sectors[secnum].SetXScale(sector_t::ceiling, xscale);
if (yscale)
sectors[secnum].SetYScale(sector_t::ceiling, yscale);
}
return true;
}
FUNC(LS_Sector_SetFloorScale2)
// Sector_SetFloorScale2 (tag, x-factor, y-factor)
{
int secnum = -1;
if (arg1)
arg1 = FixedDiv (FRACUNIT, arg1);
if (arg2)
arg2 = FixedDiv (FRACUNIT, arg2);
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
if (arg1)
sectors[secnum].SetXScale(sector_t::floor, arg1);
if (arg2)
sectors[secnum].SetYScale(sector_t::floor, arg2);
}
return true;
}
FUNC(LS_Sector_SetCeilingScale2)
// Sector_SetFloorScale2 (tag, x-factor, y-factor)
{
int secnum = -1;
if (arg1)
arg1 = FixedDiv (FRACUNIT, arg1);
if (arg2)
arg2 = FixedDiv (FRACUNIT, arg2);
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
if (arg1)
sectors[secnum].SetXScale(sector_t::ceiling, arg1);
if (arg2)
sectors[secnum].SetYScale(sector_t::ceiling, arg2);
}
return true;
}
FUNC(LS_Sector_SetRotation)
// Sector_SetRotation (tag, floor-angle, ceiling-angle)
{
int secnum = -1;
angle_t ceiling = arg2 * ANGLE_1;
angle_t floor = arg1 * ANGLE_1;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sectors[secnum].SetAngle(sector_t::floor, floor);
sectors[secnum].SetAngle(sector_t::ceiling, ceiling);
}
return true;
}
FUNC(LS_Line_AlignCeiling)
// Line_AlignCeiling (lineid, side)
{
int line = P_FindLineFromID (arg0, -1);
bool ret = 0;
if (line < 0)
I_Error ("Sector_AlignCeiling: Lineid %d is undefined", arg0);
do
{
ret |= P_AlignFlat (line, !!arg1, 1);
} while ( (line = P_FindLineFromID (arg0, line)) >= 0);
return ret;
}
FUNC(LS_Line_AlignFloor)
// Line_AlignFloor (lineid, side)
{
int line = P_FindLineFromID (arg0, -1);
bool ret = 0;
if (line < 0)
I_Error ("Sector_AlignFloor: Lineid %d is undefined", arg0);
do
{
ret |= P_AlignFlat (line, !!arg1, 0);
} while ( (line = P_FindLineFromID (arg0, line)) >= 0);
return ret;
}
FUNC(LS_Line_SetTextureOffset)
// Line_SetTextureOffset (id, x, y, side, flags)
{
const fixed_t NO_CHANGE = 32767<<FRACBITS;
if (arg0 == 0 || arg3 < 0 || arg3 > 1)
return false;
for(int line = -1; (line = P_FindLineFromID (arg0, line)) >= 0; )
{
side_t *side = lines[line].sidedef[arg3];
if (side != NULL)
{
if ((arg4&8)==0)
{
// set
if (arg1 != NO_CHANGE)
{
if (arg4&1) side->SetTextureXOffset(side_t::top, arg1);
if (arg4&2) side->SetTextureXOffset(side_t::mid, arg1);
if (arg4&4) side->SetTextureXOffset(side_t::bottom, arg1);
}
if (arg2 != NO_CHANGE)
{
if (arg4&1) side->SetTextureYOffset(side_t::top, arg2);
if (arg4&2) side->SetTextureYOffset(side_t::mid, arg2);
if (arg4&4) side->SetTextureYOffset(side_t::bottom, arg2);
}
}
else
{
// add
if (arg1 != NO_CHANGE)
{
if (arg4&1) side->AddTextureXOffset(side_t::top, arg1);
if (arg4&2) side->AddTextureXOffset(side_t::mid, arg1);
if (arg4&4) side->AddTextureXOffset(side_t::bottom, arg1);
}
if (arg2 != NO_CHANGE)
{
if (arg4&1) side->AddTextureYOffset(side_t::top, arg2);
if (arg4&2) side->AddTextureYOffset(side_t::mid, arg2);
if (arg4&4) side->AddTextureYOffset(side_t::bottom, arg2);
}
}
}
}
return true;
}
FUNC(LS_Line_SetTextureScale)
// Line_SetTextureScale (id, x, y, side, flags)
{
const fixed_t NO_CHANGE = 32767<<FRACBITS;
if (arg0 == 0 || arg3 < 0 || arg3 > 1)
return false;
for(int line = -1; (line = P_FindLineFromID (arg0, line)) >= 0; )
{
side_t *side = lines[line].sidedef[arg3];
if (side != NULL)
{
if ((arg4&8)==0)
{
// set
if (arg1 != NO_CHANGE)
{
if (arg4&1) side->SetTextureXScale(side_t::top, arg1);
if (arg4&2) side->SetTextureXScale(side_t::mid, arg1);
if (arg4&4) side->SetTextureXScale(side_t::bottom, arg1);
}
if (arg2 != NO_CHANGE)
{
if (arg4&1) side->SetTextureYScale(side_t::top, arg2);
if (arg4&2) side->SetTextureYScale(side_t::mid, arg2);
if (arg4&4) side->SetTextureYScale(side_t::bottom, arg2);
}
}
else
{
// add
if (arg1 != NO_CHANGE)
{
if (arg4&1) side->MultiplyTextureXScale(side_t::top, arg1);
if (arg4&2) side->MultiplyTextureXScale(side_t::mid, arg1);
if (arg4&4) side->MultiplyTextureXScale(side_t::bottom, arg1);
}
if (arg2 != NO_CHANGE)
{
if (arg4&1) side->MultiplyTextureYScale(side_t::top, arg2);
if (arg4&2) side->MultiplyTextureYScale(side_t::mid, arg2);
if (arg4&4) side->MultiplyTextureYScale(side_t::bottom, arg2);
}
}
}
}
return true;
}
FUNC(LS_Line_SetBlocking)
// Line_SetBlocking (id, setflags, clearflags)
{
static const int flagtrans[] =
{
ML_BLOCKING,
ML_BLOCKMONSTERS,
ML_BLOCK_PLAYERS,
ML_BLOCK_FLOATERS,
ML_BLOCKPROJECTILE,
ML_BLOCKEVERYTHING,
ML_RAILING,
ML_BLOCKUSE,
ML_BLOCKSIGHT,
ML_BLOCKHITSCAN,
-1
};
if (arg0 == 0) return false;
int setflags = 0;
int clearflags = 0;
for(int i = 0; flagtrans[i] != -1; i++, arg1 >>= 1, arg2 >>= 1)
{
if (arg1 & 1) setflags |= flagtrans[i];
if (arg2 & 1) clearflags |= flagtrans[i];
}
for(int line = -1; (line = P_FindLineFromID (arg0, line)) >= 0; )
{
lines[line].flags = (lines[line].flags & ~clearflags) | setflags;
}
return true;
}
FUNC(LS_ChangeCamera)
// ChangeCamera (tid, who, revert?)
{
AActor *camera;
if (arg0 != 0)
{
FActorIterator iterator (arg0);
camera = iterator.Next ();
}
else
{
camera = NULL;
}
if (!it || !it->player || arg1)
{
int i;
for (i = 0; i < MAXPLAYERS; i++)
{
if (!playeringame[i])
continue;
AActor *oldcamera = players[i].camera;
if (camera)
{
players[i].camera = camera;
if (arg2)
players[i].cheats |= CF_REVERTPLEASE;
}
else
{
players[i].camera = players[i].mo;
players[i].cheats &= ~CF_REVERTPLEASE;
}
if (oldcamera != players[i].camera)
{
R_ClearPastViewer (players[i].camera);
}
}
}
else
{
AActor *oldcamera = it->player->camera;
if (camera)
{
it->player->camera = camera;
if (arg2)
it->player->cheats |= CF_REVERTPLEASE;
}
else
{
it->player->camera = it;
it->player->cheats &= ~CF_REVERTPLEASE;
}
if (oldcamera != it->player->camera)
{
R_ClearPastViewer (it->player->camera);
}
}
return true;
}
enum
{
PROP_FROZEN,
PROP_NOTARGET,
PROP_INSTANTWEAPONSWITCH,
PROP_FLY,
PROP_TOTALLYFROZEN,
PROP_INVULNERABILITY,
PROP_STRENGTH,
PROP_INVISIBILITY,
PROP_RADIATIONSUIT,
PROP_ALLMAP,
PROP_INFRARED,
PROP_WEAPONLEVEL2,
PROP_FLIGHT,
PROP_UNUSED1,
PROP_UNUSED2,
PROP_SPEED,
PROP_BUDDHA,
};
FUNC(LS_SetPlayerProperty)
// SetPlayerProperty (who, value, which)
// who == 0: set activator's property
// who == 1: set every player's property
{
int mask = 0;
if ((!it || !it->player) && !arg0)
return false;
// Add or remove a power
if (arg2 >= PROP_INVULNERABILITY && arg2 <= PROP_SPEED)
{
static const PClass *powers[11] =
{
RUNTIME_CLASS(APowerInvulnerable),
RUNTIME_CLASS(APowerStrength),
RUNTIME_CLASS(APowerInvisibility),
RUNTIME_CLASS(APowerIronFeet),
NULL, // MapRevealer
RUNTIME_CLASS(APowerLightAmp),
RUNTIME_CLASS(APowerWeaponLevel2),
RUNTIME_CLASS(APowerFlight),
NULL,
NULL,
RUNTIME_CLASS(APowerSpeed)
};
int power = arg2 - PROP_INVULNERABILITY;
if (power > 4 && powers[power] == NULL)
{
return false;
}
if (arg0 == 0)
{
if (arg1)
{ // Give power to activator
if (power != 4)
{
APowerup *item = static_cast<APowerup*>(it->GiveInventoryType (powers[power]));
if (item != NULL && power == 0 && arg1 == 1)
{
item->BlendColor = MakeSpecialColormap(INVERSECOLORMAP);
}
}
else if (it->player - players == consoleplayer)
{
level.flags2 |= LEVEL2_ALLMAP;
}
}
else
{ // Take power from activator
if (power != 4)
{
AInventory *item = it->FindInventory (powers[power], true);
if (item != NULL)
{
item->Destroy ();
}
}
else if (it->player - players == consoleplayer)
{
level.flags2 &= ~LEVEL2_ALLMAP;
}
}
}
else
{
int i;
for (i = 0; i < MAXPLAYERS; i++)
{
if (!playeringame[i] || players[i].mo == NULL)
continue;
if (arg1)
{ // Give power
if (power != 4)
{
APowerup *item = static_cast<APowerup*>(players[i].mo->GiveInventoryType (powers[power]));
if (item != NULL && power == 0 && arg1 == 1)
{
item->BlendColor = MakeSpecialColormap(INVERSECOLORMAP);
}
}
else if (i == consoleplayer)
{
level.flags2 |= LEVEL2_ALLMAP;
}
}
else
{ // Take power
if (power != 4)
{
AInventory *item = players[i].mo->FindInventory (powers[power]);
if (item != NULL)
{
item->Destroy ();
}
}
else if (i == consoleplayer)
{
level.flags2 &= ~LEVEL2_ALLMAP;
}
}
}
}
return true;
}
// Set or clear a flag
switch (arg2)
{
case PROP_BUDDHA:
mask = CF_BUDDHA;
break;
case PROP_FROZEN:
mask = CF_FROZEN;
break;
case PROP_NOTARGET:
mask = CF_NOTARGET;
break;
case PROP_INSTANTWEAPONSWITCH:
mask = CF_INSTANTWEAPSWITCH;
break;
case PROP_FLY:
mask = CF_FLY;
break;
case PROP_TOTALLYFROZEN:
mask = CF_TOTALLYFROZEN;
break;
}
if (arg0 == 0)
{
if (arg1)
{
it->player->cheats |= mask;
if (arg2 == PROP_FLY)
{
it->flags2 |= MF2_FLY;
it->flags |= MF_NOGRAVITY;
}
}
else
{
it->player->cheats &= ~mask;
if (arg2 == PROP_FLY)
{
it->flags2 &= ~MF2_FLY;
it->flags &= ~MF_NOGRAVITY;
}
}
}
else
{
int i;
if ((ib_compatflags & BCOMPATF_LINKFROZENPROPS) && (mask & (CF_FROZEN | CF_TOTALLYFROZEN)))
{ // Clearing one of these properties clears both of them (if the compat flag is set.)
mask = CF_FROZEN | CF_TOTALLYFROZEN;
}
for (i = 0; i < MAXPLAYERS; i++)
{
if (!playeringame[i])
continue;
if (arg1)
{
players[i].cheats |= mask;
if (arg2 == PROP_FLY)
{
players[i].mo->flags2 |= MF2_FLY;
players[i].mo->flags |= MF_NOGRAVITY;
}
}
else
{
players[i].cheats &= ~mask;
if (arg2 == PROP_FLY)
{
players[i].mo->flags2 &= ~MF2_FLY;
players[i].mo->flags &= ~MF_NOGRAVITY;
}
}
}
}
return !!mask;
}
FUNC(LS_TranslucentLine)
// TranslucentLine (id, amount, type)
{
int linenum = -1;
while ((linenum = P_FindLineFromID (arg0, linenum)) >= 0)
{
lines[linenum].Alpha = Scale(clamp(arg1, 0, 255), FRACUNIT, 255);
if (arg2 == 0)
{
lines[linenum].flags &= ~ML_ADDTRANS;
}
else if (arg2 == 1)
{
lines[linenum].flags |= ML_ADDTRANS;
}
else
{
Printf ("Unknown translucency type used with TranslucentLine\n");
}
}
return true;
}
FUNC(LS_Autosave)
{
if (gameaction != ga_savegame)
{
level.flags2 &= ~LEVEL2_NOAUTOSAVEHINT;
Net_WriteByte (DEM_CHECKAUTOSAVE);
}
return true;
}
FUNC(LS_ChangeSkill)
{
if ((unsigned)arg0 >= AllSkills.Size())
{
NextSkill = -1;
}
else
{
NextSkill = arg0;
}
return true;
}
FUNC(LS_NoiseAlert)
// NoiseAlert (TID of target, TID of emitter)
{
AActor *target, *emitter;
if (arg0 == 0)
{
target = it;
}
else
{
FActorIterator iter (arg0);
target = iter.Next();
}
if (arg1 == 0)
{
emitter = it;
}
else if (arg1 == arg0)
{
emitter = target;
}
else
{
FActorIterator iter (arg1);
emitter = iter.Next();
}
P_NoiseAlert (target, emitter);
return true;
}
FUNC(LS_SendToCommunicator)
// SendToCommunicator (voc #, front-only, identify, nolog)
{
// This obviously isn't going to work for co-op.
if (arg1 && backSide)
return false;
if (it != NULL && it->player != NULL && it->FindInventory(NAME_Communicator))
{
char name[32];
mysnprintf (name, countof(name), "svox/voc%d", arg0);
if (!arg3)
{
it->player->SetLogNumber (arg0);
}
if (it->CheckLocalView (consoleplayer))
{
S_StopSound (CHAN_VOICE);
S_Sound (CHAN_VOICE, name, 1, ATTN_NORM);
if (arg2 == 0)
{
Printf (PRINT_CHAT, "Incoming Message\n");
}
else if (arg2 == 1)
{
Printf (PRINT_CHAT, "Incoming Message from BlackBird\n");
}
}
return true;
}
return false;
}
FUNC(LS_ForceField)
// ForceField ()
{
if (it != NULL)
{
P_DamageMobj (it, NULL, NULL, 16, NAME_None);
P_ThrustMobj (it, it->angle + ANGLE_180, 0x7D000);
}
return true;
}
FUNC(LS_ClearForceField)
// ClearForceField (tag)
{
int secnum = -1;
bool rtn = false;
while ((secnum = P_FindSectorFromTag (arg0, secnum)) >= 0)
{
sector_t *sec = &sectors[secnum];
rtn = true;
for (int i = 0; i < sec->linecount; ++i)
{
line_t *line = sec->lines[i];
if (line->backsector != NULL && line->special == ForceField)
{
line->flags &= ~(ML_BLOCKING|ML_BLOCKEVERYTHING);
line->special = 0;
line->sidedef[0]->SetTexture(side_t::mid, FNullTextureID());
line->sidedef[1]->SetTexture(side_t::mid, FNullTextureID());
}
}
}
return rtn;
}
FUNC(LS_GlassBreak)
// GlassBreak (bNoJunk)
{
bool switched;
bool quest1, quest2;
ln->flags &= ~(ML_BLOCKING|ML_BLOCKEVERYTHING);
switched = P_ChangeSwitchTexture (ln->sidedef[0], false, 0, &quest1);
ln->special = 0;
if (ln->sidedef[1] != NULL)
{
switched |= P_ChangeSwitchTexture (ln->sidedef[1], false, 0, &quest2);
}
else
{
quest2 = quest1;
}
if (switched)
{
if (!arg0)
{ // Break some glass
fixed_t x, y;
AActor *glass;
angle_t an;
int speed;
x = ln->v1->x + ln->dx/2;
y = ln->v1->y + ln->dy/2;
x += (ln->frontsector->soundorg[0] - x) / 5;
y += (ln->frontsector->soundorg[1] - y) / 5;
for (int i = 0; i < 7; ++i)
{
glass = Spawn("GlassJunk", x, y, ONFLOORZ, ALLOW_REPLACE);
glass->z += 24 * FRACUNIT;
glass->SetState (glass->SpawnState + (pr_glass() % glass->health));
an = pr_glass() << (32-8);
glass->angle = an;
an >>= ANGLETOFINESHIFT;
speed = pr_glass() & 3;
glass->velx = finecosine[an] * speed;
glass->vely = finesine[an] * speed;
glass->velz = (pr_glass() & 7) << FRACBITS;
// [RH] Let the shards stick around longer than they did in Strife.
glass->tics += pr_glass();
}
}
if (quest1 || quest2)
{ // Up stats and signal this mission is complete
if (it == NULL)
{
for (int i = 0; i < MAXPLAYERS; ++i)
{
if (playeringame[i])
{
it = players[i].mo;
break;
}
}
}
if (it != NULL)
{
it->GiveInventoryType (QuestItemClasses[28]);
it->GiveInventoryType (RUNTIME_CLASS(AUpgradeAccuracy));
it->GiveInventoryType (RUNTIME_CLASS(AUpgradeStamina));
}
}
}
// We already changed the switch texture, so don't make the main code switch it back.
return false;
}
FUNC(LS_StartConversation)
// StartConversation (tid, facetalker)
{
FActorIterator iterator (arg0);
AActor *target = iterator.Next();
// Nothing to talk to
if (target == NULL)
{
return false;
}
// Only living players are allowed to start conversations
if (it == NULL || it->player == NULL || it->player->mo != it || it->health<=0)
{
return false;
}
// Dead things can't talk.
if (target->health <= 0)
{
return false;
}
// Fighting things don't talk either.
if (target->flags4 & MF4_INCOMBAT)
{
return false;
}
if (target->Conversation != NULL)
{
// Give the NPC a chance to play a brief animation
target->ConversationAnimation (0);
P_StartConversation (target, it, !!arg1, true);
return true;
}
return false;
}
FUNC(LS_Thing_SetConversation)
// Thing_SetConversation (tid, dlg_id)
{
int dlg_index = -1;
FStrifeDialogueNode *node = NULL;
if (arg1 != 0)
{
dlg_index = GetConversation(arg1);
if (dlg_index == -1) return false;
node = StrifeDialogues[dlg_index];
}
if (arg0 != 0)
{
FActorIterator iterator (arg0);
while ((it = iterator.Next()) != NULL)
{
it->ConversationRoot = dlg_index;
it->Conversation = node;
}
}
else if (it)
{
it->ConversationRoot = dlg_index;
it->Conversation = node;
}
return true;
}
lnSpecFunc LineSpecials[256] =
{
/* 0 */ LS_NOP,
/* 1 */ LS_NOP, // Polyobj_StartLine,
/* 2 */ LS_Polyobj_RotateLeft,
/* 3 */ LS_Polyobj_RotateRight,
/* 4 */ LS_Polyobj_Move,
/* 5 */ LS_NOP, // Polyobj_ExplicitLine
/* 6 */ LS_Polyobj_MoveTimes8,
/* 7 */ LS_Polyobj_DoorSwing,
/* 8 */ LS_Polyobj_DoorSlide,
/* 9 */ LS_NOP, // Line_Horizon
/* 10 */ LS_Door_Close,
/* 11 */ LS_Door_Open,
/* 12 */ LS_Door_Raise,
/* 13 */ LS_Door_LockedRaise,
/* 14 */ LS_Door_Animated,
/* 15 */ LS_Autosave,
/* 16 */ LS_NOP, // Transfer_WallLight
/* 17 */ LS_Thing_Raise,
/* 18 */ LS_StartConversation,
/* 19 */ LS_Thing_Stop,
/* 20 */ LS_Floor_LowerByValue,
/* 21 */ LS_Floor_LowerToLowest,
/* 22 */ LS_Floor_LowerToNearest,
/* 23 */ LS_Floor_RaiseByValue,
/* 24 */ LS_Floor_RaiseToHighest,
/* 25 */ LS_Floor_RaiseToNearest,
/* 26 */ LS_Stairs_BuildDown,
/* 27 */ LS_Stairs_BuildUp,
/* 28 */ LS_Floor_RaiseAndCrush,
/* 29 */ LS_Pillar_Build,
/* 30 */ LS_Pillar_Open,
/* 31 */ LS_Stairs_BuildDownSync,
/* 32 */ LS_Stairs_BuildUpSync,
/* 33 */ LS_ForceField,
/* 34 */ LS_ClearForceField,
/* 35 */ LS_Floor_RaiseByValueTimes8,
/* 36 */ LS_Floor_LowerByValueTimes8,
/* 37 */ LS_Floor_MoveToValue,
/* 38 */ LS_Ceiling_Waggle,
/* 39 */ LS_Teleport_ZombieChanger,
/* 40 */ LS_Ceiling_LowerByValue,
/* 41 */ LS_Ceiling_RaiseByValue,
/* 42 */ LS_Ceiling_CrushAndRaise,
/* 43 */ LS_Ceiling_LowerAndCrush,
/* 44 */ LS_Ceiling_CrushStop,
/* 45 */ LS_Ceiling_CrushRaiseAndStay,
/* 46 */ LS_Floor_CrushStop,
/* 47 */ LS_Ceiling_MoveToValue,
/* 48 */ LS_NOP, // Sector_Attach3dMidtex
/* 49 */ LS_GlassBreak,
/* 50 */ LS_NOP, // ExtraFloor_LightOnly
/* 51 */ LS_Sector_SetLink,
/* 52 */ LS_Scroll_Wall,
/* 53 */ LS_Line_SetTextureOffset,
/* 54 */ LS_Sector_ChangeFlags,
/* 55 */ LS_Line_SetBlocking,
/* 56 */ LS_Line_SetTextureScale,
/* 57 */ LS_NOP, // Sector_SetPortal
/* 58 */ LS_NOP, // Sector_CopyScroller
/* 59 */ LS_Polyobj_OR_MoveToSpot,
/* 60 */ LS_Plat_PerpetualRaise,
/* 61 */ LS_Plat_Stop,
/* 62 */ LS_Plat_DownWaitUpStay,
/* 63 */ LS_Plat_DownByValue,
/* 64 */ LS_Plat_UpWaitDownStay,
/* 65 */ LS_Plat_UpByValue,
/* 66 */ LS_Floor_LowerInstant,
/* 67 */ LS_Floor_RaiseInstant,
/* 68 */ LS_Floor_MoveToValueTimes8,
/* 69 */ LS_Ceiling_MoveToValueTimes8,
/* 70 */ LS_Teleport,
/* 71 */ LS_Teleport_NoFog,
/* 72 */ LS_ThrustThing,
/* 73 */ LS_DamageThing,
/* 74 */ LS_Teleport_NewMap,
/* 75 */ LS_Teleport_EndGame,
/* 76 */ LS_TeleportOther,
/* 77 */ LS_TeleportGroup,
/* 78 */ LS_TeleportInSector,
/* 79 */ LS_Thing_SetConversation,
/* 80 */ LS_ACS_Execute,
/* 81 */ LS_ACS_Suspend,
/* 82 */ LS_ACS_Terminate,
/* 83 */ LS_ACS_LockedExecute,
/* 84 */ LS_ACS_ExecuteWithResult,
/* 85 */ LS_ACS_LockedExecuteDoor,
/* 86 */ LS_Polyobj_MoveToSpot,
/* 87 */ LS_Polyobj_Stop,
/* 88 */ LS_Polyobj_MoveTo,
/* 89 */ LS_Polyobj_OR_MoveTo,
/* 90 */ LS_Polyobj_OR_RotateLeft,
/* 91 */ LS_Polyobj_OR_RotateRight,
/* 92 */ LS_Polyobj_OR_Move,
/* 93 */ LS_Polyobj_OR_MoveTimes8,
/* 94 */ LS_Pillar_BuildAndCrush,
/* 95 */ LS_FloorAndCeiling_LowerByValue,
/* 96 */ LS_FloorAndCeiling_RaiseByValue,
/* 97 */ LS_Ceiling_LowerAndCrushDist,
/* 98 */ LS_Sector_SetTranslucent,
/* 99 */ LS_Floor_RaiseAndCrushDoom,
/* 100 */ LS_NOP, // Scroll_Texture_Left
/* 101 */ LS_NOP, // Scroll_Texture_Right
/* 102 */ LS_NOP, // Scroll_Texture_Up
/* 103 */ LS_NOP, // Scroll_Texture_Down
/* 104 */ LS_NOP,
/* 105 */ LS_NOP,
/* 106 */ LS_NOP,
/* 107 */ LS_NOP,
/* 108 */ LS_NOP,
/* 109 */ LS_Light_ForceLightning,
/* 110 */ LS_Light_RaiseByValue,
/* 111 */ LS_Light_LowerByValue,
/* 112 */ LS_Light_ChangeToValue,
/* 113 */ LS_Light_Fade,
/* 114 */ LS_Light_Glow,
/* 115 */ LS_Light_Flicker,
/* 116 */ LS_Light_Strobe,
/* 117 */ LS_Light_Stop,
/* 118 */ LS_NOP, // Plane_Copy
/* 119 */ LS_Thing_Damage,
/* 120 */ LS_Radius_Quake,
/* 121 */ LS_NOP, // Line_SetIdentification
/* 122 */ LS_NOP,
/* 123 */ LS_NOP,
/* 124 */ LS_NOP,
/* 125 */ LS_Thing_Move,
/* 126 */ LS_NOP,
/* 127 */ LS_Thing_SetSpecial,
/* 128 */ LS_ThrustThingZ,
/* 129 */ LS_UsePuzzleItem,
/* 130 */ LS_Thing_Activate,
/* 131 */ LS_Thing_Deactivate,
/* 132 */ LS_Thing_Remove,
/* 133 */ LS_Thing_Destroy,
/* 134 */ LS_Thing_Projectile,
/* 135 */ LS_Thing_Spawn,
/* 136 */ LS_Thing_ProjectileGravity,
/* 137 */ LS_Thing_SpawnNoFog,
/* 138 */ LS_Floor_Waggle,
/* 139 */ LS_Thing_SpawnFacing,
/* 140 */ LS_Sector_ChangeSound,
/* 141 */ LS_NOP,
/* 142 */ LS_NOP,
/* 143 */ LS_NOP,
/* 144 */ LS_NOP,
/* 145 */ LS_NOP, // 145 Player_SetTeam
/* 146 */ LS_NOP,
/* 147 */ LS_NOP,
/* 148 */ LS_NOP,
/* 149 */ LS_NOP,
/* 150 */ LS_NOP,
/* 151 */ LS_NOP,
/* 152 */ LS_NOP, // 152 Team_Score
/* 153 */ LS_NOP, // 153 Team_GivePoints
/* 154 */ LS_Teleport_NoStop,
/* 155 */ LS_NOP,
/* 156 */ LS_NOP,
/* 157 */ LS_NOP, // SetGlobalFogParameter // in GZDoom
/* 158 */ LS_NOP, // FS_Execute
/* 159 */ LS_NOP, // Sector_SetPlaneReflection in GZDoom
/* 160 */ LS_NOP, // Sector_Set3DFloor
/* 161 */ LS_NOP, // Sector_SetContents
/* 162 */ LS_NOP, // Reserved Doom64 branch
/* 163 */ LS_NOP, // Reserved Doom64 branch
/* 164 */ LS_NOP, // Reserved Doom64 branch
/* 165 */ LS_NOP, // Reserved Doom64 branch
/* 166 */ LS_NOP, // Reserved Doom64 branch
/* 167 */ LS_NOP, // Reserved Doom64 branch
/* 168 */ LS_Ceiling_CrushAndRaiseDist,
/* 169 */ LS_Generic_Crusher2,
/* 170 */ LS_Sector_SetCeilingScale2,
/* 171 */ LS_Sector_SetFloorScale2,
/* 172 */ LS_Plat_UpNearestWaitDownStay,
/* 173 */ LS_NoiseAlert,
/* 174 */ LS_SendToCommunicator,
/* 175 */ LS_Thing_ProjectileIntercept,
/* 176 */ LS_Thing_ChangeTID,
/* 177 */ LS_Thing_Hate,
/* 178 */ LS_Thing_ProjectileAimed,
/* 179 */ LS_ChangeSkill,
/* 180 */ LS_Thing_SetTranslation,
/* 181 */ LS_NOP, // Plane_Align
/* 182 */ LS_NOP, // Line_Mirror
/* 183 */ LS_Line_AlignCeiling,
/* 184 */ LS_Line_AlignFloor,
/* 185 */ LS_Sector_SetRotation,
/* 186 */ LS_Sector_SetCeilingPanning,
/* 187 */ LS_Sector_SetFloorPanning,
/* 188 */ LS_Sector_SetCeilingScale,
/* 189 */ LS_Sector_SetFloorScale,
/* 190 */ LS_NOP, // Static_Init
/* 191 */ LS_SetPlayerProperty,
/* 192 */ LS_Ceiling_LowerToHighestFloor,
/* 193 */ LS_Ceiling_LowerInstant,
/* 194 */ LS_Ceiling_RaiseInstant,
/* 195 */ LS_Ceiling_CrushRaiseAndStayA,
/* 196 */ LS_Ceiling_CrushAndRaiseA,
/* 197 */ LS_Ceiling_CrushAndRaiseSilentA,
/* 198 */ LS_Ceiling_RaiseByValueTimes8,
/* 199 */ LS_Ceiling_LowerByValueTimes8,
/* 200 */ LS_Generic_Floor,
/* 201 */ LS_Generic_Ceiling,
/* 202 */ LS_Generic_Door,
/* 203 */ LS_Generic_Lift,
/* 204 */ LS_Generic_Stairs,
/* 205 */ LS_Generic_Crusher,
/* 206 */ LS_Plat_DownWaitUpStayLip,
/* 207 */ LS_Plat_PerpetualRaiseLip,
/* 208 */ LS_TranslucentLine,
/* 209 */ LS_NOP, // Transfer_Heights
/* 210 */ LS_NOP, // Transfer_FloorLight
/* 211 */ LS_NOP, // Transfer_CeilingLight
/* 212 */ LS_Sector_SetColor,
/* 213 */ LS_Sector_SetFade,
/* 214 */ LS_Sector_SetDamage,
/* 215 */ LS_Teleport_Line,
/* 216 */ LS_Sector_SetGravity,
/* 217 */ LS_Stairs_BuildUpDoom,
/* 218 */ LS_Sector_SetWind,
/* 219 */ LS_Sector_SetFriction,
/* 220 */ LS_Sector_SetCurrent,
/* 221 */ LS_Scroll_Texture_Both,
/* 222 */ LS_NOP, // Scroll_Texture_Model
/* 223 */ LS_Scroll_Floor,
/* 224 */ LS_Scroll_Ceiling,
/* 225 */ LS_NOP, // Scroll_Texture_Offsets
/* 226 */ LS_ACS_ExecuteAlways,
/* 227 */ LS_PointPush_SetForce,
/* 228 */ LS_Plat_RaiseAndStayTx0,
/* 229 */ LS_Thing_SetGoal,
/* 230 */ LS_Plat_UpByValueStayTx,
/* 231 */ LS_Plat_ToggleCeiling,
/* 232 */ LS_Light_StrobeDoom,
/* 233 */ LS_Light_MinNeighbor,
/* 234 */ LS_Light_MaxNeighbor,
/* 235 */ LS_Floor_TransferTrigger,
/* 236 */ LS_Floor_TransferNumeric,
/* 237 */ LS_ChangeCamera,
/* 238 */ LS_Floor_RaiseToLowestCeiling,
/* 239 */ LS_Floor_RaiseByValueTxTy,
/* 240 */ LS_Floor_RaiseByTexture,
/* 241 */ LS_Floor_LowerToLowestTxTy,
/* 242 */ LS_Floor_LowerToHighest,
/* 243 */ LS_Exit_Normal,
/* 244 */ LS_Exit_Secret,
/* 245 */ LS_Elevator_RaiseToNearest,
/* 246 */ LS_Elevator_MoveToFloor,
/* 247 */ LS_Elevator_LowerToNearest,
/* 248 */ LS_HealThing,
/* 249 */ LS_Door_CloseWaitOpen,
/* 250 */ LS_Floor_Donut,
/* 251 */ LS_FloorAndCeiling_LowerRaise,
/* 252 */ LS_Ceiling_RaiseToNearest,
/* 253 */ LS_Ceiling_LowerToLowest,
/* 254 */ LS_Ceiling_LowerToFloor,
/* 255 */ LS_Ceiling_CrushRaiseAndStaySilA
};
#define DEFINE_SPECIAL(name, num, min, max, mmax) {#name, num, min, max, mmax},
static FLineSpecial LineSpecialNames[] = {
#include "actionspecials.h"
};
const FLineSpecial *LineSpecialsInfo[256];
static int STACK_ARGS lscmp (const void * a, const void * b)
{
return stricmp( ((FLineSpecial*)a)->name, ((FLineSpecial*)b)->name);
}
static struct InitLineSpecials
{
InitLineSpecials()
{
qsort(LineSpecialNames, countof(LineSpecialNames), sizeof(FLineSpecial), lscmp);
for (size_t i = 0; i < countof(LineSpecialNames); ++i)
{
assert(LineSpecialsInfo[LineSpecialNames[i].number] == NULL);
LineSpecialsInfo[LineSpecialNames[i].number] = &LineSpecialNames[i];
}
}
} DoInit;
//==========================================================================
//
// P_FindLineSpecial
//
// Finds a line special and also returns the min and max argument count.
//
//==========================================================================
int P_FindLineSpecial (const char *string, int *min_args, int *max_args)
{
int min = 0, max = countof(LineSpecialNames) - 1;
while (min <= max)
{
int mid = (min + max) / 2;
int lexval = stricmp (string, LineSpecialNames[mid].name);
if (lexval == 0)
{
if (min_args != NULL) *min_args = LineSpecialNames[mid].min_args;
if (max_args != NULL) *max_args = LineSpecialNames[mid].max_args;
return LineSpecialNames[mid].number;
}
else if (lexval > 0)
{
min = mid + 1;
}
else
{
max = mid - 1;
}
}
return 0;
}
//==========================================================================
//
// P_ExecuteSpecial
//
//==========================================================================
int P_ExecuteSpecial(int num,
struct line_t *line,
class AActor *activator,
bool backSide,
int arg1,
int arg2,
int arg3,
int arg4,
int arg5)
{
if (num >= 0 && num <= 255)
{
return LineSpecials[num](line, activator, backSide, arg1, arg2, arg3, arg4, arg5);
}
return 0;
}
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