gzdoom/src/am_map.cpp

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// Emacs style mode select -*- C++ -*-
//-----------------------------------------------------------------------------
//
// $Id:$
//
// Copyright (C) 1993-1996 by id Software, Inc.
//
// This source is available for distribution and/or modification
// only under the terms of the DOOM Source Code License as
// published by id Software. All rights reserved.
//
// The source is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// FITNESS FOR A PARTICULAR PURPOSE. See the DOOM Source Code License
// for more details.
//
//
// $Log:$
//
// DESCRIPTION: the automap code
//
//-----------------------------------------------------------------------------
#include <stdio.h>
#include "doomdef.h"
#include "templates.h"
#include "g_level.h"
#include "doomdef.h"
#include "st_stuff.h"
#include "p_local.h"
#include "p_lnspec.h"
#include "w_wad.h"
#include "a_sharedglobal.h"
#include "statnums.h"
#include "r_data/r_translate.h"
#include "d_event.h"
#include "gi.h"
#include "p_setup.h"
#include "c_bind.h"
#include "farchive.h"
#include "r_renderer.h"
#include "r_sky.h"
#include "sbar.h"
#include "m_cheat.h"
#include "i_system.h"
#include "c_dispatch.h"
#include "colormatcher.h"
2008-09-15 00:47:31 +00:00
#include "d_netinf.h"
// Needs access to LFB.
#include "v_video.h"
#include "v_palette.h"
#include "v_text.h"
// State.
#include "doomstat.h"
#include "r_state.h"
// Data.
#include "gstrings.h"
#include "am_map.h"
#include "a_artifacts.h"
#include "po_man.h"
#include "a_keys.h"
#include "r_data/colormaps.h"
//=============================================================================
//
// CVARs
//
//=============================================================================
CVAR (Int, am_rotate, 0, CVAR_ARCHIVE);
CVAR (Int, am_overlay, 0, CVAR_ARCHIVE);
CVAR (Bool, am_showsecrets, true, CVAR_ARCHIVE);
CVAR (Bool, am_showmonsters, true, CVAR_ARCHIVE);
CVAR (Bool, am_showitems, false, CVAR_ARCHIVE);
CVAR (Bool, am_showtime, true, CVAR_ARCHIVE);
CVAR (Bool, am_showtotaltime, false, CVAR_ARCHIVE);
CVAR (Int, am_colorset, 0, CVAR_ARCHIVE);
CVAR (Bool, am_customcolors, true, CVAR_ARCHIVE);
CVAR (Int, am_map_secrets, 1, CVAR_ARCHIVE);
CVAR (Int, am_drawmapback, 1, CVAR_ARCHIVE);
CVAR (Bool, am_showkeys, true, CVAR_ARCHIVE);
CVAR (Bool, am_showtriggerlines, false, CVAR_ARCHIVE);
CVAR (Int, am_showthingsprites, 0, CVAR_ARCHIVE);
//=============================================================================
//
// Automap colors
//
//=============================================================================
CVAR (Color, am_backcolor, 0x6c5440, CVAR_ARCHIVE);
CVAR (Color, am_yourcolor, 0xfce8d8, CVAR_ARCHIVE);
CVAR (Color, am_wallcolor, 0x2c1808, CVAR_ARCHIVE);
CVAR (Color, am_secretwallcolor, 0x000000, CVAR_ARCHIVE);
CVAR (Color, am_specialwallcolor, 0xffffff, CVAR_ARCHIVE);
CVAR (Color, am_tswallcolor, 0x888888, CVAR_ARCHIVE);
CVAR (Color, am_fdwallcolor, 0x887058, CVAR_ARCHIVE);
CVAR (Color, am_cdwallcolor, 0x4c3820, CVAR_ARCHIVE);
CVAR (Color, am_efwallcolor, 0x665555, CVAR_ARCHIVE);
CVAR (Color, am_thingcolor, 0xfcfcfc, CVAR_ARCHIVE);
CVAR (Color, am_gridcolor, 0x8b5a2b, CVAR_ARCHIVE);
CVAR (Color, am_xhaircolor, 0x808080, CVAR_ARCHIVE);
CVAR (Color, am_notseencolor, 0x6c6c6c, CVAR_ARCHIVE);
CVAR (Color, am_lockedcolor, 0x007800, CVAR_ARCHIVE);
CVAR (Color, am_intralevelcolor, 0x0000ff, CVAR_ARCHIVE);
CVAR (Color, am_interlevelcolor, 0xff0000, CVAR_ARCHIVE);
CVAR (Color, am_secretsectorcolor, 0xff00ff, CVAR_ARCHIVE);
CVAR (Color, am_thingcolor_friend, 0xfcfcfc, CVAR_ARCHIVE);
CVAR (Color, am_thingcolor_monster, 0xfcfcfc, CVAR_ARCHIVE);
CVAR (Color, am_thingcolor_ncmonster, 0xfcfcfc, CVAR_ARCHIVE);
CVAR (Color, am_thingcolor_item, 0xfcfcfc, CVAR_ARCHIVE);
CVAR (Color, am_thingcolor_citem, 0xfcfcfc, CVAR_ARCHIVE);
CVAR (Color, am_ovyourcolor, 0xfce8d8, CVAR_ARCHIVE);
CVAR (Color, am_ovwallcolor, 0x00ff00, CVAR_ARCHIVE);
CVAR (Color, am_ovsecretwallcolor, 0x008844, CVAR_ARCHIVE);
CVAR (Color, am_ovspecialwallcolor, 0xffffff, CVAR_ARCHIVE);
CVAR (Color, am_ovotherwallscolor, 0x008844, CVAR_ARCHIVE);
CVAR (Color, am_ovlockedcolor, 0x008844, CVAR_ARCHIVE);
CVAR (Color, am_ovefwallcolor, 0x008844, CVAR_ARCHIVE);
CVAR (Color, am_ovfdwallcolor, 0x008844, CVAR_ARCHIVE);
CVAR (Color, am_ovcdwallcolor, 0x008844, CVAR_ARCHIVE);
CVAR (Color, am_ovunseencolor, 0x00226e, CVAR_ARCHIVE);
CVAR (Color, am_ovtelecolor, 0xffff00, CVAR_ARCHIVE);
CVAR (Color, am_ovinterlevelcolor, 0xffff00, CVAR_ARCHIVE);
CVAR (Color, am_ovsecretsectorcolor,0x00ffff, CVAR_ARCHIVE);
CVAR (Color, am_ovthingcolor, 0xe88800, CVAR_ARCHIVE);
CVAR (Color, am_ovthingcolor_friend, 0xe88800, CVAR_ARCHIVE);
CVAR (Color, am_ovthingcolor_monster, 0xe88800, CVAR_ARCHIVE);
CVAR (Color, am_ovthingcolor_ncmonster, 0xe88800, CVAR_ARCHIVE);
CVAR (Color, am_ovthingcolor_item, 0xe88800, CVAR_ARCHIVE);
CVAR (Color, am_ovthingcolor_citem, 0xe88800, CVAR_ARCHIVE);
//=============================================================================
//
// internal representation of a single color
//
//=============================================================================
struct AMColor
{
int Index;
uint32 RGB;
void FromCVar(FColorCVar & cv)
{
Index = cv.GetIndex();
RGB = uint32(cv) | MAKEARGB(255, 0, 0, 0);
}
void FromRGB(int r,int g, int b)
{
RGB = MAKEARGB(255, r, g, b);
Index = ColorMatcher.Pick(r, g, b);
}
void setInvalid()
{
Index = -1;
RGB = -1;
}
bool isValid() const
{
return Index > -1;
}
};
//=============================================================================
//
// a complete color set
//
//=============================================================================
static const char *ColorNames[] = {
"Background",
"YourColor",
"WallColor",
"TwoSidedWallColor",
"FloorDiffWallColor",
"CeilingDiffWallColor",
"ExtraFloorWallColor",
"ThingColor",
"ThingColor_Item",
"ThingColor_CountItem",
"ThingColor_Monster",
"ThingColor_NocountMonster",
"ThingColor_Friend",
"SpecialWallColor",
"SecretWallColor",
"GridColor",
"XHairColor",
"NotSeenColor",
"LockedColor",
"IntraTeleportColor",
"InterTeleportColor",
"SecretSectorColor",
"AlmostBackgroundColor",
NULL
};
struct AMColorset
{
enum
{
Background,
YourColor,
WallColor,
TSWallColor,
FDWallColor,
CDWallColor,
EFWallColor,
ThingColor,
ThingColor_Item,
ThingColor_CountItem,
ThingColor_Monster,
ThingColor_NocountMonster,
ThingColor_Friend,
SpecialWallColor,
SecretWallColor,
GridColor,
XHairColor,
NotSeenColor,
LockedColor,
IntraTeleportColor,
InterTeleportColor,
SecretSectorColor,
AlmostBackgroundColor,
AM_NUM_COLORS
};
AMColor c[AM_NUM_COLORS];
bool displayLocks;
bool forcebackground;
bool defined; // only for mod specific colorsets: must be true to be usable
void initFromCVars(FColorCVar **values)
{
for(int i=0;i<AlmostBackgroundColor; i++)
{
c[i].FromCVar(*values[i]);
}
DWORD ba = *(values[0]);
int r = RPART(ba) - 16;
int g = GPART(ba) - 16;
int b = BPART(ba) - 16;
if (r < 0)
r += 32;
if (g < 0)
g += 32;
if (b < 0)
b += 32;
c[AlmostBackgroundColor].FromRGB(r, g, b);
displayLocks = true;
forcebackground = false;
}
void initFromColors(const unsigned char *colors, bool showlocks)
{
for(int i=0, j=0; i<AM_NUM_COLORS; i++, j+=3)
{
if (colors[j] == 1 && colors[j+1] == 0 && colors[j+2] == 0)
{
c[i].setInvalid();
}
else
{
c[i].FromRGB(colors[j], colors[j+1], colors[j+2]);
}
}
displayLocks = showlocks;
forcebackground = false;
}
void setWhite()
{
c[0].FromRGB(0,0,0);
for(int i=1; i<AM_NUM_COLORS; i++)
{
c[i].FromRGB(255,255,255);
}
}
const AMColor &operator[](int index) const
{
return c[index];
}
bool isValid(int index) const
{
return c[index].isValid();
}
};
//=============================================================================
//
// predefined colorsets
//
//=============================================================================
static FColorCVar *cv_standard[] = {
&am_backcolor,
&am_yourcolor,
&am_wallcolor,
&am_tswallcolor,
&am_fdwallcolor,
&am_cdwallcolor,
&am_efwallcolor,
&am_thingcolor,
&am_thingcolor_item,
&am_thingcolor_citem,
&am_thingcolor_monster,
&am_thingcolor_ncmonster,
&am_thingcolor_friend,
&am_specialwallcolor,
&am_secretwallcolor,
&am_gridcolor,
&am_xhaircolor,
&am_notseencolor,
&am_lockedcolor,
&am_intralevelcolor,
&am_interlevelcolor,
&am_secretsectorcolor
};
static FColorCVar *cv_overlay[] = {
&am_backcolor, // this will not be used in overlay mode
&am_ovyourcolor,
&am_ovwallcolor,
&am_ovotherwallscolor,
&am_ovfdwallcolor,
&am_ovcdwallcolor,
&am_ovefwallcolor,
&am_ovthingcolor,
&am_ovthingcolor_item,
&am_ovthingcolor_citem,
&am_ovthingcolor_monster,
&am_ovthingcolor_ncmonster,
&am_ovthingcolor_friend,
&am_ovspecialwallcolor,
&am_ovsecretwallcolor,
&am_gridcolor, // this will not be used in overlay mode
&am_xhaircolor, // this will not be used in overlay mode
&am_ovunseencolor,
&am_ovlockedcolor,
&am_ovtelecolor,
&am_ovinterlevelcolor,
&am_ovsecretsectorcolor
};
CCMD(am_restorecolors)
{
for (unsigned i = 0; i < countof(cv_standard); i++)
{
cv_standard[i]->ResetToDefault();
}
for (unsigned i = 0; i < countof(cv_overlay); i++)
{
cv_overlay[i]->ResetToDefault();
}
}
#define NOT_USED 1,0,0 // use almost black as indicator for an unused color
static unsigned char DoomColors[]= {
0x00,0x00,0x00, // background
0xff,0xff,0xff, // yourcolor
0xfc,0x00,0x00, // wallcolor
0x80,0x80,0x80, // tswallcolor
0xbc,0x78,0x48, // fdwallcolor
0xfc,0xfc,0x00, // cdwallcolor
0xbc,0x78,0x48, // efwallcolor
0x74,0xfc,0x6c, // thingcolor
0x74,0xfc,0x6c, // thingcolor_item
0x74,0xfc,0x6c, // thingcolor_citem
0x74,0xfc,0x6c, // thingcolor_monster
0x74,0xfc,0x6c, // thingcolor_ncmonster
0x74,0xfc,0x6c, // thingcolor_friend
NOT_USED, // specialwallcolor
NOT_USED, // secretwallcolor
0x4c,0x4c,0x4c, // gridcolor
0x80,0x80,0x80, // xhaircolor
0x6c,0x6c,0x6c, // notseencolor
0xfc,0xfc,0x00, // lockedcolor
NOT_USED, // intrateleport
NOT_USED, // interteleport
NOT_USED, // secretsector
0x10,0x10,0x10, // almostbackground
};
static unsigned char StrifeColors[]= {
0x00,0x00,0x00, // background
239, 239, 0, // yourcolor
199, 195, 195, // wallcolor
119, 115, 115, // tswallcolor
55, 59, 91, // fdwallcolor
119, 115, 115, // cdwallcolor
55, 59, 91, // efwallcolor
187, 59, 0, // thingcolor
219, 171, 0, // thingcolor_item
219, 171, 0, // thingcolor_citem
0xfc,0x00,0x00, // thingcolor_monster
0xfc,0x00,0x00, // thingcolor_ncmonster
0xfc,0x00,0x00, // thingcolor_friend
NOT_USED, // specialwallcolor
NOT_USED, // secretwallcolor
0x4c,0x4c,0x4c, // gridcolor
0x80,0x80,0x80, // xhaircolor
0x6c,0x6c,0x6c, // notseencolor
119, 115, 115, // lockedcolor
NOT_USED, // intrateleport
NOT_USED, // interteleport
NOT_USED, // secretsector
0x10,0x10,0x10, // almostbackground
};
static unsigned char RavenColors[]= {
0x6c,0x54,0x40, // background
0xff,0xff,0xff, // yourcolor
75, 50, 16, // wallcolor
88, 93, 86, // tswallcolor
208, 176, 133, // fdwallcolor
103, 59, 31, // cdwallcolor
208, 176, 133, // efwallcolor
236, 236, 236, // thingcolor
236, 236, 236, // thingcolor_item
236, 236, 236, // thingcolor_citem
236, 236, 236, // thingcolor_monster
236, 236, 236, // thingcolor_ncmonster
236, 236, 236, // thingcolor_friend
NOT_USED, // specialwallcolor
NOT_USED, // secretwallcolor
75, 50, 16, // gridcolor
0x00,0x00,0x00, // xhaircolor
0x00,0x00,0x00, // notseencolor
103, 59, 31, // lockedcolor
NOT_USED, // intrateleport
NOT_USED, // interteleport
NOT_USED, // secretsector
0x10,0x10,0x10, // almostbackground
};
#undef NOT_USED
static AMColorset AMColors;
static AMColorset AMMod;
static AMColorset AMModOverlay;
//=============================================================================
//
//
//
//=============================================================================
void FMapInfoParser::ParseAMColors(bool overlay)
{
bool colorset = false;
AMColorset &cset = overlay? AMModOverlay : AMMod;
cset.setWhite();
cset.defined = true;
sc.MustGetToken('{');
while(sc.GetToken())
{
if (sc.TokenType == '}') return;
sc.TokenMustBe(TK_Identifier);
FString nextKey = sc.String;
sc.MustGetToken('=');
if (nextKey.CompareNoCase("base") == 0)
{
if (colorset) sc.ScriptError("'base' must be specified before the first color");
sc.MustGetToken(TK_StringConst);
if (sc.Compare("doom"))
{
cset.initFromColors(DoomColors, false);
}
else if (sc.Compare("raven"))
{
cset.initFromColors(RavenColors, true);
}
else if (sc.Compare("strife"))
{
cset.initFromColors(StrifeColors, false);
}
else
{
sc.ScriptError("Unknown value for 'base'. Must be 'Doom', 'Strife' or 'Raven'.");
}
}
else if (nextKey.CompareNoCase("showlocks") == 0)
{
if(sc.CheckToken(TK_False))
cset.displayLocks = false;
else
{
sc.MustGetToken(TK_True);
cset.displayLocks = true;
}
}
else
{
int i;
for (i = 0; ColorNames[i] != NULL; i++)
{
if (nextKey.CompareNoCase(ColorNames[i]) == 0)
{
sc.MustGetToken(TK_StringConst);
FString color = sc.String;
FString colorName = V_GetColorStringByName(color);
if(!colorName.IsEmpty()) color = colorName;
int colorval = V_GetColorFromString(NULL, color);
cset.c[i].FromRGB(RPART(colorval), GPART(colorval), BPART(colorval));
colorset = true;
break;
}
}
if (ColorNames[i]== NULL)
{
sc.ScriptError("Unknown key '%s'", nextKey.GetChars());
}
}
}
}
//=============================================================================
//
//
//
//=============================================================================
#define MAPBITS 12
#define MapDiv SafeDivScale12
#define MapMul MulScale12
#define MAPUNIT (1<<MAPBITS)
#define FRACTOMAPBITS (FRACBITS-MAPBITS)
// scale on entry
#define INITSCALEMTOF (.2*MAPUNIT)
// used by MTOF to scale from map-to-frame-buffer coords
static fixed_t scale_mtof = (fixed_t)INITSCALEMTOF;
// used by FTOM to scale from frame-buffer-to-map coords (=1/scale_mtof)
static fixed_t scale_ftom;
// translates between frame-buffer and map distances
inline fixed_t FTOM(fixed_t x)
{
return x * scale_ftom;
}
inline fixed_t MTOF(fixed_t x)
{
return MulScale24 (x, scale_mtof);
}
static int bigstate = 0;
static bool textured = 1; // internal toggle for texture mode
CUSTOM_CVAR(Bool, am_textured, false, CVAR_ARCHIVE)
{
textured |= self;
}
CVAR(Int, am_showsubsector, -1, 0);
// Disable the ML_DONTDRAW line flag if x% of all lines in a map are flagged with it
// (To counter annoying mappers who think they are smart by making the automap unusable)
bool am_showallenabled;
CUSTOM_CVAR (Int, am_showalllines, -1, 0) // This is a cheat so don't save it.
{
int flagged = 0;
int total = 0;
if (self > 0 && numlines > 0)
{
for(int i=0;i<numlines;i++)
{
line_t *line = &lines[i];
// disregard intra-sector lines
if (line->frontsector == line->backsector) continue;
// disregard control sectors for deep water
if (line->frontsector->e->FakeFloor.Sectors.Size() > 0) continue;
// disregard control sectors for 3D-floors
if (line->frontsector->e->XFloor.attached.Size() > 0) continue;
total++;
if (line->flags & ML_DONTDRAW) flagged++;
}
am_showallenabled = (flagged * 100 / total >= self);
}
else if (self == 0)
{
am_showallenabled = true;
}
else
{
am_showallenabled = false;
}
}
EXTERN_CVAR (Bool, sv_cheats)
CUSTOM_CVAR (Int, am_cheat, 0, 0)
{
// No automap cheat in net games when cheats are disabled!
if (netgame && !sv_cheats && self != 0)
{
self = 0;
}
}
#define AM_NUMMARKPOINTS 10
// player radius for automap checking
#define PLAYERRADIUS 16*MAPUNIT
// how much the automap moves window per tic in frame-buffer coordinates
// moves 140 pixels at 320x200 in 1 second
#define F_PANINC (140/TICRATE)
// how much zoom-in per tic
// goes to 2x in 1 second
#define M_ZOOMIN (1.02*MAPUNIT)
// how much zoom-out per tic
// pulls out to 0.5x in 1 second
#define M_ZOOMOUT (MAPUNIT/1.02)
// translates between frame-buffer and map coordinates
#define CXMTOF(x) (MTOF((x)-m_x)/* - f_x*/)
#define CYMTOF(y) (f_h - MTOF((y)-m_y)/* + f_y*/)
struct fpoint_t
{
int x, y;
};
struct fline_t
{
fpoint_t a, b;
};
struct mpoint_t
{
fixed_t x,y;
};
struct mline_t
{
mpoint_t a, b;
};
struct islope_t
{
fixed_t slp, islp;
};
//=============================================================================
//
// The vector graphics for the automap.
// A line drawing of the player pointing right,
// starting from the middle.
//
//=============================================================================
static TArray<mline_t> MapArrow;
static TArray<mline_t> CheatMapArrow;
static TArray<mline_t> CheatKey;
static TArray<mline_t> EasyKey;
#define R (MAPUNIT)
// [RH] Avoid lots of warnings without compiler-specific #pragmas
#define L(a,b,c,d) { {(fixed_t)((a)*R),(fixed_t)((b)*R)}, {(fixed_t)((c)*R),(fixed_t)((d)*R)} }
static mline_t triangle_guy[] = {
L (-.867,-.5, .867,-.5),
L (.867,-.5, 0,1),
L (0,1, -.867,-.5)
};
#define NUMTRIANGLEGUYLINES (sizeof(triangle_guy)/sizeof(mline_t))
static mline_t thintriangle_guy[] = {
L (-.5,-.7, 1,0),
L (1,0, -.5,.7),
L (-.5,.7, -.5,-.7)
};
#define NUMTHINTRIANGLEGUYLINES (sizeof(thintriangle_guy)/sizeof(mline_t))
static mline_t square_guy[] = {
L (0,1,1,0),
L (1,0,0,-1),
L (0,-1,-1,0),
L (-1,0,0,1)
};
#define NUMSQUAREGUYLINES (sizeof(square_guy)/sizeof(mline_t))
#undef R
//=============================================================================
//
//
//
//=============================================================================
static int grid = 0;
bool automapactive = false;
// location of window on screen
static int f_x;
static int f_y;
// size of window on screen
static int f_w;
static int f_h;
static int f_p; // [RH] # of bytes from start of a line to start of next
static int amclock;
static mpoint_t m_paninc; // how far the window pans each tic (map coords)
static fixed_t mtof_zoommul; // how far the window zooms in each tic (map coords)
static float am_zoomdir;
static fixed_t m_x, m_y; // LL x,y where the window is on the map (map coords)
static fixed_t m_x2, m_y2; // UR x,y where the window is on the map (map coords)
//
// width/height of window on map (map coords)
//
static fixed_t m_w;
static fixed_t m_h;
// based on level size
static fixed_t min_x, min_y, max_x, max_y;
static fixed_t max_w; // max_x-min_x,
static fixed_t max_h; // max_y-min_y
// based on player size
static fixed_t min_w;
static fixed_t min_h;
static fixed_t min_scale_mtof; // used to tell when to stop zooming out
static fixed_t max_scale_mtof; // used to tell when to stop zooming in
// old stuff for recovery later
static fixed_t old_m_w, old_m_h;
static fixed_t old_m_x, old_m_y;
// old location used by the Follower routine
static mpoint_t f_oldloc;
static FTextureID marknums[10]; // numbers used for marking by the automap
static mpoint_t markpoints[AM_NUMMARKPOINTS]; // where the points are
static int markpointnum = 0; // next point to be assigned
static FTextureID mapback; // the automap background
static fixed_t mapystart=0; // y-value for the start of the map bitmap...used in the parallax stuff.
static fixed_t mapxstart=0; //x-value for the bitmap.
static bool stopped = true;
static void AM_calcMinMaxMtoF();
static void DrawMarker (FTexture *tex, fixed_t x, fixed_t y, int yadjust,
INTBOOL flip, fixed_t xscale, fixed_t yscale, int translation, fixed_t alpha, DWORD fillcolor, FRenderStyle renderstyle);
void AM_rotatePoint (fixed_t *x, fixed_t *y);
void AM_rotate (fixed_t *x, fixed_t *y, angle_t an);
void AM_doFollowPlayer ();
//=============================================================================
//
// map functions
//
//=============================================================================
bool AM_addMark ();
bool AM_clearMarks ();
void AM_saveScaleAndLoc ();
void AM_restoreScaleAndLoc ();
void AM_minOutWindowScale ();
CVAR(Bool, am_followplayer, true, CVAR_ARCHIVE)
CCMD(am_togglefollow)
{
am_followplayer = !am_followplayer;
f_oldloc.x = FIXED_MAX;
Printf ("%s\n", GStrings(am_followplayer ? "AMSTR_FOLLOWON" : "AMSTR_FOLLOWOFF"));
}
CCMD(am_togglegrid)
{
grid = !grid;
Printf ("%s\n", GStrings(grid ? "AMSTR_GRIDON" : "AMSTR_GRIDOFF"));
}
CCMD(am_toggletexture)
{
if (am_textured && hasglnodes)
{
textured = !textured;
Printf ("%s\n", GStrings(textured ? "AMSTR_TEXON" : "AMSTR_TEXOFF"));
}
}
CCMD(am_setmark)
{
if (AM_addMark())
{
Printf ("%s %d\n", GStrings("AMSTR_MARKEDSPOT"), markpointnum);
}
}
CCMD(am_clearmarks)
{
if (AM_clearMarks())
{
Printf ("%s\n", GStrings("AMSTR_MARKSCLEARED"));
}
}
CCMD(am_gobig)
{
bigstate = !bigstate;
if (bigstate)
{
AM_saveScaleAndLoc();
AM_minOutWindowScale();
}
else
AM_restoreScaleAndLoc();
}
// Calculates the slope and slope according to the x-axis of a line
// segment in map coordinates (with the upright y-axis n' all) so
// that it can be used with the brain-dead drawing stuff.
// Ripped out for Heretic
/*
void AM_getIslope (mline_t *ml, islope_t *is)
{
int dx, dy;
dy = ml->a.y - ml->b.y;
dx = ml->b.x - ml->a.x;
if (!dy) is->islp = (dx<0?-MAXINT:MAXINT);
else is->islp = FixedDiv(dx, dy);
if (!dx) is->slp = (dy<0?-MAXINT:MAXINT);
else is->slp = FixedDiv(dy, dx);
}
*/
void AM_ParseArrow(TArray<mline_t> &Arrow, const char *lumpname)
{
const int R = ((8*PLAYERRADIUS)/7);
FScanner sc;
int lump = Wads.CheckNumForFullName(lumpname, true);
if (lump >= 0)
{
sc.OpenLumpNum(lump);
sc.SetCMode(true);
while (sc.GetToken())
{
mline_t line;
sc.TokenMustBe('(');
sc.MustGetFloat();
line.a.x = xs_RoundToInt(sc.Float*R);
sc.MustGetToken(',');
sc.MustGetFloat();
line.a.y = xs_RoundToInt(sc.Float*R);
sc.MustGetToken(')');
sc.MustGetToken(',');
sc.MustGetToken('(');
sc.MustGetFloat();
line.b.x = xs_RoundToInt(sc.Float*R);
sc.MustGetToken(',');
sc.MustGetFloat();
line.b.y = xs_RoundToInt(sc.Float*R);
sc.MustGetToken(')');
Arrow.Push(line);
}
}
}
void AM_StaticInit()
{
MapArrow.Clear();
CheatMapArrow.Clear();
CheatKey.Clear();
EasyKey.Clear();
if (gameinfo.mMapArrow.IsNotEmpty()) AM_ParseArrow(MapArrow, gameinfo.mMapArrow);
if (gameinfo.mCheatMapArrow.IsNotEmpty()) AM_ParseArrow(CheatMapArrow, gameinfo.mCheatMapArrow);
AM_ParseArrow(CheatKey, gameinfo.mCheatKey);
AM_ParseArrow(EasyKey, gameinfo.mEasyKey);
if (MapArrow.Size() == 0) I_FatalError("No automap arrow defined");
char namebuf[9];
for (int i = 0; i < 10; i++)
{
mysnprintf (namebuf, countof(namebuf), "AMMNUM%d", i);
marknums[i] = TexMan.CheckForTexture (namebuf, FTexture::TEX_MiscPatch);
}
markpointnum = 0;
mapback.SetInvalid();
}
//=============================================================================
//
// called by the coordinate drawer
//
//=============================================================================
void AM_GetPosition(fixed_t &x, fixed_t &y)
2006-04-11 16:27:41 +00:00
{
x = (m_x + m_w/2) << FRACTOMAPBITS;
y = (m_y + m_h/2) << FRACTOMAPBITS;
}
//=============================================================================
//
//
//
//=============================================================================
void AM_activateNewScale ()
{
m_x += m_w/2;
m_y += m_h/2;
m_w = FTOM(f_w);
m_h = FTOM(f_h);
m_x -= m_w/2;
m_y -= m_h/2;
m_x2 = m_x + m_w;
m_y2 = m_y + m_h;
}
//=============================================================================
//
//
//
//=============================================================================
void AM_saveScaleAndLoc ()
{
old_m_x = m_x;
old_m_y = m_y;
old_m_w = m_w;
old_m_h = m_h;
}
//=============================================================================
//
//
//
//=============================================================================
void AM_restoreScaleAndLoc ()
{
m_w = old_m_w;
m_h = old_m_h;
if (!am_followplayer)
{
m_x = old_m_x;
m_y = old_m_y;
}
else
{
m_x = (players[consoleplayer].camera->x >> FRACTOMAPBITS) - m_w/2;
m_y = (players[consoleplayer].camera->y >> FRACTOMAPBITS)- m_h/2;
}
m_x2 = m_x + m_w;
m_y2 = m_y + m_h;
// Change the scaling multipliers
scale_mtof = MapDiv(f_w<<MAPBITS, m_w);
scale_ftom = MapDiv(MAPUNIT, scale_mtof);
}
//=============================================================================
//
// adds a marker at the current location
//
//=============================================================================
bool AM_addMark ()
{
if (marknums[0].isValid())
{
markpoints[markpointnum].x = m_x + m_w/2;
markpoints[markpointnum].y = m_y + m_h/2;
markpointnum = (markpointnum + 1) % AM_NUMMARKPOINTS;
return true;
}
return false;
}
//=============================================================================
//
// Determines bounding box of all vertices,
// sets global variables controlling zoom range.
//
//=============================================================================
static void AM_findMinMaxBoundaries ()
{
min_x = min_y = FIXED_MAX;
max_x = max_y = FIXED_MIN;
for (int i = 0; i < numvertexes; i++)
{
if (vertexes[i].x < min_x)
min_x = vertexes[i].x;
else if (vertexes[i].x > max_x)
max_x = vertexes[i].x;
if (vertexes[i].y < min_y)
min_y = vertexes[i].y;
else if (vertexes[i].y > max_y)
max_y = vertexes[i].y;
}
max_w = (max_x >>= FRACTOMAPBITS) - (min_x >>= FRACTOMAPBITS);
max_h = (max_y >>= FRACTOMAPBITS) - (min_y >>= FRACTOMAPBITS);
min_w = 2*PLAYERRADIUS; // const? never changed?
min_h = 2*PLAYERRADIUS;
AM_calcMinMaxMtoF();
}
//=============================================================================
//
//
//
//=============================================================================
static void AM_calcMinMaxMtoF()
{
fixed_t a = MapDiv (SCREENWIDTH << MAPBITS, max_w);
fixed_t b = MapDiv (::ST_Y << MAPBITS, max_h);
min_scale_mtof = a < b ? a : b;
max_scale_mtof = MapDiv (SCREENHEIGHT << MAPBITS, 2*PLAYERRADIUS);
}
//=============================================================================
//
//
//
//=============================================================================
static void AM_ClipRotatedExtents (fixed_t pivotx, fixed_t pivoty)
{
if (am_rotate == 0 || (am_rotate == 2 && !viewactive))
{
if (m_x + m_w/2 > max_x)
m_x = max_x - m_w/2;
else if (m_x + m_w/2 < min_x)
m_x = min_x - m_w/2;
if (m_y + m_h/2 > max_y)
m_y = max_y - m_h/2;
else if (m_y + m_h/2 < min_y)
m_y = min_y - m_h/2;
}
else
{
#if 0
fixed_t rmin_x, rmin_y, rmax_x, rmax_y;
fixed_t xs[5], ys[5];
int i;
xs[0] = min_x; ys[0] = min_y;
xs[1] = max_x; ys[1] = min_y;
xs[2] = max_x; ys[2] = max_y;
xs[3] = min_x; ys[3] = max_y;
xs[4] = m_x + m_w/2; ys[4] = m_y + m_h/2;
rmin_x = rmin_y = FIXED_MAX;
rmax_x = rmax_y = FIXED_MIN;
for (i = 0; i < 5; ++i)
{
xs[i] -= pivotx;
ys[i] -= pivoty;
AM_rotate (&xs[i], &ys[i], ANG90 - players[consoleplayer].camera->angle);
if (i == 5)
break;
// xs[i] += pivotx;
// ys[i] += pivoty;
if (xs[i] < rmin_x) rmin_x = xs[i];
if (xs[i] > rmax_x) rmax_x = xs[i];
if (ys[i] < rmin_y) rmin_y = ys[i];
if (ys[i] > rmax_y) rmax_y = ys[i];
}
if (rmax_x < 0)
xs[4] = -rmax_x;
else if (rmin_x > 0)
xs[4] = -rmin_x;
// if (ys[4] > rmax_y)
// ys[4] = rmax_y;
// else if (ys[4] < rmin_y)
// ys[4] = rmin_y;
AM_rotate (&xs[4], &ys[4], ANG270 - players[consoleplayer].camera->angle);
m_x = xs[4] + pivotx - m_w/2;
m_y = ys[4] + pivoty - m_h/2;
#endif
}
m_x2 = m_x + m_w;
m_y2 = m_y + m_h;
}
//=============================================================================
//
//
//
//=============================================================================
static void AM_ScrollParchment (fixed_t dmapx, fixed_t dmapy)
{
mapxstart -= MulScale12 (dmapx, scale_mtof);
mapystart -= MulScale12 (dmapy, scale_mtof);
if (mapback.isValid())
{
FTexture *backtex = TexMan[mapback];
if (backtex != NULL)
{
int pwidth = backtex->GetWidth() << MAPBITS;
int pheight = backtex->GetHeight() << MAPBITS;
while(mapxstart > 0)
mapxstart -= pwidth;
while(mapxstart <= -pwidth)
mapxstart += pwidth;
while(mapystart > 0)
mapystart -= pheight;
while(mapystart <= -pheight)
mapystart += pheight;
}
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_changeWindowLoc ()
{
if (0 != (m_paninc.x | m_paninc.y))
{
am_followplayer = false;
f_oldloc.x = FIXED_MAX;
}
int oldmx = m_x, oldmy = m_y;
fixed_t incx, incy, oincx, oincy;
incx = m_paninc.x;
incy = m_paninc.y;
oincx = incx = Scale(m_paninc.x, SCREENWIDTH, 320);
oincy = incy = Scale(m_paninc.y, SCREENHEIGHT, 200);
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotate(&incx, &incy, players[consoleplayer].camera->angle - ANG90);
}
m_x += incx;
m_y += incy;
AM_ClipRotatedExtents (oldmx + m_w/2, oldmy + m_h/2);
AM_ScrollParchment (m_x != oldmx ? oincx : 0, m_y != oldmy ? -oincy : 0);
}
//=============================================================================
//
//
//
//=============================================================================
void AM_initVariables ()
{
int pnum;
automapactive = true;
// Reset AM buttons
Button_AM_PanLeft.Reset();
Button_AM_PanRight.Reset();
Button_AM_PanUp.Reset();
Button_AM_PanDown.Reset();
Button_AM_ZoomIn.Reset();
Button_AM_ZoomOut.Reset();
f_oldloc.x = FIXED_MAX;
amclock = 0;
m_paninc.x = m_paninc.y = 0;
mtof_zoommul = MAPUNIT;
m_w = FTOM(SCREENWIDTH);
m_h = FTOM(SCREENHEIGHT);
// find player to center on initially
if (!playeringame[pnum = consoleplayer])
for (pnum=0;pnum<MAXPLAYERS;pnum++)
if (playeringame[pnum])
break;
assert(pnum >= 0 && pnum < MAXPLAYERS);
m_x = (players[pnum].camera->x >> FRACTOMAPBITS) - m_w/2;
m_y = (players[pnum].camera->y >> FRACTOMAPBITS) - m_h/2;
AM_changeWindowLoc();
// for saving & restoring
old_m_x = m_x;
old_m_y = m_y;
old_m_w = m_w;
old_m_h = m_h;
}
//=============================================================================
//
//
//
//=============================================================================
static void AM_initColors (bool overlayed)
{
if (overlayed)
{
if (am_customcolors && AMModOverlay.defined)
{
AMColors = AMModOverlay;
}
else
{
AMColors.initFromCVars(cv_overlay);
}
}
else if (am_customcolors && AMMod.defined)
{
AMColors = AMMod;
}
else switch(am_colorset)
{
default:
/* Use the custom colors in the am_* cvars */
AMColors.initFromCVars(cv_standard);
break;
case 1: // Doom
// Use colors corresponding to the original Doom's
AMColors.initFromColors(DoomColors, false);
break;
case 2: // Strife
// Use colors corresponding to the original Strife's
AMColors.initFromColors(StrifeColors, false);
break;
case 3: // Raven
// Use colors corresponding to the original Raven's
AMColors.initFromColors(RavenColors, true);
break;
}
}
//=============================================================================
//
//
//
//=============================================================================
bool AM_clearMarks ()
{
for (int i = AM_NUMMARKPOINTS-1; i >= 0; i--)
markpoints[i].x = -1; // means empty
markpointnum = 0;
return marknums[0].isValid();
}
//=============================================================================
//
// called right after the level has been loaded
//
//=============================================================================
void AM_LevelInit ()
{
if (level.info->MapBackground.Len() == 0)
{
mapback = TexMan.CheckForTexture("AUTOPAGE", FTexture::TEX_MiscPatch);
}
else
{
mapback = TexMan.CheckForTexture(level.info->MapBackground, FTexture::TEX_MiscPatch);
}
AM_clearMarks();
AM_findMinMaxBoundaries();
scale_mtof = MapDiv(min_scale_mtof, (int) (0.7*MAPUNIT));
if (scale_mtof > max_scale_mtof)
scale_mtof = min_scale_mtof;
scale_ftom = MapDiv(MAPUNIT, scale_mtof);
am_showalllines.Callback();
}
//=============================================================================
//
//
//
//=============================================================================
void AM_Stop ()
{
automapactive = false;
stopped = true;
V_SetBorderNeedRefresh();
viewactive = true;
}
//=============================================================================
//
//
//
//=============================================================================
void AM_Start ()
{
if (!stopped) AM_Stop();
stopped = false;
AM_initVariables();
}
//=============================================================================
//
// set the window scale to the maximum size
//
//=============================================================================
void AM_minOutWindowScale ()
{
scale_mtof = min_scale_mtof;
scale_ftom = MapDiv(MAPUNIT, scale_mtof);
}
//=============================================================================
//
// set the window scale to the minimum size
//
//=============================================================================
void AM_maxOutWindowScale ()
{
scale_mtof = max_scale_mtof;
scale_ftom = MapDiv(MAPUNIT, scale_mtof);
}
//=============================================================================
//
// Called right after the resolution has changed
//
//=============================================================================
void AM_NewResolution()
{
fixed_t oldmin = min_scale_mtof;
if ( oldmin == 0 )
{
return; // [SP] Not in a game, exit!
}
AM_calcMinMaxMtoF();
scale_mtof = Scale(scale_mtof, min_scale_mtof, oldmin);
scale_ftom = MapDiv(MAPUNIT, scale_mtof);
if (scale_mtof < min_scale_mtof)
AM_minOutWindowScale();
else if (scale_mtof > max_scale_mtof)
AM_maxOutWindowScale();
f_w = screen->GetWidth();
f_h = ST_Y;
AM_activateNewScale();
}
//=============================================================================
//
//
//
//=============================================================================
CCMD (togglemap)
{
if (gameaction == ga_nothing)
{
gameaction = ga_togglemap;
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_ToggleMap ()
{
if (gamestate != GS_LEVEL)
return;
// Don't activate the automap if we're not allowed to use it.
if (dmflags2 & DF2_NO_AUTOMAP)
return;
ST_SetNeedRefresh();
if (!automapactive)
{
AM_Start ();
viewactive = (am_overlay != 0.f);
}
else
{
if (am_overlay==1 && viewactive)
{
viewactive = false;
ST_SetNeedRefresh();
}
else
{
AM_Stop ();
}
}
}
//=============================================================================
//
// Handle events (user inputs) in automap mode
//
//=============================================================================
bool AM_Responder (event_t *ev, bool last)
{
if (automapactive && (ev->type == EV_KeyDown || ev->type == EV_KeyUp))
{
if (am_followplayer)
{
// check for am_pan* and ignore in follow mode
const char *defbind = AutomapBindings.GetBind(ev->data1);
if (!strnicmp(defbind, "+am_pan", 7)) return false;
}
bool res = C_DoKey(ev, &AutomapBindings, NULL);
if (res && ev->type == EV_KeyUp && !last)
{
// If this is a release event we also need to check if it released a button in the main Bindings
// so that that button does not get stuck.
const char *defbind = Bindings.GetBind(ev->data1);
return (defbind[0] != '+'); // Let G_Responder handle button releases
}
return res;
}
return false;
}
//=============================================================================
//
// Zooming
//
//=============================================================================
void AM_changeWindowScale ()
{
int mtof_zoommul;
if (am_zoomdir > 0)
{
mtof_zoommul = int(M_ZOOMIN * am_zoomdir);
}
else if (am_zoomdir < 0)
{
mtof_zoommul = int(M_ZOOMOUT / -am_zoomdir);
}
else if (Button_AM_ZoomIn.bDown)
{
mtof_zoommul = int(M_ZOOMIN);
}
else if (Button_AM_ZoomOut.bDown)
{
mtof_zoommul = int(M_ZOOMOUT);
}
else
{
mtof_zoommul = MAPUNIT;
}
am_zoomdir = 0;
// Change the scaling multipliers
scale_mtof = MapMul(scale_mtof, mtof_zoommul);
scale_ftom = MapDiv(MAPUNIT, scale_mtof);
if (scale_mtof < min_scale_mtof)
AM_minOutWindowScale();
else if (scale_mtof > max_scale_mtof)
AM_maxOutWindowScale();
}
CCMD(am_zoom)
{
if (argv.argc() >= 2)
{
am_zoomdir = (float)atof(argv[1]);
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_doFollowPlayer ()
{
fixed_t sx, sy;
if (players[consoleplayer].camera != NULL &&
(f_oldloc.x != players[consoleplayer].camera->x ||
f_oldloc.y != players[consoleplayer].camera->y))
{
m_x = (players[consoleplayer].camera->x >> FRACTOMAPBITS) - m_w/2;
m_y = (players[consoleplayer].camera->y >> FRACTOMAPBITS) - m_h/2;
m_x2 = m_x + m_w;
m_y2 = m_y + m_h;
// do the parallax parchment scrolling.
sx = (players[consoleplayer].camera->x - f_oldloc.x) >> FRACTOMAPBITS;
sy = (f_oldloc.y - players[consoleplayer].camera->y) >> FRACTOMAPBITS;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotate (&sx, &sy, players[consoleplayer].camera->angle - ANG90);
}
AM_ScrollParchment (sx, sy);
f_oldloc.x = players[consoleplayer].camera->x;
f_oldloc.y = players[consoleplayer].camera->y;
}
}
//=============================================================================
//
// Updates on Game Tick
//
//=============================================================================
void AM_Ticker ()
{
if (!automapactive)
return;
amclock++;
if (am_followplayer)
{
AM_doFollowPlayer();
}
else
{
m_paninc.x = m_paninc.y = 0;
if (Button_AM_PanLeft.bDown) m_paninc.x -= FTOM(F_PANINC);
if (Button_AM_PanRight.bDown) m_paninc.x += FTOM(F_PANINC);
if (Button_AM_PanUp.bDown) m_paninc.y += FTOM(F_PANINC);
if (Button_AM_PanDown.bDown) m_paninc.y -= FTOM(F_PANINC);
}
// Change the zoom if necessary
if (Button_AM_ZoomIn.bDown || Button_AM_ZoomOut.bDown || am_zoomdir != 0)
AM_changeWindowScale();
// Change x,y location
//if (m_paninc.x || m_paninc.y)
AM_changeWindowLoc();
}
//=============================================================================
//
// Clear automap frame buffer.
//
//=============================================================================
void AM_clearFB (const AMColor &color)
{
bool drawback = mapback.isValid() && am_drawmapback != 0;
if (am_drawmapback == 2)
{
// only draw background when using a mod defined custom color set or Raven colors, if am_drawmapback is 2.
if (!am_customcolors || !AMMod.defined)
{
drawback &= (am_colorset == 3);
}
}
if (!drawback)
{
screen->Clear (0, 0, f_w, f_h, color.Index, color.RGB);
}
else
{
FTexture *backtex = TexMan[mapback];
if (backtex != NULL)
{
int pwidth = backtex->GetWidth();
int pheight = backtex->GetHeight();
int x, y;
//blit the automap background to the screen.
for (y = mapystart >> MAPBITS; y < f_h; y += pheight)
{
for (x = mapxstart >> MAPBITS; x < f_w; x += pwidth)
{
screen->DrawTexture (backtex, x, y, DTA_ClipBottom, f_h, DTA_TopOffset, 0, DTA_LeftOffset, 0, TAG_DONE);
}
}
}
}
}
//=============================================================================
//
// Automap clipping of lines.
//
// Based on Cohen-Sutherland clipping algorithm but with a slightly
// faster reject and precalculated slopes. If the speed is needed,
// use a hash algorithm to handle the common cases.
//
//=============================================================================
bool AM_clipMline (mline_t *ml, fline_t *fl)
{
enum {
LEFT =1,
RIGHT =2,
BOTTOM =4,
TOP =8
};
register int outcode1 = 0;
register int outcode2 = 0;
register int outside;
fpoint_t tmp = { 0, 0 };
int dx;
int dy;
#define DOOUTCODE(oc, mx, my) \
(oc) = 0; \
if ((my) < 0) (oc) |= TOP; \
else if ((my) >= f_h) (oc) |= BOTTOM; \
if ((mx) < 0) (oc) |= LEFT; \
else if ((mx) >= f_w) (oc) |= RIGHT;
// do trivial rejects and outcodes
if (ml->a.y > m_y2)
outcode1 = TOP;
else if (ml->a.y < m_y)
outcode1 = BOTTOM;
if (ml->b.y > m_y2)
outcode2 = TOP;
else if (ml->b.y < m_y)
outcode2 = BOTTOM;
if (outcode1 & outcode2)
return false; // trivially outside
if (ml->a.x < m_x)
outcode1 |= LEFT;
else if (ml->a.x > m_x2)
outcode1 |= RIGHT;
if (ml->b.x < m_x)
outcode2 |= LEFT;
else if (ml->b.x > m_x2)
outcode2 |= RIGHT;
if (outcode1 & outcode2)
return false; // trivially outside
// transform to frame-buffer coordinates.
fl->a.x = CXMTOF(ml->a.x);
fl->a.y = CYMTOF(ml->a.y);
fl->b.x = CXMTOF(ml->b.x);
fl->b.y = CYMTOF(ml->b.y);
DOOUTCODE(outcode1, fl->a.x, fl->a.y);
DOOUTCODE(outcode2, fl->b.x, fl->b.y);
if (outcode1 & outcode2)
return false;
while (outcode1 | outcode2) {
// may be partially inside box
// find an outside point
if (outcode1)
outside = outcode1;
else
outside = outcode2;
// clip to each side
if (outside & TOP)
{
dy = fl->a.y - fl->b.y;
dx = fl->b.x - fl->a.x;
tmp.x = fl->a.x + Scale(dx, fl->a.y, dy);
tmp.y = 0;
}
else if (outside & BOTTOM)
{
dy = fl->a.y - fl->b.y;
dx = fl->b.x - fl->a.x;
tmp.x = fl->a.x + Scale(dx, fl->a.y - f_h, dy);
tmp.y = f_h-1;
}
else if (outside & RIGHT)
{
dy = fl->b.y - fl->a.y;
dx = fl->b.x - fl->a.x;
tmp.y = fl->a.y + Scale(dy, f_w-1 - fl->a.x, dx);
tmp.x = f_w-1;
}
else if (outside & LEFT)
{
dy = fl->b.y - fl->a.y;
dx = fl->b.x - fl->a.x;
tmp.y = fl->a.y + Scale(dy, -fl->a.x, dx);
tmp.x = 0;
}
if (outside == outcode1)
{
fl->a = tmp;
DOOUTCODE(outcode1, fl->a.x, fl->a.y);
}
else
{
fl->b = tmp;
DOOUTCODE(outcode2, fl->b.x, fl->b.y);
}
if (outcode1 & outcode2)
return false; // trivially outside
}
return true;
}
#undef DOOUTCODE
//=============================================================================
//
// Clip lines, draw visible parts of lines.
//
//=============================================================================
void AM_drawMline (mline_t *ml, const AMColor &color)
{
fline_t fl;
if (AM_clipMline (ml, &fl))
{
screen->DrawLine (f_x + fl.a.x, f_y + fl.a.y, f_x + fl.b.x, f_y + fl.b.y, color.Index, color.RGB);
}
}
inline void AM_drawMline (mline_t *ml, int colorindex)
{
AM_drawMline(ml, AMColors[colorindex]);
}
//=============================================================================
//
// Draws flat (floor/ceiling tile) aligned grid lines.
//
//=============================================================================
void AM_drawGrid (int color)
{
fixed_t x, y;
fixed_t start, end;
mline_t ml;
fixed_t minlen, extx, exty;
fixed_t minx, miny;
// [RH] Calculate a minimum for how long the grid lines should be so that
// they cover the screen at any rotation.
minlen = (fixed_t)sqrt ((double)m_w*(double)m_w + (double)m_h*(double)m_h);
extx = (minlen - m_w) / 2;
exty = (minlen - m_h) / 2;
minx = m_x;
miny = m_y;
// Figure out start of vertical gridlines
start = minx - extx;
if ((start-bmaporgx)%(MAPBLOCKUNITS<<MAPBITS))
start += (MAPBLOCKUNITS<<MAPBITS)
- ((start-bmaporgx)%(MAPBLOCKUNITS<<MAPBITS));
end = minx + minlen - extx;
// draw vertical gridlines
for (x = start; x < end; x += (MAPBLOCKUNITS<<MAPBITS))
{
ml.a.x = x;
ml.b.x = x;
ml.a.y = miny - exty;
ml.b.y = ml.a.y + minlen;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&ml.a.x, &ml.a.y);
AM_rotatePoint (&ml.b.x, &ml.b.y);
}
AM_drawMline(&ml, color);
}
// Figure out start of horizontal gridlines
start = miny - exty;
if ((start-bmaporgy)%(MAPBLOCKUNITS<<MAPBITS))
start += (MAPBLOCKUNITS<<MAPBITS)
- ((start-bmaporgy)%(MAPBLOCKUNITS<<MAPBITS));
end = miny + minlen - exty;
// draw horizontal gridlines
for (y=start; y<end; y+=(MAPBLOCKUNITS<<MAPBITS))
{
ml.a.x = minx - extx;
ml.b.x = ml.a.x + minlen;
ml.a.y = y;
ml.b.y = y;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&ml.a.x, &ml.a.y);
AM_rotatePoint (&ml.b.x, &ml.b.y);
}
AM_drawMline (&ml, color);
}
}
//=============================================================================
//
// AM_drawSubsectors
//
//=============================================================================
void AM_drawSubsectors()
{
static TArray<FVector2> points;
float scale = float(scale_mtof);
angle_t rotation;
sector_t tempsec;
int floorlight, ceilinglight;
fixed_t scalex, scaley;
double originx, originy;
FDynamicColormap *colormap;
mpoint_t originpt;
for (int i = 0; i < numsubsectors; ++i)
{
if (subsectors[i].flags & SSECF_POLYORG)
{
continue;
}
if ((!(subsectors[i].flags & SSECF_DRAWN) || (subsectors[i].render_sector->MoreFlags & SECF_HIDDEN)) && am_cheat == 0)
{
continue;
}
// Fill the points array from the subsector.
points.Resize(subsectors[i].numlines);
for (DWORD j = 0; j < subsectors[i].numlines; ++j)
{
mpoint_t pt = { subsectors[i].firstline[j].v1->x >> FRACTOMAPBITS,
subsectors[i].firstline[j].v1->y >> FRACTOMAPBITS };
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint(&pt.x, &pt.y);
}
points[j].X = f_x + ((pt.x - m_x) * scale / float(1 << 24));
points[j].Y = f_y + (f_h - (pt.y - m_y) * scale / float(1 << 24));
}
// For lighting and texture determination
sector_t *sec = Renderer->FakeFlat (subsectors[i].render_sector, &tempsec, &floorlight, &ceilinglight, false);
// Find texture origin.
originpt.x = -sec->GetXOffset(sector_t::floor) >> FRACTOMAPBITS;
originpt.y = sec->GetYOffset(sector_t::floor) >> FRACTOMAPBITS;
rotation = 0 - sec->GetAngle(sector_t::floor);
// Coloring for the polygon
colormap = sec->ColorMap;
FTextureID maptex = sec->GetTexture(sector_t::floor);
scalex = sec->GetXScale(sector_t::floor);
scaley = sec->GetYScale(sector_t::floor);
if (sec->e->XFloor.ffloors.Size())
{
secplane_t *floorplane = &sec->floorplane;
// Look for the highest floor below the camera viewpoint.
// Check the center of the subsector's sector. Do not check each
// subsector separately because that might result in different planes for
// different subsectors of the same sector which is not wanted here.
// (Make the comparison in floating point to avoid overflows and improve performance.)
double secx;
double secy;
double seczb, seczt;
double cmpz = FIXED2DBL(viewz);
if (players[consoleplayer].camera && sec == players[consoleplayer].camera->Sector)
{
// For the actual camera sector use the current viewpoint as reference.
secx = FIXED2DBL(viewx);
secy = FIXED2DBL(viewy);
}
else
{
secx = FIXED2DBL(sec->soundorg[0]);
secy = FIXED2DBL(sec->soundorg[1]);
}
seczb = floorplane->ZatPoint(secx, secy);
seczt = sec->ceilingplane.ZatPoint(secx, secy);
for (unsigned int i = 0; i < sec->e->XFloor.ffloors.Size(); ++i)
{
F3DFloor *rover = sec->e->XFloor.ffloors[i];
if (!(rover->flags & FF_EXISTS)) continue;
if (rover->flags & FF_FOG) continue;
if (!(rover->flags & FF_RENDERPLANES)) continue;
if (rover->alpha == 0) continue;
double roverz = rover->top.plane->ZatPoint(secx, secy);
// Ignore 3D floors that are above or below the sector itself:
// they are hidden. Since 3D floors are sorted top to bottom,
// if we get below the sector floor, we can stop.
if (roverz > seczt) continue;
if (roverz < seczb) break;
if (roverz < cmpz)
{
maptex = *(rover->top.texture);
floorplane = rover->top.plane;
sector_t *model = rover->top.model;
int selector = (rover->flags & FF_INVERTPLANES) ? sector_t::floor : sector_t::ceiling;
rotation = 0 - model->GetAngle(selector);
scalex = model->GetXScale(selector);
scaley = model->GetYScale(selector);
originpt.x = -model->GetXOffset(selector) >> FRACTOMAPBITS;
originpt.y = model->GetYOffset(selector) >> FRACTOMAPBITS;
break;
}
}
lightlist_t *light = P_GetPlaneLight(sec, floorplane, false);
floorlight = *light->p_lightlevel;
colormap = light->extra_colormap;
}
if (maptex == skyflatnum)
{
continue;
}
// Apply the floor's rotation to the texture origin.
if (rotation != 0)
{
AM_rotate(&originpt.x, &originpt.y, rotation);
}
// Apply the automap's rotation to the texture origin.
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
rotation += ANG90 - players[consoleplayer].camera->angle;
AM_rotatePoint(&originpt.x, &originpt.y);
}
originx = f_x + ((originpt.x - m_x) * scale / float(1 << 24));
originy = f_y + (f_h - (originpt.y - m_y) * scale / float(1 << 24));
// If this subsector has not actually been seen yet (because you are cheating
// to see it on the map), tint and desaturate it.
if (!(subsectors[i].flags & SSECF_DRAWN))
{
colormap = GetSpecialLights(
MAKERGB(
(colormap->Color.r + 255) / 2,
(colormap->Color.g + 200) / 2,
(colormap->Color.b + 160) / 2),
colormap->Fade,
255 - (255 - colormap->Desaturate) / 4);
floorlight = (floorlight + 200*15) / 16;
}
// Draw the polygon.
FTexture *pic = TexMan(maptex);
if (pic != NULL && pic->UseType != FTexture::TEX_Null)
{
screen->FillSimplePoly(TexMan(maptex),
&points[0], points.Size(),
originx, originy,
scale / (FIXED2DBL(scalex) * float(1 << MAPBITS)),
scale / (FIXED2DBL(scaley) * float(1 << MAPBITS)),
rotation,
colormap,
floorlight
);
}
}
}
//=============================================================================
//
//
//
//=============================================================================
static bool AM_CheckSecret(line_t *line)
{
if (AMColors.isValid(AMColors.SecretSectorColor))
{
if (line->frontsector != NULL)
{
if (line->frontsector->secretsector)
{
if (am_map_secrets!=0 && !(line->frontsector->special&SECRET_MASK)) return true;
if (am_map_secrets==2 && !(line->flags & ML_SECRET)) return true;
}
}
if (line->backsector != NULL)
{
if (line->backsector->secretsector)
{
if (am_map_secrets!=0 && !(line->backsector->special&SECRET_MASK)) return true;
if (am_map_secrets==2 && !(line->flags & ML_SECRET)) return true;
}
}
}
return false;
}
//=============================================================================
//
// Polyobject debug stuff
//
//=============================================================================
void AM_drawSeg(seg_t *seg, const AMColor &color)
{
mline_t l;
l.a.x = seg->v1->x >> FRACTOMAPBITS;
l.a.y = seg->v1->y >> FRACTOMAPBITS;
l.b.x = seg->v2->x >> FRACTOMAPBITS;
l.b.y = seg->v2->y >> FRACTOMAPBITS;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&l.a.x, &l.a.y);
AM_rotatePoint (&l.b.x, &l.b.y);
}
AM_drawMline(&l, color);
}
void AM_drawPolySeg(FPolySeg *seg, const AMColor &color)
{
mline_t l;
l.a.x = seg->v1.x >> FRACTOMAPBITS;
l.a.y = seg->v1.y >> FRACTOMAPBITS;
l.b.x = seg->v2.x >> FRACTOMAPBITS;
l.b.y = seg->v2.y >> FRACTOMAPBITS;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&l.a.x, &l.a.y);
AM_rotatePoint (&l.b.x, &l.b.y);
}
AM_drawMline(&l, color);
}
void AM_showSS()
{
if (am_showsubsector >= 0 && am_showsubsector < numsubsectors)
{
AMColor yellow;
yellow.FromRGB(255,255,0);
AMColor red;
red.FromRGB(255,0,0);
subsector_t *sub = &subsectors[am_showsubsector];
for (unsigned int i = 0; i < sub->numlines; i++)
{
AM_drawSeg(sub->firstline + i, yellow);
}
PO_LinkToSubsectors();
for (int i = 0; i <po_NumPolyobjs; i++)
{
FPolyObj *po = &polyobjs[i];
FPolyNode *pnode = po->subsectorlinks;
while (pnode != NULL)
{
if (pnode->subsector == sub)
{
for (unsigned j = 0; j < pnode->segs.Size(); j++)
{
AM_drawPolySeg(&pnode->segs[j], red);
}
}
pnode = pnode->snext;
}
}
}
}
//=============================================================================
//
// Determines if a 3D floor boundary should be drawn
//
//=============================================================================
bool AM_Check3DFloors(line_t *line)
{
TArray<F3DFloor*> &ff_front = line->frontsector->e->XFloor.ffloors;
TArray<F3DFloor*> &ff_back = line->backsector->e->XFloor.ffloors;
// No 3D floors so there's no boundary
if (ff_back.Size() == 0 && ff_front.Size() == 0) return false;
int realfrontcount = 0;
int realbackcount = 0;
for(unsigned i=0;i<ff_front.Size();i++)
{
F3DFloor *rover = ff_front[i];
if (!(rover->flags & FF_EXISTS)) continue;
if (rover->alpha == 0) continue;
realfrontcount++;
}
for(unsigned i=0;i<ff_back.Size();i++)
{
F3DFloor *rover = ff_back[i];
if (!(rover->flags & FF_EXISTS)) continue;
if (rover->alpha == 0) continue;
realbackcount++;
}
// if the amount of 3D floors does not match there is a boundary
if (realfrontcount != realbackcount) return true;
for(unsigned i=0;i<ff_front.Size();i++)
{
F3DFloor *rover = ff_front[i];
if (!(rover->flags & FF_EXISTS)) continue;
if (rover->alpha == 0) continue;
bool found = false;
for(unsigned j=0;j<ff_back.Size();j++)
{
F3DFloor *rover2 = ff_back[j];
if (!(rover2->flags & FF_EXISTS)) continue;
if (rover2->alpha == 0) continue;
if (rover->model == rover2->model && rover->flags == rover2->flags)
{
found = true;
break;
}
}
// At least one 3D floor in the front sector didn't have a match in the back sector so there is a boundary.
if (!found) return true;
}
// All 3D floors could be matched so let's not draw a boundary.
return false;
}
// [TP] Check whether a sector can trigger a special that satisfies the provided function.
// If found, specialptr and argsptr will be filled by the special and the arguments
// If needUseActivated is true, the special must be activated by use.
bool AM_checkSectorActions (sector_t *sector, bool (*function)(int, int *), int *specialptr, int **argsptr, bool needUseActivated)
{
for (ASectorAction* action = sector->SecActTarget; action; action = barrier_cast<ASectorAction *>(action->tracer))
{
if ((action->IsActivatedByUse() || false == needUseActivated)
&& (*function)(action->special, action->args)
&& action->CanTrigger (players[consoleplayer].mo))
{
*specialptr = action->special;
*argsptr = action->args;
return true;
}
}
return false;
}
// [TP] Check whether there's a boundary on the provided line for a special that satisfies the provided function.
// It's a boundary if the line can activate the special or the line's bordering sectors can activate it.
// If found, specialptr and argsptr will be filled with special and args if given.
bool AM_checkSpecialBoundary (line_t &line, bool (*function)(int, int*), int *specialptr = NULL, int **argsptr = NULL)
{
if (specialptr == NULL)
{
static int sink;
specialptr = &sink;
}
if (argsptr == NULL)
{
static int* sink;
argsptr = &sink;
}
// Check if the line special qualifies for this
if ((*function)(line.special, line.args) && (line.activation & SPAC_PlayerActivate))
{
*specialptr = line.special;
*argsptr = line.args;
return true;
}
// Check sector actions in the line's front sector -- the action has to be use-activated in order to
// show up if this is a one-sided line, because the player cannot trigger sector actions by crossing
// a one-sided line (since that's impossible, duh).
if (AM_checkSectorActions(line.frontsector, function, specialptr, argsptr, line.backsector == NULL))
return true;
// If it has a back sector, check sector actions in that.
return (line.backsector && AM_checkSectorActions(line.backsector, function, specialptr, argsptr, false));
}
bool AM_isTeleportSpecial (int special, int*)
{
return (special == Teleport ||
special == Teleport_NoFog ||
special == Teleport_ZombieChanger ||
special == Teleport_Line);
}
bool AM_isTeleportBoundary (line_t& line)
{
return AM_checkSpecialBoundary(line, &AM_isTeleportSpecial);
}
bool AM_isExitSpecial (int special, int*)
{
return (special == Teleport_NewMap ||
special == Teleport_EndGame ||
special == Exit_Normal ||
special == Exit_Secret);
}
bool AM_isExitBoundary (line_t& line)
{
return AM_checkSpecialBoundary(line, &AM_isExitSpecial);
}
bool AM_isTriggerSpecial (int special, int*)
{
return special != 0
&& special != Door_Open
&& special != Door_Close
&& special != Door_CloseWaitOpen
&& special != Door_Raise
&& special != Door_Animated
&& special != Generic_Door;
}
bool AM_isTriggerBoundary (line_t& line)
{
return AM_checkSpecialBoundary(line, &AM_isTriggerSpecial);
}
bool AM_isLockSpecial (int special, int* args)
{
return special == Door_LockedRaise
|| special == ACS_LockedExecute
|| special == ACS_LockedExecuteDoor
|| (special == Door_Animated && args[3] != 0)
|| (special == Generic_Door && args[4] != 0)
|| (special == FS_Execute && args[2] != 0);
}
bool AM_isLockBoundary (line_t &line, int *lockptr = NULL)
{
if (lockptr == NULL)
{
static int sink;
lockptr = &sink;
}
if (line.locknumber)
{
*lockptr = line.locknumber;
return true;
}
int special;
int *args;
bool result = AM_checkSpecialBoundary(line, &AM_isLockSpecial, &special, &args);
if (result)
{
switch (special)
{
case FS_Execute:
*lockptr = args[2];
break;
case Door_Animated:
case Door_LockedRaise:
*lockptr = args[3];
break;
default:
*lockptr = args[4];
break;
}
}
return result;
}
//=============================================================================
//
// Determines visible lines, draws them.
// This is LineDef based, not LineSeg based.
//
//=============================================================================
void AM_drawWalls (bool allmap)
{
int i;
static mline_t l;
int lock, color;
for (i = 0; i < numlines; i++)
{
l.a.x = lines[i].v1->x >> FRACTOMAPBITS;
l.a.y = lines[i].v1->y >> FRACTOMAPBITS;
l.b.x = lines[i].v2->x >> FRACTOMAPBITS;
l.b.y = lines[i].v2->y >> FRACTOMAPBITS;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&l.a.x, &l.a.y);
AM_rotatePoint (&l.b.x, &l.b.y);
}
if (am_cheat != 0 || (lines[i].flags & ML_MAPPED))
{
if ((lines[i].flags & ML_DONTDRAW) && (am_cheat == 0 || am_cheat >= 4))
{
if (!am_showallenabled || CheckCheatmode(false))
{
continue;
}
}
2006-04-11 16:27:41 +00:00
if (AM_CheckSecret(&lines[i]))
{
// map secret sectors like Boom
AM_drawMline(&l, AMColors.SecretSectorColor);
}
else if (lines[i].flags & ML_SECRET)
{ // secret door
if (am_cheat != 0 && lines[i].backsector != NULL)
AM_drawMline(&l, AMColors.SecretWallColor);
else
AM_drawMline(&l, AMColors.WallColor);
}
else if (AM_isTeleportBoundary(lines[i]) && AMColors.isValid(AMColors.IntraTeleportColor))
{ // intra-level teleporters
AM_drawMline(&l, AMColors.IntraTeleportColor);
}
else if (AM_isExitBoundary(lines[i]) && AMColors.isValid(AMColors.InterTeleportColor))
{ // inter-level/game-ending teleporters
AM_drawMline(&l, AMColors.InterTeleportColor);
}
else if (AM_isLockBoundary(lines[i], &lock))
{
if (AMColors.displayLocks)
{
color = P_GetMapColorForLock(lock);
AMColor c;
if (color >= 0) c.FromRGB(RPART(color), GPART(color), BPART(color));
else c = AMColors[AMColors.LockedColor];
AM_drawMline (&l, c);
}
else
{
AM_drawMline (&l, AMColors.LockedColor); // locked special
}
}
else if (am_showtriggerlines
&& AMColors.isValid(AMColors.SpecialWallColor)
&& AM_isTriggerBoundary(lines[i]))
{
AM_drawMline(&l, AMColors.SpecialWallColor); // wall with special non-door action the player can do
}
else if (lines[i].backsector == NULL)
{
AM_drawMline(&l, AMColors.WallColor); // one-sided wall
}
else if (lines[i].backsector->floorplane
!= lines[i].frontsector->floorplane)
{
AM_drawMline(&l, AMColors.FDWallColor); // floor level change
}
else if (lines[i].backsector->ceilingplane
!= lines[i].frontsector->ceilingplane)
{
AM_drawMline(&l, AMColors.CDWallColor); // ceiling level change
}
else if (AM_Check3DFloors(&lines[i]))
{
AM_drawMline(&l, AMColors.EFWallColor); // Extra floor border
}
else if (am_cheat > 0 && am_cheat < 4)
{
AM_drawMline(&l, AMColors.TSWallColor);
}
}
else if (allmap)
{
if ((lines[i].flags & ML_DONTDRAW) && (am_cheat == 0 || am_cheat >= 4))
{
if (!am_showallenabled || CheckCheatmode(false))
{
continue;
}
}
AM_drawMline(&l, AMColors.NotSeenColor);
}
}
}
//=============================================================================
//
// Rotation in 2D.
// Used to rotate player arrow line character.
//
//=============================================================================
void AM_rotate(fixed_t *xp, fixed_t *yp, angle_t a)
{
static angle_t angle_saved = 0;
static double sinrot = 0;
static double cosrot = 1;
if (angle_saved != a)
{
angle_saved = a;
double rot = (double)a / (double)(1u << 31) * (double)M_PI;
sinrot = sin(rot);
cosrot = cos(rot);
}
double x = FIXED2FLOAT(*xp);
double y = FIXED2FLOAT(*yp);
double tmpx = (x * cosrot) - (y * sinrot);
y = (x * sinrot) + (y * cosrot);
x = tmpx;
*xp = FLOAT2FIXED(x);
*yp = FLOAT2FIXED(y);
}
//=============================================================================
//
//
//
//=============================================================================
void AM_rotatePoint (fixed_t *x, fixed_t *y)
{
fixed_t pivotx = m_x + m_w/2;
fixed_t pivoty = m_y + m_h/2;
*x -= pivotx;
*y -= pivoty;
AM_rotate (x, y, ANG90 - players[consoleplayer].camera->angle);
*x += pivotx;
*y += pivoty;
}
//=============================================================================
//
//
//
//=============================================================================
void
AM_drawLineCharacter
( const mline_t *lineguy,
int lineguylines,
fixed_t scale,
angle_t angle,
const AMColor &color,
fixed_t x,
fixed_t y )
{
int i;
mline_t l;
for (i=0;i<lineguylines;i++) {
l.a.x = lineguy[i].a.x;
l.a.y = lineguy[i].a.y;
if (scale) {
l.a.x = MapMul(scale, l.a.x);
l.a.y = MapMul(scale, l.a.y);
}
if (angle)
AM_rotate(&l.a.x, &l.a.y, angle);
l.a.x += x;
l.a.y += y;
l.b.x = lineguy[i].b.x;
l.b.y = lineguy[i].b.y;
if (scale) {
l.b.x = MapMul(scale, l.b.x);
l.b.y = MapMul(scale, l.b.y);
}
if (angle)
AM_rotate(&l.b.x, &l.b.y, angle);
l.b.x += x;
l.b.y += y;
AM_drawMline(&l, color);
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_drawPlayers ()
{
if (am_cheat >= 2 && am_cheat != 4 && am_showthingsprites > 0)
{
// Player sprites are drawn with the others
return;
}
mpoint_t pt;
angle_t angle;
int i;
if (!multiplayer)
{
mline_t *arrow;
int numarrowlines;
pt.x = players[consoleplayer].camera->x >> FRACTOMAPBITS;
pt.y = players[consoleplayer].camera->y >> FRACTOMAPBITS;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
angle = ANG90;
AM_rotatePoint (&pt.x, &pt.y);
}
else
{
angle = players[consoleplayer].camera->angle;
}
if (am_cheat != 0 && CheatMapArrow.Size() > 0)
{
arrow = &CheatMapArrow[0];
numarrowlines = CheatMapArrow.Size();
}
else
{
arrow = &MapArrow[0];
numarrowlines = MapArrow.Size();
}
AM_drawLineCharacter(arrow, numarrowlines, 0, angle, AMColors[AMColors.YourColor], pt.x, pt.y);
return;
}
for (i = 0; i < MAXPLAYERS; i++)
{
player_t *p = &players[i];
AMColor color;
if (!playeringame[i] || p->mo == NULL)
{
continue;
}
// We don't always want to show allies on the automap.
if (dmflags2 & DF2_NO_AUTOMAP_ALLIES && i != consoleplayer)
continue;
if (deathmatch && !demoplayback &&
!p->mo->IsTeammate (players[consoleplayer].mo) &&
p != players[consoleplayer].camera->player)
{
continue;
}
if (p->mo->alpha < OPAQUE)
{
color = AMColors[AMColors.AlmostBackgroundColor];
}
else
{
float h, s, v, r, g, b;
D_GetPlayerColor (i, &h, &s, &v, NULL);
HSVtoRGB (&r, &g, &b, h, s, v);
color.FromRGB(clamp (int(r*255.f),0,255), clamp (int(g*255.f),0,255), clamp (int(b*255.f),0,255));
}
if (p->mo != NULL)
{
pt.x = p->mo->x >> FRACTOMAPBITS;
pt.y = p->mo->y >> FRACTOMAPBITS;
angle = p->mo->angle;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&pt.x, &pt.y);
angle -= players[consoleplayer].camera->angle - ANG90;
}
AM_drawLineCharacter(&MapArrow[0], MapArrow.Size(), 0, angle, color, pt.x, pt.y);
}
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_drawKeys ()
{
AMColor color;
mpoint_t p;
angle_t angle;
TThinkerIterator<AKey> it;
AKey *key;
while ((key = it.Next()) != NULL)
{
p.x = key->x >> FRACTOMAPBITS;
p.y = key->y >> FRACTOMAPBITS;
angle = key->angle;
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&p.x, &p.y);
angle += ANG90 - players[consoleplayer].camera->angle;
}
if (key->flags & MF_SPECIAL)
{
// Find the key's own color.
// Only works correctly if single-key locks have lower numbers than any-key locks.
// That is the case for all default keys, however.
int P_GetMapColorForKey (AInventory * key);
int c = P_GetMapColorForKey(key);
if (c >= 0) color.FromRGB(RPART(c), GPART(c), BPART(c));
else color = AMColors[AMColors.ThingColor_CountItem];
AM_drawLineCharacter(&EasyKey[0], EasyKey.Size(), 0, 0, color, p.x, p.y);
}
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_drawThings ()
{
AMColor color;
int i;
AActor* t;
mpoint_t p;
angle_t angle;
for (i=0;i<numsectors;i++)
{
t = sectors[i].thinglist;
while (t)
{
if (am_cheat > 0 || !(t->flags6 & MF6_NOTONAUTOMAP))
{
p.x = t->x >> FRACTOMAPBITS;
p.y = t->y >> FRACTOMAPBITS;
if (am_showthingsprites > 0 && t->sprite > 0)
{
FTexture *texture = NULL;
spriteframe_t *frame;
angle_t rotation = 0;
// try all modes backwards until a valid texture has been found.
for(int show = am_showthingsprites; show > 0 && texture == NULL; show--)
{
const spritedef_t& sprite = sprites[t->sprite];
const size_t spriteIndex = sprite.spriteframes + (show > 1 ? t->frame : 0);
frame = &SpriteFrames[spriteIndex];
angle_t angle = ANGLE_270 - t->angle;
if (frame->Texture[0] != frame->Texture[1]) angle += (ANGLE_180 / 16);
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
angle += players[consoleplayer].camera->angle - ANGLE_90;
}
rotation = angle >> 28;
2006-04-11 16:27:41 +00:00
const FTextureID textureID = frame->Texture[show > 2 ? rotation : 0];
texture = TexMan(textureID);
}
if (texture == NULL) goto drawTriangle; // fall back to standard display if no sprite can be found.
const fixed_t spriteXScale = FixedMul(t->scaleX, 10 * scale_mtof);
const fixed_t spriteYScale = FixedMul(t->scaleY, 10 * scale_mtof);
DrawMarker (texture, p.x, p.y, 0, !!(frame->Flip & (1 << rotation)),
spriteXScale, spriteYScale, t->Translation, FRACUNIT, 0, LegacyRenderStyles[STYLE_Normal]);
}
else
{
drawTriangle:
angle = t->angle;
2006-04-11 16:27:41 +00:00
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&p.x, &p.y);
angle += ANG90 - players[consoleplayer].camera->angle;
}
color = AMColors[AMColors.ThingColor];
// use separate colors for special thing types
if (t->flags3&MF3_ISMONSTER && !(t->flags&MF_CORPSE))
{
if (t->flags & MF_FRIENDLY) color = AMColors[AMColors.ThingColor_Friend];
else if (!(t->flags & MF_COUNTKILL)) color = AMColors[AMColors.ThingColor_NocountMonster];
else color = AMColors[AMColors.ThingColor_Monster];
}
else if (t->flags&MF_SPECIAL)
{
// Find the key's own color.
// Only works correctly if single-key locks have lower numbers than any-key locks.
// That is the case for all default keys, however.
if (t->IsKindOf(RUNTIME_CLASS(AKey)))
{
if (G_SkillProperty(SKILLP_EasyKey))
{
// Already drawn by AM_drawKeys(), so don't draw again
color.Index = -1;
}
else if (am_showkeys)
{
int P_GetMapColorForKey (AInventory * key);
int c = P_GetMapColorForKey(static_cast<AKey *>(t));
if (c >= 0) color.FromRGB(RPART(c), GPART(c), BPART(c));
else color = AMColors[AMColors.ThingColor_CountItem];
AM_drawLineCharacter(&CheatKey[0], CheatKey.Size(), 0, 0, color, p.x, p.y);
color.Index = -1;
}
else
{
color = AMColors[AMColors.ThingColor_Item];
}
}
else if (t->flags&MF_COUNTITEM)
color = AMColors[AMColors.ThingColor_CountItem];
else
color = AMColors[AMColors.ThingColor_Item];
}
if (color.Index != -1)
{
AM_drawLineCharacter
(thintriangle_guy, NUMTHINTRIANGLEGUYLINES,
16<<MAPBITS, angle, color, p.x, p.y);
}
if (am_cheat == 3 || am_cheat == 6)
{
static const mline_t box[4] =
{
{ { -MAPUNIT, -MAPUNIT }, { MAPUNIT, -MAPUNIT } },
{ { MAPUNIT, -MAPUNIT }, { MAPUNIT, MAPUNIT } },
{ { MAPUNIT, MAPUNIT }, { -MAPUNIT, MAPUNIT } },
{ { -MAPUNIT, MAPUNIT }, { -MAPUNIT, -MAPUNIT } },
};
AM_drawLineCharacter (box, 4, t->radius >> FRACTOMAPBITS, angle - t->angle, color, p.x, p.y);
}
}
}
t = t->snext;
}
}
}
//=============================================================================
//
//
//
//=============================================================================
static void DrawMarker (FTexture *tex, fixed_t x, fixed_t y, int yadjust,
- Updated lempar.c to v1.31. - Added .txt files to the list of types (wad, zip, and pk3) that can be loaded without listing them after -file. - Fonts that are created by the ACS setfont command to wrap a texture now support animated textures. - FON2 fonts can now use their full palette for CR_UNTRANSLATED when drawn with the hardware 2D path instead of being restricted to the game palette. - Fixed: Toggling vid_vsync would reset the displayed fullscreen gamma to 1 on a Radeon 9000. - Added back the off-by-one palette handling, but in a much more limited scope than before. The skipped entry is assumed to always be at 248, and it is assumed that all Shader Model 1.4 cards suffer from this. That's because all SM1.4 cards are based on variants of the ATI R200 core, and the RV250 in a Radeon 9000 craps up like this. I see no reason to assume that other flavors of the R200 are any different. (Interesting note: With the Radeon 9000, D3DTADDRESS_CLAMP is an invalid address mode when using the debug Direct3D 9 runtime, but it works perfectly fine with the retail Direct3D 9 runtime.) (Insight: The R200 probably uses bytes for all its math inside pixel shaders. That would explain perfectly why I can't use constants greater than 1 with PS1.4 and why it can't do an exact mapping to every entry in the color palette. - Fixed: The software shaded drawer did not work for 2D, because its selected "color"map was replaced with the identitymap before being used. - Fixed: I cannot use Printf to output messages before the framebuffer was completely setup, meaning that Shader Model 1.4 cards could not change resolution. - I have decided to let remap palettes specify variable alpha values for their colors. D3DFB no longer forces them to 255. - Updated re2c to version 0.12.3. - Fixed: A_Wander used threshold as a timer, when it should have used reactiontime. - Fixed: A_CustomRailgun would not fire at all for actors without a target when the aim parameter was disabled. - Made the warp command work in multiplayer, again courtesy of Karate Chris. - Fixed: Trying to spawn a bot while not in a game made for a crashing time. (Patch courtesy of Karate Chris.) - Removed some floating point math from hu_scores.cpp that somebody's GCC gave warnings for (not mine, though). - Fixed: The SBarInfo drawbar command crashed if the sprite image was unavailable. - Fixed: FString::operator=(const char *) did not release its old buffer when being assigned to the null string. - The scanner no longer has an upper limit on the length of strings it accepts, though short strings will be faster than long ones. - Moved all the text scanning functions into a class. Mainly, this means that multiple script scanner states can be stored without being forced to do so recursively. I think I might be taking advantage of that in the near future. Possibly. Maybe. - Removed some potential buffer overflows from the decal parser. - Applied Blzut3's SBARINFO update #9: * Fixed: When using even length values in drawnumber it would cap to a 98 value instead of a 99 as intended. * The SBarInfo parser can now accept negatives for coordinates. This doesn't allow much right now, but later I plan to add better fullscreen hud support in which the negatives will be more useful. This also cleans up the source a bit since all calls for (x, y) coordinates are with the function getCoordinates(). - Added support for stencilling actors. - Added support for non-black colors specified with DTA_ColorOverlay to the software renderer. - Fixed: The inverse, gold, red, and green fixed colormaps each allocated space for 32 different colormaps, even though each only used the first one. - Added two new blending flags to make reverse subtract blending more useful: STYLEF_InvertSource and STYLEF_InvertOverlay. These invert the color that gets blended with the background, since that seems like a good idea for reverse subtraction. They also work with the other two blending operations. - Added subtract and reverse subtract blending operations to the renderer. Since the ERenderStyle enumeration was getting rather unwieldy, I converted it into a new FRenderStyle structure that lets each parameter of the blending equation be set separately. This simplified the set up for the blend quite a bit, and it means a number of new combinations are available by setting the parameters properly. SVN r710 (trunk)
2008-01-25 23:57:44 +00:00
INTBOOL flip, fixed_t xscale, fixed_t yscale, int translation, fixed_t alpha, DWORD fillcolor, FRenderStyle renderstyle)
{
if (tex == NULL || tex->UseType == FTexture::TEX_Null)
{
return;
}
if (am_rotate == 1 || (am_rotate == 2 && viewactive))
{
AM_rotatePoint (&x, &y);
}
screen->DrawTexture (tex, CXMTOF(x) + f_x, CYMTOF(y) + yadjust + f_y,
DTA_DestWidth, MulScale16 (tex->GetScaledWidth() * CleanXfac, xscale),
DTA_DestHeight, MulScale16 (tex->GetScaledHeight() * CleanYfac, yscale),
DTA_ClipTop, f_y,
DTA_ClipBottom, f_y + f_h,
DTA_ClipLeft, f_x,
DTA_ClipRight, f_x + f_w,
DTA_FlipX, flip,
- Discovered that Shader Model 1.4 clamps my constants, so I can't use palettes smaller than 256 entries with the shader I wrote for it. Is there a list of gotchas like this listed some where? I'd really like to see it. Well, when compiled with SM2.0, the PalTex shader seems to be every-so- slightly faster on my GF7950GT than the SM1.4 version, so I guess it's a minor win for cards that support it. - Fixed: ST_Endoom() failed to free the bitmap it used. - Added the DTA_ColorOverlay attribute to blend a color with the texture being drawn. For software, this (currently) only works with black. For hardware, it works with any color. The motiviation for this was so I could rewrite the status bar calls that passed DIM_MAP to DTA_Translation to draw darker icons into something that didn't require making a whole new remap table. - After having an "OMG! How could I have been so stupid?" moment, I have removed the off-by-one check from D3DFB. I had thought the off-by-one error was caused by rounding errors by the shader hardware. Not so. Rather, I wasn't sampling what I thought I was sampling. A texture that uses palette index 255 passes the value 1.0 to the shader. The shader needs to adjust the range of its palette indexes, or it will end up trying to read color 256 from the palette texture when it should be reading color 255. Doh! - The TranslationToTable() function has been added to map from translation numbers used by actors to the tables those numbers represent. This function performs validation for the input and returns NULL if the input value is invalid. - Major changes to the way translation tables work: No longer are they each a 256-byte array. Instead, the FRemapTable structure is used to represent each one. It includes a remap array for the software renderer, a palette array for a hardware renderer, and a native texture pointer for D3DFB. The translationtables array itself is now an array of TArrays that point to the real tables. The DTA_Translation attribute must also be passed a pointer to a FRemapTable, not a byte array as previously. - Modified DFrameBuffer::DrawRateStuff() so that it can do its thing properly for D3DFB's 2D mode. Before, any fullscreen graphics (like help images) covered it up. SVN r640 (trunk)
2007-12-26 04:42:15 +00:00
DTA_Translation, TranslationToTable(translation),
DTA_Alpha, alpha,
- Updated lempar.c to v1.31. - Added .txt files to the list of types (wad, zip, and pk3) that can be loaded without listing them after -file. - Fonts that are created by the ACS setfont command to wrap a texture now support animated textures. - FON2 fonts can now use their full palette for CR_UNTRANSLATED when drawn with the hardware 2D path instead of being restricted to the game palette. - Fixed: Toggling vid_vsync would reset the displayed fullscreen gamma to 1 on a Radeon 9000. - Added back the off-by-one palette handling, but in a much more limited scope than before. The skipped entry is assumed to always be at 248, and it is assumed that all Shader Model 1.4 cards suffer from this. That's because all SM1.4 cards are based on variants of the ATI R200 core, and the RV250 in a Radeon 9000 craps up like this. I see no reason to assume that other flavors of the R200 are any different. (Interesting note: With the Radeon 9000, D3DTADDRESS_CLAMP is an invalid address mode when using the debug Direct3D 9 runtime, but it works perfectly fine with the retail Direct3D 9 runtime.) (Insight: The R200 probably uses bytes for all its math inside pixel shaders. That would explain perfectly why I can't use constants greater than 1 with PS1.4 and why it can't do an exact mapping to every entry in the color palette. - Fixed: The software shaded drawer did not work for 2D, because its selected "color"map was replaced with the identitymap before being used. - Fixed: I cannot use Printf to output messages before the framebuffer was completely setup, meaning that Shader Model 1.4 cards could not change resolution. - I have decided to let remap palettes specify variable alpha values for their colors. D3DFB no longer forces them to 255. - Updated re2c to version 0.12.3. - Fixed: A_Wander used threshold as a timer, when it should have used reactiontime. - Fixed: A_CustomRailgun would not fire at all for actors without a target when the aim parameter was disabled. - Made the warp command work in multiplayer, again courtesy of Karate Chris. - Fixed: Trying to spawn a bot while not in a game made for a crashing time. (Patch courtesy of Karate Chris.) - Removed some floating point math from hu_scores.cpp that somebody's GCC gave warnings for (not mine, though). - Fixed: The SBarInfo drawbar command crashed if the sprite image was unavailable. - Fixed: FString::operator=(const char *) did not release its old buffer when being assigned to the null string. - The scanner no longer has an upper limit on the length of strings it accepts, though short strings will be faster than long ones. - Moved all the text scanning functions into a class. Mainly, this means that multiple script scanner states can be stored without being forced to do so recursively. I think I might be taking advantage of that in the near future. Possibly. Maybe. - Removed some potential buffer overflows from the decal parser. - Applied Blzut3's SBARINFO update #9: * Fixed: When using even length values in drawnumber it would cap to a 98 value instead of a 99 as intended. * The SBarInfo parser can now accept negatives for coordinates. This doesn't allow much right now, but later I plan to add better fullscreen hud support in which the negatives will be more useful. This also cleans up the source a bit since all calls for (x, y) coordinates are with the function getCoordinates(). - Added support for stencilling actors. - Added support for non-black colors specified with DTA_ColorOverlay to the software renderer. - Fixed: The inverse, gold, red, and green fixed colormaps each allocated space for 32 different colormaps, even though each only used the first one. - Added two new blending flags to make reverse subtract blending more useful: STYLEF_InvertSource and STYLEF_InvertOverlay. These invert the color that gets blended with the background, since that seems like a good idea for reverse subtraction. They also work with the other two blending operations. - Added subtract and reverse subtract blending operations to the renderer. Since the ERenderStyle enumeration was getting rather unwieldy, I converted it into a new FRenderStyle structure that lets each parameter of the blending equation be set separately. This simplified the set up for the blend quite a bit, and it means a number of new combinations are available by setting the parameters properly. SVN r710 (trunk)
2008-01-25 23:57:44 +00:00
DTA_FillColor, fillcolor,
DTA_RenderStyle, DWORD(renderstyle),
TAG_DONE);
}
//=============================================================================
//
//
//
//=============================================================================
void AM_drawMarks ()
{
for (int i = 0; i < AM_NUMMARKPOINTS; i++)
{
if (markpoints[i].x != -1)
{
- Updated lempar.c to v1.31. - Added .txt files to the list of types (wad, zip, and pk3) that can be loaded without listing them after -file. - Fonts that are created by the ACS setfont command to wrap a texture now support animated textures. - FON2 fonts can now use their full palette for CR_UNTRANSLATED when drawn with the hardware 2D path instead of being restricted to the game palette. - Fixed: Toggling vid_vsync would reset the displayed fullscreen gamma to 1 on a Radeon 9000. - Added back the off-by-one palette handling, but in a much more limited scope than before. The skipped entry is assumed to always be at 248, and it is assumed that all Shader Model 1.4 cards suffer from this. That's because all SM1.4 cards are based on variants of the ATI R200 core, and the RV250 in a Radeon 9000 craps up like this. I see no reason to assume that other flavors of the R200 are any different. (Interesting note: With the Radeon 9000, D3DTADDRESS_CLAMP is an invalid address mode when using the debug Direct3D 9 runtime, but it works perfectly fine with the retail Direct3D 9 runtime.) (Insight: The R200 probably uses bytes for all its math inside pixel shaders. That would explain perfectly why I can't use constants greater than 1 with PS1.4 and why it can't do an exact mapping to every entry in the color palette. - Fixed: The software shaded drawer did not work for 2D, because its selected "color"map was replaced with the identitymap before being used. - Fixed: I cannot use Printf to output messages before the framebuffer was completely setup, meaning that Shader Model 1.4 cards could not change resolution. - I have decided to let remap palettes specify variable alpha values for their colors. D3DFB no longer forces them to 255. - Updated re2c to version 0.12.3. - Fixed: A_Wander used threshold as a timer, when it should have used reactiontime. - Fixed: A_CustomRailgun would not fire at all for actors without a target when the aim parameter was disabled. - Made the warp command work in multiplayer, again courtesy of Karate Chris. - Fixed: Trying to spawn a bot while not in a game made for a crashing time. (Patch courtesy of Karate Chris.) - Removed some floating point math from hu_scores.cpp that somebody's GCC gave warnings for (not mine, though). - Fixed: The SBarInfo drawbar command crashed if the sprite image was unavailable. - Fixed: FString::operator=(const char *) did not release its old buffer when being assigned to the null string. - The scanner no longer has an upper limit on the length of strings it accepts, though short strings will be faster than long ones. - Moved all the text scanning functions into a class. Mainly, this means that multiple script scanner states can be stored without being forced to do so recursively. I think I might be taking advantage of that in the near future. Possibly. Maybe. - Removed some potential buffer overflows from the decal parser. - Applied Blzut3's SBARINFO update #9: * Fixed: When using even length values in drawnumber it would cap to a 98 value instead of a 99 as intended. * The SBarInfo parser can now accept negatives for coordinates. This doesn't allow much right now, but later I plan to add better fullscreen hud support in which the negatives will be more useful. This also cleans up the source a bit since all calls for (x, y) coordinates are with the function getCoordinates(). - Added support for stencilling actors. - Added support for non-black colors specified with DTA_ColorOverlay to the software renderer. - Fixed: The inverse, gold, red, and green fixed colormaps each allocated space for 32 different colormaps, even though each only used the first one. - Added two new blending flags to make reverse subtract blending more useful: STYLEF_InvertSource and STYLEF_InvertOverlay. These invert the color that gets blended with the background, since that seems like a good idea for reverse subtraction. They also work with the other two blending operations. - Added subtract and reverse subtract blending operations to the renderer. Since the ERenderStyle enumeration was getting rather unwieldy, I converted it into a new FRenderStyle structure that lets each parameter of the blending equation be set separately. This simplified the set up for the blend quite a bit, and it means a number of new combinations are available by setting the parameters properly. SVN r710 (trunk)
2008-01-25 23:57:44 +00:00
DrawMarker (TexMan(marknums[i]), markpoints[i].x, markpoints[i].y, -3, 0,
FRACUNIT, FRACUNIT, 0, FRACUNIT, 0, LegacyRenderStyles[STYLE_Normal]);
}
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_drawAuthorMarkers ()
{
// [RH] Draw any actors derived from AMapMarker on the automap.
// If args[0] is 0, then the actor's sprite is drawn at its own location.
// Otherwise, its sprite is drawn at the location of any actors whose TIDs match args[0].
TThinkerIterator<AMapMarker> it (STAT_MAPMARKER);
AMapMarker *mark;
while ((mark = it.Next()) != NULL)
{
if (mark->flags2 & MF2_DORMANT)
{
continue;
}
FTextureID picnum;
FTexture *tex;
WORD flip = 0;
if (mark->picnum.isValid())
{
tex = TexMan(mark->picnum);
if (tex->Rotations != 0xFFFF)
{
spriteframe_t *sprframe = &SpriteFrames[tex->Rotations];
picnum = sprframe->Texture[0];
flip = sprframe->Flip & 1;
tex = TexMan[picnum];
}
}
else
{
spritedef_t *sprdef = &sprites[mark->sprite];
if (mark->frame >= sprdef->numframes)
{
continue;
}
else
{
spriteframe_t *sprframe = &SpriteFrames[sprdef->spriteframes + mark->frame];
picnum = sprframe->Texture[0];
flip = sprframe->Flip & 1;
tex = TexMan[picnum];
}
}
FActorIterator it (mark->args[0]);
AActor *marked = mark->args[0] == 0 ? mark : it.Next();
while (marked != NULL)
{
// Use more correct info if we have GL nodes available
if (mark->args[1] == 0 ||
(mark->args[1] == 1 && (hasglnodes ?
marked->subsector->flags & SSECF_DRAWN :
marked->Sector->MoreFlags & SECF_DRAWN)))
{
DrawMarker (tex, marked->x >> FRACTOMAPBITS, marked->y >> FRACTOMAPBITS, 0,
flip, mark->scaleX, mark->scaleY, mark->Translation,
mark->alpha, mark->fillcolor, mark->RenderStyle);
}
marked = mark->args[0] != 0 ? it.Next() : NULL;
}
}
}
//=============================================================================
//
//
//
//=============================================================================
void AM_drawCrosshair (const AMColor &color)
{
screen->DrawPixel(f_w/2, (f_h+1)/2, color.Index, color.RGB);
}
//=============================================================================
//
//
//
//=============================================================================
void AM_Drawer ()
{
if (!automapactive)
return;
bool allmap = (level.flags2 & LEVEL2_ALLMAP) != 0;
bool allthings = allmap && players[consoleplayer].mo->FindInventory(RUNTIME_CLASS(APowerScanner), true) != NULL;
AM_initColors (viewactive);
if (!viewactive)
{
// [RH] Set f_? here now to handle automap overlaying
// and view size adjustments.
f_x = f_y = 0;
f_w = screen->GetWidth ();
f_h = ST_Y;
f_p = screen->GetPitch ();
AM_clearFB(AMColors[AMColors.Background]);
}
else
{
f_x = viewwindowx;
f_y = viewwindowy;
- Ported vlinetallasm4 to AMD64 assembly. Even with the increased number of registers AMD64 provides, this routine still needs to be written as self- modifying code for maximum performance. The additional registers do allow for further optimization over the x86 version by allowing all four pixels to be in flight at the same time. The end result is that AMD64 ASM is about 2.18 times faster than AMD64 C and about 1.06 times faster than x86 ASM. (For further comparison, AMD64 C and x86 C are practically the same for this function.) Should I port any more assembly to AMD64, mvlineasm4 is the most likely candidate, but it's not used enough at this point to bother. Also, this may or may not work with Linux at the moment, since it doesn't have the eh_handler metadata. Win64 is easier, since I just need to structure the function prologue and epilogue properly and use some assembler directives/macros to automatically generate the metadata. And that brings up another point: You need YASM to assemble the AMD64 code, because NASM doesn't support the Win64 metadata directives. - Added an SSE version of DoBlending. This is strictly C intrinsics. VC++ still throws around unneccessary register moves. GCC seems to be pretty close to optimal, requiring only about 2 cycles/color. They're both faster than my hand-written MMX routine, so I don't need to feel bad about not hand-optimizing this for x64 builds. - Removed an extra instruction from DoBlending_MMX, transposed two instructions, and unrolled it once, shaving off about 80 cycles from the time required to blend 256 palette entries. Why? Because I tried writing a C version of the routine using compiler intrinsics and was appalled by all the extra movq's VC++ added to the code. GCC was better, but still generated extra instructions. I only wanted a C version because I can't use inline assembly with VC++'s x64 compiler, and x64 assembly is a bit of a pain. (It's a pain because Linux and Windows have different calling conventions, and you need to maintain extra metadata for functions.) So, the assembly version stays and the C version stays out. - Removed all the pixel doubling r_detail modes, since the one platform they were intended to assist (486) actually sees very little benefit from them. - Rewrote CheckMMX in C and renamed it to CheckCPU. - Fixed: CPUID function 0x80000005 is specified to return detailed L1 cache only for AMD processors, so we must not use it on other architectures, or we end up overwriting the L1 cache line size with 0 or some other number we don't actually understand. SVN r1134 (trunk)
2008-08-09 03:13:43 +00:00
f_w = viewwidth;
f_h = viewheight;
f_p = screen->GetPitch ();
}
AM_activateNewScale();
if (am_textured && hasglnodes && textured && !viewactive)
AM_drawSubsectors();
if (grid)
AM_drawGrid(AMColors.GridColor);
AM_drawWalls(allmap);
AM_drawPlayers();
if (G_SkillProperty(SKILLP_EasyKey))
AM_drawKeys();
if ((am_cheat >= 2 && am_cheat != 4) || allthings)
AM_drawThings();
AM_drawAuthorMarkers();
if (!viewactive)
AM_drawCrosshair(AMColors[AMColors.XHairColor]);
AM_drawMarks();
AM_showSS();
}
//=============================================================================
//
//
//
//=============================================================================
void AM_SerializeMarkers(FArchive &arc)
{
arc << markpointnum;
for (int i=0; i<AM_NUMMARKPOINTS; i++)
{
arc << markpoints[i].x << markpoints[i].y;
}
arc << scale_mtof;
arc << scale_ftom;
2008-01-08 01:48:33 +00:00
}