raze-gles/polymer/eduke32/source/lunatic/doc/lunatic.txt
helixhorned 10a0e82736 Fix the "fix for flying/jumping monsters getting stuck in water".
In C and Lunatic, split 'jumptoplayer' of enum amoveflags_t / action.MOVFLAGS
into 'jumptoplayer_bits' and 'jumptoplayer_only' (see updated Lunatic doc).

git-svn-id: https://svn.eduke32.com/eduke32@4378 1a8010ca-5511-0410-912e-c29ae57300e0
2014-03-16 14:37:52 +00:00

2641 lines
104 KiB
Text

Lunatic User Manual
===================
Helixhorned <contact: Duke4.net forums>
:max-width: 56em
:numbered:
:icons:
:toc:
:toclevels: 3
:language: lua
[red]*DRAFT DRAFT DRAFT*
Lunatic is in preview stage. Modifications or TCs may be started, but must not
be released. The interfaces (including constants, functions, methods *and
structure members*) described in this document may be assumed to not change
significantly until release, but *undocumented API may change without further
notice*.
[red]*DRAFT DRAFT DRAFT*
Introduction
------------
Language
--------
:Lua51: http://www.lua.org/about.html
:Lua51Ref: http://www.lua.org/manual/5.1/
:PiL: http://www.lua.org/docs.html
:LuaJIT: http://luajit.org
:LuaJIText: http://luajit.org/extensions.html
The base language for writing Lunatic user code is {Lua51}[Lua 5.1]. It is
extensively documented in a {Lua51Ref}[Reference Manual], as well as described
more broadly and accessibly in the {PiL}[Programming in Lua] books.
// TODO: describe Lua a bit
Because Lunatic is implemented using {LuaJIT}[LuaJIT], a just-in-time compiler
for the Lua language, some {LuaJIText}[extensions] to the core language are
automatically available. They may be used if no compatibility with Rio Lua 5.1
is desired.footnote:[Not all extensions from LuaJIT are available, since some
like the FFI are targeted at C programmers rather than scripting coders.]
NOTE: The length operator (`#`) for table arguments should be taken to be
defined by the http://www.lua.org/manual/5.2/manual.html#3.4.6[stricter wording
of Lua 5.2].
Environment and Usage
---------------------
Lunatic aims to provide a _safe_ scripting environment for EDuke32. Thus, not
all of Lua's functionality is available in Lunatic, and some is slightly
altered to play well with being embedded into a game, or to prevent commonly
occurring mistakes.
.Differences from default Lua environment
- Creating new variables in the global environment is forbidden.
- Referencing a non-existent variable (i.e. one that has value *nil*) is an
error.
EDuke32 can load multiple Lunatic _modules_ when starting up. This is always
done after translating CON code to Lua and loading it. Such modules must reside
in files named `*.lua` (case-sensitive) and should be passed directly, without
any option letters, at the command line. Directory separators must be forward
slashes.
The command-line option `-Lopts=strict` enables errors on certain conditions
that may indicate problems in user Lua or CON code. Currently, strict mode
checks for
* Accesses to <<sprite,sprites>> not in the game world
* Indexing the tables returned by <<require,`require("DEFS")`>> and the like
with nonexistent keys. This may indicate a missing file from a bundle
belonging together.
.Invocation example
====================
`eduke32 -nologo MYTC.CON -mx addition.con test.lua weapons/nuke.lua -v1 -l1`
====================
If the OS environment variable `LUNATIC_TIMING_BASEFN` is defined, EDuke32 will
write out aggregate timing results for actors and events in a comma-separated
value format, obtained by suffixing the base name with ```.actors.csv`'' and
```.events.csv`''.
Global Environment
------------------
When a Lua module is loaded, its global environment contains both selected
functions from core Lua, as well as Lunatic's own pre-defined variables.
These allow access and manipulation of EDuke32 engine and game data.
[icon="din_w_explosive.png"]
CAUTION: If an attempt is made to create a new variable in the global
environment or to assign any value to an existing variable, the behavior is
undefined.
For convenience of debugging from the command line (using the `lua` OSD
command), the global environment contains a table `d` which is initially
empty. It should only be used to temporarily store values of interest in a
debugging session and should never be referenced from actual script code.
Lua functions
~~~~~~~~~~~~~
The following base Lua functions are available in Lunatic's global environment:
`assert`, *`error`*, `ipairs`, `pairs`, `pcall`, *`print`*, *`module`*, `next`,
*`require`*, `select`, `tostring`, `tonumber`, `type`, `unpack`, `xpcall`.
The bold ones add functionality or behave slightly differently, described below.
Additionally, `printf` is provided for convenience.
[[error]] *`error(message [, level])`*::
In Lunatic, errors also print to the on-screen display (OSD) and are written to
the log (unless a maximum error count is exceeded). These also have a
_backtrace_ added. Additionally, errors not caught by a `pcall` result a
permanent message to appear on the screen, containing the source file name and
line number.
*`print(...)`*::
The messages are printed to the OSD and the log. Color codes available in
EDuke32 (e.g. `^10` for dark red) are interpreted. Overriding `tostring` has no
effect on Lunatic's `print` as it uses the initial, built-in `tostring`
function instead of looking it up in the global environment.
*`printf(fmt, ...)`*::
Calls `print` with the result of `string.format(fmt, ...)`.
[[modules]]
Writing and using modules
~~~~~~~~~~~~~~~~~~~~~~~~~
In Lunatic, like in Lua, a _module_ is a conceptually a sort of package that
unites related bits of functionality. Language-wise, it is simply a Lua
table holding its contents, as described and motivated at length in
_Programming in Lua_ (second edition).
The ``creation'' and ``usage'' sides of the modularity concept are reflected in
two functions known from Lua 5.1, `module` and `require`. The former is a
convenient way of separating the _import_, potential _gamevar_, and main body
sections when writing a package. It is not required to use `module`, but it is
the only way to declare _game variables_, that is, variables that EDuke32
stores within savegames, recreating their values when they are loaded.
The other side of the coin, `require`, is also used like in Lua: ``including''
a named module is requested by passing its name to `require`. This searches for
a matching module, loading and running it if the request happens for the first
time.
[[require]]
==== The function `require(modname, ...)`
Attempts to find a Lua or Lunatic module named `modname`. The name can refer to
a _built-in_ module, of which the following ones are allowed:
* The http://bitop.luajit.org/[`bit`] module for bitwise operations
* `math`, `string` and `table`, base modules from Lua
* Lua's `os` module, containing a single function, `clock`. Like the
<<timing_funcs,timing functions>>, it should only be used to profile bits of
code.
* Modules provided by Lunatic, which are described in <<ext_api,their own
section>>.
If `modname` does not designate a built-in module, Lunatic first replaces every
dot contained in it with a directory separator. Then, it looks for a file with
that base name suffixed with `.lua` in the EDuke32 search path (virtual file
system, GRP, ZIP). Using directory separators directly is not allowed.
The loaded module is protected so that write accesses to its table yield
errors. Unlike in Lua, our `require` does not return *true* when a module is
requested that has not yet finished loading (that is, the inclusion chain
contains a loop). Instead, an error is raised.
Lunatic's `require` allows passing additional arguments to the module to load.
On the module side, they can be obtained by examining the vararg expression
``++\...++'' at file scope. Given a definition of `args` as `{...}`, its first
element `args[1]` would contain `modname` and the following entries the values
passed in addition to `require`. This feature is useful for parametrizing a
module: for example, the module could provide a way alter the starting tile
number of an actor it defines.
Issuing `require` for some special names listed below has a predefined meaning
that cannot be overridden by the user.
* `CON.DEFS`: returns a table mapping labels ++define++d from CON to their
values. Values pre-defined by the system are not included.
* `CON.ACTION`: returns a table mapping labels of ++action++s defined from CON
to immutable <<con_action,`con.action`>> objects.
* `CON.MOVE`: returns a table mapping labels of ++move++s defined from CON
to immutable <<con_move,`con.move`>> objects.
* `CON.AI`: returns a table mapping labels of ++ai++s defined from CON
to immutable <<con_ai,`con.ai`>> objects.
* `end_gamevars`: used to mark the end of a gamevar block, described below.
==== The `module()` function
Initiates a _module_ environment by creating a new empty table and setting it
as the global environment of the chunk. Subsequently creating global variables
will place them into this ``hidden'' table. Assuming no subsequent *`return`*
is placed at file scope, this table will be the one obtained by a `require` for
the module at the client side.
[source]
.Example file using using `module`
----------
-- Import section: cache everything the module needs into locals
local print = print
local gameactor = gameactor
local MYDEFS = require("MyEnemyDefs", 1200) -- see next example
-- After this, the global environment will be swept clean!
module(...)
-- Our enemy at last
gameactor{ MYDEFS.tilenum, strength=MYDEFS.strength,
function(aci)
print("My tilenum is "..sprite[aci].picnum.." and I "
..(MYDEFS.canfly and "can" or "can't").." fly")
end
}
----------
Unlike Lua 5.1, our `module` takes neither a name argument nor ``option''
varargs. A Lunatic file may have at most one call to `module`, which (if there
is one) *must* be called at file scope.
If the Lua file doesn't need to register any game variables, it is also
possible to return its table directly instead of using `module`. However, due
to the way modules are loaded, a trailing *`return`* statement must be wrapped
in a *`do`*...*`end`* block, like this:
.Example module `MyEnemyDefs.lua` explicitly returning a table
[source]
----------
local args = { ... }
do return {
tilenum = args[1] or 1000,
strength = 100,
canfly = true,
}
end
----------
===== Game variables
Lunatic has a special mechanism to mark variables that represent persistent
state and whose values should be stored in savegames. If such variables are
desired, they must be initialized between the `module` call in a Lua file and a
closing `require("end_gamevars")`.footnote:[The reason that the initialization
has to happen between the `module` and the `require('end_gamevars')` is that on
savegame loading, gamevars are restored from the latter.] These variables may
also be *`local`*.
Game variables may take on only values of types that Lunatic knows how to
serialize into savegames. These are the following:
* Booleans, numbers, and strings, collectively called the _basic types_
* Custom Lunatic types that are labeled _serializable_ in their documentation
* Tables, but with the following restrictions on their contents:
** A table key may only be of basic type.
** A table value may be (a reference to) any serializable object, but tables
or Lunatic objects that are so referenced *must* have originated in the
gamevar section of the same module. Beyond that, there are no restrictions
on the table topology.
[icon="din_w_collapse.png"]
CAUTION: If a gamevar contains a value that is not serializable at any point
in the execution, the behavior is undefined. Note that in particular, gamevars
are not allowed to take on the value *nil*.
// TODO: example?
// TODO: the rest
[[gv]]
The `gv` variable
~~~~~~~~~~~~~~~~~~~
Some constants, global C variables, and miscellaneous functions and structures
are accessible via the global `gv` variable.
Constants
^^^^^^^^^
`gv.MAXSECTORS`, `gv.MAXWALLS`, `gv.MAXSPRITES`::
The hard engine limits on the number of sectors, walls, and sprites. These
constants *must* be used instead of any literal numeric values because they
can change depending on how EDuke32 was configured and built.
`gv.CEILING`, `gv.FLOOR`, `gv.BOTH_CF`::
Constants permissible to the <<sectorsofbunch_1,`sectorsofbunch`>> iterator.
//////////
`gv.MAXSTATUS`, `gv.MAXTILES`, `gv.MAXSPRITESONSCREEN`::
TODO
`gv.MAXBUNCHES`::
TODO
//////////
`gv.CLIPMASK0`::
A clipping (collision detection) mask specifying to consider only _blocking_
walls and sprites.
`gv.CLIPMASK1`::
A clipping (collision detection) mask specifying to consider only _hitscan
sensitive_ walls and sprites. The set bits of `CLIPMASK1` and `CLIPMASK0` are
disjoint.
[[gv_REND]] `gv.REND`::
A mapping of names to values representing rendering modes: `CLASSIC`,
`POLYMOST`, `POLYMER`.
// Game-side
[[gv_GTICSPERSEC]] `gv.GTICSPERSEC`::
The number of times in a second each actor executes its code and updates its
position (``game tics'').
[[gv_GET]] `gv.GET`::
A mapping of names to inventory indices: `STEROIDS`, `SHIELD`, `SCUBA`,
`HOLODUKE`, `JETPACK`, `DUMMY1`, `ACCESS`, `HEATS`, `DUMMY2`, `FIRSTAID`,
`BOOTS`.
`gv.GET_MAX`::
The maximum permissible inventory index plus one.
[[gv_WEAPON]] `gv.WEAPON`::
A mapping of names to weapon indices: `KNEE`, `PISTOL`, `SHOTGUN`, `CHAINGUN`,
`RPG`, `HANDBOMB`, `SHRINKER`, `DEVISTATOR`, `TRIPBOMB`, `FREEZE`,
`HANDREMOTE`, `GROW`. Note that ```DEVISTATOR`'' is misspelled.
`gv.MAX_WEAPONS`::
The maximum permissible weapon index plus one.
//////////
`gv.MAXPLAYERS`::
TODO
//////////
`gv.LUNATIC_CLIENT`::
A constant indicating which program Lua is embedded into. It can be compared
for (in)equality with:
+
* `gv.LUNATIC_CLIENT_EDUKE32`
* `gv.LUNATIC_CLIENT_MAPSTER32`
+
(Mapster32 supports a subset of Lunatic that is not documented and subject to
change at any time.)
Variables
^^^^^^^^^
`gv.numsectors` (read-only)::
The total number of sectors in the currently loaded map.
`gv.numwalls` (read-only)::
The total number of walls in the currently loaded map.
[[totalclock]] `gv.totalclock` (read-only)::
The current value of the engine timer that increments at a rate of 120 per
second under default settings. (Thus, one game tic corresponds to four
`totalclock` increments.) When staying within one ``mode'' such as in-menu or
in-game, it is guaranteed to not decrease. However, going from one mode to
another may produce discontinuities.
`gv.gametic` (read-only)::
The number of <<gv_GTICSPERSEC,game tics>> that have elapsed since starting the
current level. This value is guaranteed to not decrease during a game, and is
restored from savegames.
`gv.screenpeek` (read-only)::
The player index of the player from whose position the scene is being displayed.
`gv.rendmode` (read-only)::
The current rendering mode as a value that can be compared against those in
<<gv_REND,`gv.REND`>>.
`gv.hudweap`::
A structure containing information about the currently displayed HUD weapon.
Contains the following members, which are set from C before entering
`EVENT_DISPLAYWEAPONS`: `cur`, `count`, `gunposx`, `gunposy`, `lookhalfang`,
`lookhoriz`, `shade`.
// TODO: describe
`gv.cam`::
A structure that, prior to entering `EVENT_DISPLAYROOMS`, is populated with the
position and orientation of the ``camera'' from which the scene would be drawn.
Contains the following members: `pos`, `dist`, `clock`, `ang`, `horiz`, `sect`.
// TODO: describe
// TODO: g_logoFlags?
[[gv_RETURN]] `gv.RETURN`::
A special variable that is used by the game to pass specific values to game
events, or to examine values passed back from events and act upon them
accordingly. Refer to <<Appendix_event_RETURN,Appendix B>> for a list of how the various
events interpret this variable.
Functions
^^^^^^^^^
`gv.getangle(x, y)`::
Returns an approximation of the angle between the line segments (0,0)->(1,0)
and (0,0)->(`x`,`y`) in BUILD angle units in the range [0 .. 2047].
[[krand]] `gv.krand()`::
Returns one value from the global engine-side pseudo-random number generator
in the integer range [0{nbsp}..{nbsp}65535].
[[timing_funcs]] `gv.getticks()`, `gv.gethiticks()`::
Each of these functions return a number that increases at a rate of 1 per
millisecond. Their only intended application is to profile bits of code; they
should not be used to control the game world. The two functions differ in their
precision: `getticks()` always returns integral values, while the result of
`gethiticks()` also has an unspecified precision in the fractional part. (It
can be expected to give a time precision of at least one microsecond.)
`gv.doQuake(gametics [, snd])`::
Requests from the game to perform the ``quake'' effect that shakes the screen
etc. for the next `gametics` game tics. If a sound index `snd` is passed, also
start playing that sound.
// TODO: Play sound how? ("globalsound")
`gv.currentEpisode()`::
Returns the one-based number of the episode currently being played.
`gv.currentLevel()`::
Returns the one-based number of the level currently being played.
[[Lunatic_structures]]
Lunatic structures
~~~~~~~~~~~~~~~~~~
The primary means of effecting game state in Lunatic is via _composite
variables_ defined in the global environment. These provide direct, but
restricted, access to C _structure arrays_ of the EDuke32 engine or game.
[icon="din_w_toxic.png"]
CAUTION: If an attempt is made to access any composite variable outside of
event or actor code, the behavior is undefined.
Composite variables can be used in various ways. All of them allow indexing
with an integer value from `0` to some maximum (sometimes the size of the array
minus one, but occasionally less). For example, the code snippet
[source]
----------
local sec = sector[0]
----------
gets a _reference_ to the first sector of the loaded map into the local `sec`.
This reference can then be used to both read and write its members.
Various structures also provide _methods_ in Lunatic to modify their state,
usable with Lua's `v:func(args...)` syntax. Building on the previous example,
[source]
----------
local cz = sec:ceilingzat(wall[sec.wallptr])
----------
would get into `cz` the ceiling z position at the first sector's first
wall-point.
Finally, some composite variables offer _static data_, which can contain
functions or tables of constants. These are accessed using the dot notation on
the composite variable, *not* its constituents. For instance, the following can
be used to change the sector number of the sprite with index `i` manually:
[source]
----------
sprite.changesect(i, sectnum)
----------
Type of structure members
^^^^^^^^^^^^^^^^^^^^^^^^^
In the following, some structure members will be annotated with their _integer
type_, for example _`i16`_ or _`u8`_. The letter _`i`_ denotes a _signed_
integer whereas a _`u`_ designates an _unsigned_ one. The number following that
letter indicates the _bit width_ of that integer.
.Representable values
* A member of signed integer type and bit width _B_ can contain any whole
number from --2^_B_--1^ to 2^_B_--1^--1. +
* A member of unsigned integer type and bit width _B_ can contain any whole
number from 0 to 2^_B_^--1.
[[int_assignment]]
.Assignment
1. If an assignment to a member having signed integer type is made, the
``right-hand side'' value must be a number in the closed interval
[--2^31^ .. 2^31^--1].
2. If an assignment to a member having unsigned integer type and bit width _B_
is made, the ``right-hand side'' value must be in the closed interval
[--2^31^ .. 2^31^--1] if _B_ is less than 32, or in [0 .. 2^32^--1] otherwise.
3. If the appropriate requirements hold, an assignment from a Lua number to a
member having integer type begins by discarding the fractional part
(``truncation''). Otherwise, the behavior is undefined. +
4. If the truncated value is outside the range of representable values for the
corresponding integer type of bit width _B_, the final value is obtained by
successively adding or subtracting 2^B^, until the value falls inside that
range.
//////////
NOTE to self: this is stricter than C99 (which has first truncation, then range
check). Also, it may be tempting to assign 0x80000000 to an int32_t to mean
INT32_MIN, but this is wrong because it's out of range.
Also see:
http://lua-users.org/lists/lua-l/2011-09/msg00534.html
//////////
.Examples
1. Assignments to _`u8`_ member `visibility`
* `sec.visibility=3.94159` results the member to contain the integer `3`
* `sec.visibility=1/0` is undefined (attempt to assign an infinity)
* `sec.visibility=-1` results the member to contain the integer `255`
2. Assignments to _`i16`_ member `lotag`
* `sec.lotag=32768` results the member to contain `-32768`
* `sec.lotag=2^32` is undefined
[[bit_fields]]
Bit fields
^^^^^^^^^^
Some structures contain members that represent a collection of _flags_, for
example `sprite[].cstat` or `actor[].flags`. These flags can be toggled by
setting or clearing their respective _bits_ (integer numbers that are powers of
two).
For convenience, Lunatic provides alternative names for some of these members,
together with methods to examine or modify any number of bits of such a member
in one expression. Whenever there is such an alternative name available, it is
declared as having type _`bitfield`_ in the listings of the structure members.
===== methods of the _`bitfield`_ type
`bf:set(bits)`::
_Sets_ (toggles to an ``on'' state in a boolean sense) those bits of `bf`
that are set in `bits`.
`bf:clear(bits)`::
_Clears_ (toggles to an ``off'' state in a boolean sense) those bits of `bf`
that are set in `bits`.
`bf:flip(bits)`::
_Flips_ those bits of `bf` that are set in `bits`, that is, reverses their
boolean state.
`bf:test(bits)`::
Returns a boolean that indicates whether `bf` has *any* of the bits set in
`bits` set.
`bf:mask(bits)`::
Returns a number containing the bits of `bf` bitwise ANDed with those in
`bits`.
.Examples
==========
After the lines setting sprite `i` to 33% translucent and blocking,
[source]
----------
local CS = sprite.CSTAT
local spr = sprite[i]
spr.cstat = CS.TRANS1 + CS.BLOCK
----------
one could proceed as follows for the sake of example:
[source]
----------
spr.cstatbits:set(CS.TRANS2) -- make the sprite 66% translucent now
spr.cstatbits:flip(CS.BLOCK + CS.HITSCAN) -- make it hitscan-sensitive and non-blocking
local isflipped = spr.cstatbits:test(CS.FLIP_BITMASK) -- is it x- or y-flipped? (no)
----------
==========
Engine-side composites
^^^^^^^^^^^^^^^^^^^^^^
The composite variables described in this subsection provide access to
engine-side structures. The first three, `sector`, `wall`, and `sprite`,
are part of a BUILD map saved to disk. The other ones only exist when
running the game.
===== `sector`
Accessible from `0` to `gv.numsectors-1`. Each element has the following
members:
`wallptr`, `wallnum` (read-only)::
The index of the sector's first wall and the number of walls in the sector,
respectively.
_`u8`_ `visibility`::
Determines the amount of distance fading. In the range [`0` .. `239`], the
``darkening'' increases with rising values. The range [`240` .. `255`] should
be thought of as [`-16` .. `-1`].
// TODO: better wording?
_`i16`_ `lotag`, `hitag`, `extra`::
General-purpose ``tags'' provided for game programming. They may be used by
various EDuke32 sector effects, so it is not recommended to use them in
scripting code.
In addition to the members described above, each sector has two sets of members
for its ceiling and floor. A sector reference can be indexed with the strings
`ceiling` or `floor` to get references to the respective ``parts'', or one can
access the consituent members by prefixing `ceiling` or `floor` to the base
member names given below.
.Different ways of accessing the same member
==========
After the code lines
[source]
----------
local sec = sector[0]
local ceil = sec.ceiling
----------
the following expressions all denote the same location, both if read or written
to: `sec.ceilingheinum`, `ceil.heinum`, `sector[0].ceiling.heinum`,
`sector[0].ceilingheinum`.
==========
In the following, `cf` will stand for a ceiling or floor reference, while `sec`
will label a sector reference.
`cf.picnum` (read-only)::
The tile number of the ceiling or floor.
[[cf_stat]] _`u16`_ `cf.stat`, {nbsp} _`bitfield`_ `cf.statbits`::
A bit field holding various flags about how the ceiling or floor should be
displayed, how collision detection should be handled, etc.
The <<sector_STAT,`sector.STAT`>>
object should be used to obtain the values for applicable flags.
_`i16`_ `cf.heinum`::
If `cf.stat` has bit `sector.STAT.SLOPE` set, the tangent of the slope angle,
multiplied by 4096. Positive values make the ceiling or floor slope towards
the floor, negative ones slope upward.
[[cf_z]] _`i32`_ `cf.z`::
The BUILD z coordinate (scaled by 16 compared to the x and y directions) of the
pivoting line of the ceiling or floor.
`cf.bunch` (read-only)::
The ``bunch'' number of the ceiling or floor used for True Room over Room. One
bunch comprises _N_ ceilings and _M_ floors (_N_ &ge; 1, _M_ &ge; 1) such that
each set covers the same planar, connected area.
_`i8`_ `cf.shade`::
The shade of the ceiling or floor. Larger values mean a more darker appearance.
_`u8`_ `cf.pal`::
The ``palette swap'' index of the ceiling or floor.
_`u8`_ `cf.xpanning`, `cf.ypanning`::
The panning values of the ceiling or floor. One full cycle is covered by values
from `0` to `255`.
===== ceiling-or-floor methods
`cf:set_picnum(tilenum)`::
Set the tile number of the ceiling-or-floor `cf`.
===== `sector` methods
`sec:set_ceilingpicnum(tilenum)`, {nbsp} `sec:set_floorpicnum(tilenum)`::
Set the tile number of the ceiling or the floor.
[[sec_cfz_at]] `sec:ceilingzat(pos)`, {nbsp} `sec:floorzat(pos)`::
Return the z coordinate of sector `sec`'s ceiling or floor at position `pos`,
which can be anything indexable with the strings `x` and `y`.
`sec:zrangeat(pos, walldist, clipmask)` -> `hit`::
Given a starting point `pos` assumed to be contained in the sector, calculate
the z coordinates of the objects that would be first hit by a quadratic,
floor-aligned sprite pointing parallel to the grid and having side length
`2*walldist`, when travelling in a straight line up- and downwards.
+
The argument `clipmask` is a number specifying which objects should be checked
for collision: its least significant 16 bits are bitwise-ANDed with
`wall[].cstat` values, while the high 16 bits are ANDed with
`sprite[].cstat`. Whenever the so masked values are non-zero, the objects are
considered for collision.
+
The method returns an immutable structure `hit`, containing the sub-structures
`c` and `f` (for movement upwards and downwards, respectively) with the
following members:
+
* `spritep`: a boolean signifying whether a sprite was hit
* `num`: if `spritep` is true, the index of the hit sprite, otherwise the index
of the hit ceiling/floor's sector
* `z`: the z coordinate of where the sprite would end up on collision
===== `sector` static data
[[sector_STAT]] `sector.STAT`::
Provides a mapping of symbolic names to values applicable to
<<cf_stat,`cf.stat`>>. These name single bits:
`PARALLAX`, `SLOPE`, `SWAPXY`, `SMOOSH`, `FLIPX`, `FLIPY`, `RELATIVE`, `MASK`,
`TRANS1`, `TRANS2`, `BLOCK`, `HITSCAN`, while the following denote _bit masks_:
`FLIP_BITMASK`, `ORIENT_BITMASK`, `TRANS_BITMASK`.
[[sector_UPDATE_FLAGS]] `sector.UPDATE_FLAGS`::
Contains flags permissible to <<updatesector,`updatesector`>> and other sector
updating functions. `BREADTH`, `Z`.
'''
[[wall]]
===== `wall`
Accessible from `0` to `gv.numwalls-1`. Each element has the following
members:
_`i32`_ `x`, `y`::
The 2D coordinates or this wall point. Should not be set directly.
`z` (read-only)::
Always yields `0`. The primary purpose of this field is to make wall references
permissible as arguments to <<vector_types,`xmath` vector>> operations.
`point2` (read-only)::
The index of the second wall point.
[[nextwall]] `nextwall`, `nextsector` (read-only)::
If the wall is ``white'', these members equal `-1`. For ``red'' walls, they
contain the wall and sector indices (respectively) of the wall on the other side.
`upwall`, `dnwall` (read-only)::
For walls constrained by TROR extension, the upper and lower neighbor walls,
respectively. Any of them may be `-1`, meaning that the wall is not attached to
a neighbor in this direction.
[[wall_cstat]] _`u16`_ `cstat`, {nbsp} _`bitfield`_ `cstatbits`::
A bit field holding various flags about how the wall should be
displayed, how collision detection should be handled, etc.
The <<wall_CSTAT,`wall.CSTAT`>>
object should be used to obtain the values for applicable flags.
[[wall_picnum]]`picnum` (read-only)::
The tile number of the non-masked portion of the wall. If
`wall.CSTAT.BOTTOMSWAP` is set on this wall's `.cstat`, it is only displayed in
the upper portion. (The lower portion takes it from this wall's `.nextwall`
then; this will be labeled _use-other-bottom_ in the following.)
`overpicnum` (read-only)::
The tile number of the masked portion of the wall, i.e. that which is drawn if
this wall's `.cstat` has bit `wall.CSTAT.MASK` or `wall.CSTAT.ONEWAY` set.
_`i8`_ `shade` (<<wall_picnum,_use-other-bottom_>>)::
The shade of the wall for both non-masked and masked portions. Larger values
mean a more darker appearance.
_`u8`_ `pal` (<<wall_picnum,_use-other-bottom_>>)::
The ``palette swap'' index of the wall.
_`u8`_ `xrepeat`, `yrepeat`::
Values that are proportional to the number of times that the wall's texture
repeats in each direction per given wall length/height. A value of `8` renders
64 texels across a length of 1024 x/y map units or a height of 16384 z units.
_`u8`_ `xpanning`, `ypanning` (<<wall_picnum,_use-other-bottom_>>)::
The panning values of both masked and non-masked portions of the wall. One full
cycle is covered by values from `0` to `255`.
_`i16`_ `lotag`, `hitag`, `extra`::
General-purpose ``tags'' provided for game programming. They may be used by
various EDuke32 effects internally, so it is advised to do some research before
claiming them for oneself.
===== `wall` methods
`wal:set_picnum(tilenum)`, `wal:set_overpicnum(tilenum)`::
Set the tile number of the wall or its masked portion.
===== `wall` static functions
`wall.dragto(i, pos)`::
Set the position of the point of the wall with index `i` to `pos`, which can be
anything indexable with `x` and `y`. This function is the preferred way of
changing wall coordinates, since it takes care to reposition dependent wall
points, too.
===== `wall` static data
[[wall_CSTAT]] `wall.CSTAT`::
Provides a mapping of symbolic names to values applicable to
<<wall_cstat,`wall[i].cstat`>>. These name single bits:
`BLOCK`, `BOTTOMSWAP`, `ALIGNBOTTOM`, `FLIPX`, `MASK`, `ONEWAY`, `HITSCAN`,
`TRANS1`, `FLIPY`, `TRANS2`,
while the following denote _bit masks_:
`FLIP_BITMASK`, `TRANS_BITMASK`.
'''
[[sprite]]
===== `sprite`
The `sprite` composite is accessible with indices from `0` to
`gv.MAXSPRITES-1`, but accesses to sprites that do not exist in the game world
have no meaning. Each element has the following members:
_`i32`_ `x`, `y`, `z`::
The BUILD coordinates of the sprite. It is not advisable to set these directly.
//////////
_`i16`_ `ang`::
TODO (make set_ang() out of that which always ANDs with 2047?)
//////////
[[sprite_cstat]] _`u16`_ `cstat`, {nbsp} _`bitfield`_ `cstatbits`::
A bit field holding various flags about how the sprite should be
displayed, how collision detection should be handled, etc.
The <<sprite_CSTAT,`sprite.CSTAT`>>
object should be used to obtain the values for applicable flags.
`picnum` (read-only)::
The tile number of the sprite, also used to determine which actor code is run
if this sprite has a `statnum` of `actor.STAT.ACTOR`.
_`i8`_ `shade`::
The shade of the sprite. This may not be the shade that this sprite is
ultimately drawn with, though.
_`u8`_ `pal`::
The ``palette swap'' index of the sprite. This may not be the palette swap that
this sprite is ultimately drawn with, though.
_`u8`_ `blend`::
The blending table index of the sprite. See
<<blending_table_interfaces,Blending table interfaces>> for more details.
_`u8`_ `clipdist`::
If this sprite is _view-aligned_, controls the distance at which another moving
object is considered to be in collision with this *stationary* sprite. (It does
not control the inverse case.) More precisely, it designates half the
side-length of the bounding square divided by 4. Thus, a value of `255` keeps
moving objects away from this one at a max-norm distance
footnote:[The max-norm distance between points _p_~1~=(x~1~, y~1~) and
_p_~2~=(x~2~, y~2~) is defined as max(abs(x~2~ -- x~1~), abs(y~2~ -- y~1~)).]
of at least 1020
BUILD x/y units.
// ^ XXX: clipshapes? Also, clipdist is effective for moving sprites (A_MoveSprite()).
_`u8`_ `xrepeat`, `yrepeat`::
The size of the sprite in each dimension. For wall- and floor- aligned sprites,
a value of `64` means a width of 16 x/y BUILD units or a height of 256 z BUILD
units per texel.
`sectnum` (read-only)::
The index of the sector that this sprite is currently contained in.
[[sprite_statnum]] `statnum` (read-only)::
The current _status number_ of this sprite. Applicable values are contained in
<<actor_STAT,`actor.STAT`>>.
`owner` (read-only)::
The index of the sprite from which this sprite was spawned. If this sprite is
not a ``child'' of another one, then `owner` is the index of this sprite itself.
//Occasionally, game effects may use this member for their particular purposes,
//so research is recommended before claiming it for oneself.
_`i16`_ `xvel`, `zvel`::
For actors and other moving sprite kinds, the horizontal and vertical
components of the current velocity. See the description of
<<con_move,`con.move`>> for more details.
_`i16`_ `yvel` (read-only)::
A member used for different purposes by Duke3D. Setting it is only allowed
through the `set_yvel` method.
_`i16`_ `lotag`, `hitag`, `extra`::
General-purpose ``tags'' provided for game programming. They may be used by
hard-coded actors internally, so it is advised to do some research before
claiming them for oneself.
===== `sprite` methods
`spr:set_picnum(tilenum)`::
Sets the tile number of sprite `spr` to `tilenum`. It is disallowed to issue
`set_picnum` on an `APLAYER` sprite or change the tile number of a sprite to
`APLAYER`.
`spr:set_yvel(yvel)`::
Sets the `yvel` member of sprite `spr` to `yvel`. It is disallowed to issue
`set_yvel` on an `APLAYER` sprite. Further restrictions are reserved.
`spr:getheightofs()` -> `height`, `offset`::
Returns the `height` and z `offset` of sprite `spr` in BUILD z units. Adding the
`offset` to `spr.z` yields the z coordinate at the bottom of the
sprite. Subtracting from that the `height` results the z coordinate at its
top. However, the per-tile z offset is not taken into account.
`spr:setpos(pos [, newsect])`::
Unconditionally sets the position of `spr` to `pos`, which can be anything
indexable with `x`, `y` and `z`. Thus, in effect a shorthand for
+
[source]
----------
spr.x, spr.y, spr.z = pos.x, pos.y, pos.z
----------
+
If `newsect` is passed, additionally calls `spr:changesect(newsect)`. +
Returns `spr`.
`spr:changesect(sectnum)`::
An alternative way to call
+<<sprite_changesect,sprite.changesect>>(_index_of_spr_, sectnum)+, where
_`index_of_spr`_ is the sprite index corresponding to `spr`. This method is
provided for convenience, but may be slower than the static function
`changesect`.
`spr:updatesect([flags])`::
An alternative way to call
+<<sprite_updatesect,sprite.updatesect>>(_index_of_spr_, flags)+, where
_`index_of_spr`_ is the sprite index corresponding to `spr`. This method is
provided for convenience, but may be slower than the static function
`updatesect`.
===== `sprite` iterators
+*for* i *in* sprite.all()+::
Iterates over all sprites currently in the game world.
===== `sprite` static functions
`sprite.changestat(i, statnum)`::
Allows to manually change the status number of the sprite with index `i` to
`statnum`. If `i` is an invalid sprite index or the index of a sprite not in
the game world, or `statnum` is an invalid status number, an error is thrown.
[[sprite_changesect]] `sprite.changesect(i, sectnum)`::
Allows to manually change the sector number of the sprite with index `i` to
`sectnum`. If `i` is an invalid sprite index or the index of a sprite not in
the game world, or `sectnum` is an invalid sector index, an error is thrown.
[[sprite_updatesect]] `sprite.updatesect(i [, flags])`::
Updates the sector number of the sprite with index `i`, in effect setting
`sprite[i]`'s sector number to the result of
+
[source]
----------
updatesector(sprite[i].pos, sprite[i].sectnum, flags)
----------
+
If the <<updatesector,`updatesector`>> call returns `-1`, the sprite's sector
number remains unchanged. +
Returns the result of the `updatesector` call.
===== `sprite` overridden operators
[[sprite_power]] `spr^zofs`::
Returns an <<vector_types,`xmath.ivec3`>> object that contains the position of
this sprite, diminished by `zofs` in the z direction. Because in BUILD, z
coordinates increase toward the floor, the `^` can be thought of as ``raise the
sprite by `zofs` units''.
===== `sprite` static data
[[sprite_CSTAT]] `sprite.CSTAT`::
Provides a mapping of symbolic names to values applicable to
<<sprite_cstat,`sprite[i].cstat`>>. These name single bits:
`BLOCK`, `TRANS1`, `XFLIP`, `YFLIP`, `ALIGNWALL`, `ALIGNFLOOR`, `ONESIDE`,
`CENTER`, `HITSCAN`, `TRANS2`, `INVISIBLE`,
while the following denote _bit masks_: `ALIGN_BITMASK`, `TRANS_BITMASK`.
===== `spriteext`
Accessible with the same indices and with the same restrictions as
<<sprite,`sprite`>>.
//`angoff`::
//The BUILD angle that is added to that of a drawn voxel or model.
// XXX: needs better wording to express this: tspr->ang + spriteext[tspr->owner].angoff
Game-side composites
^^^^^^^^^^^^^^^^^^^^
[[actor]]
===== `actor`
The `actor` composite holds various run-time data about a sprite. Like
<<sprite,`sprite`>>, it is accessible with indices from `0` to
`gv.MAXSPRITES-1`, but accesses to actors that do not exist in the game world
have no meaning. Each element has the following members:
_`u16`_ `movflags`, {nbsp} _`bitfield`_ `movflagsbits`::
The actor's current <<actor_MOVFLAGS,movement flags>>.
[[actor_methods]]
===== `actor` methods
The following methods query or set properties related to
<<actions_moves_ais,actor behavior>>.
`a:set_action(act)`::
Sets the action of actor `a` to `act`, which may be either an object returned
by <<con_action,`con.action`>> or a number 0 or 1. Resets the actor's _action
count_ and current frame offset to 0.
`a:has_action(act)`::
Returns a boolean of whether the current action of actor `a` is `act`, which
can be any value permissible to `a:set_action()`. For composite action objects,
equality is established using its hidden ID, not the public members. Refer to
<<actions_moves_ais,Actions&#44; moves and AIs>> for further details.
`a:set_action_delay()`::
Overrides the <<action_delay,`delay`>> of the current action of actor `a`
without changing the action's ID.
`a:set_count(count)`::
Sets the actor's _execution count_ to `count`. The execution count of an actor
increments after each time its <<gameactor,callback function>> has run once.
`a:get_count()`::
Returns the actor's execution count.
`a:reset_acount()`::
Resets the _action count_ of the actor to 0. The action count is incremented on
each frame advance of the actor's current action. Also see the
<<action_delay,`delay`>> argument to `con.action`.
`a:get_acount()`::
Returns the actor's action count.
`a:set_move(mov [, movflags])`::
Sets the move of actor `a` to `mov`, which may be either an object returned by
<<con_move,`con.move`>> or a number 0 or 1. See the <<gameactor_move,`move`>>
argument to `gameactor` for further details. If <<actor_MOVFLAGS,`movflags`>>
is omitted, it defaults to 0.
+
The `set_move` method resets the actor's execution count. Also, if `moveflags`
has bit <<actor_MOVFLAGS,`actor.MOVFLAGS.randomangle`>> set and the actor is
not an enemy or a live enemy, its `sprite[].ang` value is set to a ``random''
value using <<krand,`gv.krand`>>.
`a:has_move(mov)`::
Returns a boolean of whether the current move of actor `a` is `mov`, which can
be any value permissible to `a:set_move()`. Like with `a:has_action()`,
equality is established using the move ID in case a composite one is passed.
`a:set_hvel(hvel)`::
Overrides the <<con_move,horizontal velocity>> of the actor's current move to
`hvel` without changing its ID.
`a:set_vvel(vvel)`::
Overrides the <<con_move,vertical velocity>> of the actor's current move to
`vvel` without changing its ID.
`a:set_ai(ai)`::
Sets the AI of actor `a` to `ai`, which must be an object returned by
<<con_ai,`con.ai`>>. In addition to setting the current AI ID of the actor,
`a:set_ai(ai)` is equivalent to the sequence
+
[source]
----------
a:set_action(ai.act)
a:set_move(ai.mov, ai.movflags)
----------
`a:has_ai(ai)`::
Returns a boolean of whether the current AI of actor `a` is `ai`.
Various methods query whether the last movement step of the actor made it
collide with another object, or allow getting this object's index then.
`a:checkhit()`::
Returns a boolean of whether the actor hit any object in the world, including
ceilings and floors.
// TODO: This needs verification:
// Staying motionless on the ground is considered as ``hitting'' it, too.
`a:checkbump()`::
Returns a boolean of whether the actor bumped into another actor or a wall.
`a:hitwall()`::
If the actor hit a wall with the last movement, returns that wall's
index. Otherwise, returns *nil*.
`a:hitsprite()`::
If the actor hit a sprite with the last movement, returns that sprite's
index. Otherwise, returns *nil*.
// TODO: set_picnum, set_owner?
[[actor_static_functions]]
===== `actor` static functions
`actor.fall(i)`::
Causes the actor with index `i` to fall in a ``hard-coded'', not further
specified fashion.
[[actor_static_data]]
===== `actor` static data
[[actor_STAT]]
`actor.STAT`::
Provides a mapping of symbolic names to values applicable as sprite
<<sprite_statnum,status numbers>>. +
`DEFAULT`, `ACTOR`, `ZOMBIEACTOR`, `EFFECTOR`, `PROJECTILE`, `MISC`,
`STANDABLE`, `LOCATOR`, `ACTIVATOR`, `TRANSPORT`, `PLAYER`, `FX`, `FALLER`,
`DUMMYPLAYER`, `LIGHT`.
[[actor_FLAGS]] `actor.FLAGS`::
Contains symbolic names of values applicable to <<gameactor,`gameactor`>>'s
`flags` input argument, most of which are described there. +
`SHADOW`, `NVG`, `NOSHADE`, `NOPAL`, `NOEVENTS`, `NOLIGHT`,
`USEACTIVATOR`, `NOCLIP`, `SMOOTHMOVE`, `NOTELEPORT`, `NODAMAGEPUSH`.
//`BADGUY`,
[[actor_MOVFLAGS]] `actor.MOVFLAGS`::
Contains symbolic names of values applicable <<gameactor,`gameactor`>>'s
`movflags` input argument, `actor[]:set_move()`, and the like. +
* `faceplayer`, `geth`, `getv`, `randomangle`, `faceplayerslow`, `spin`,
`faceplayersmart`, `fleeenemy`, `seekplayer`, `furthestdir`,
`dodgebullet`, all naming single bits
* `jumptoplayer_bits`: the bitwise-OR of *two* bits, one of which is `faceplayer`
* `jumptoplayer_only`: the same as `jumptoplayer_bits`, but without the `faceplayer` bit set
* `jumptoplayer`: [red]*deprecated*
'''
[[player]]
===== `player`
Accessible with the index 0 and any nonnegative `pli` index passed to a
<<gameactor,game actor>> or event callback function.
.Arrays with named elements
The structures obtained by indexing `player` contain arrays whose elements may
be referred to either by index of by a particular name. Thus, the array can be
thought to be overlaid with a structure containing as many members as the array
has elements, all having the element's type.
Currently, there are with two kinds of names: weapon names and inventory
names. They will be marked using notation like this:
==========
_`i16`_ +ammo_amount[_weapon_]+
means that the structure member `ammo_amount` is an array with named elements,
themselves being of signed 16-bit integer type. The array can be indexed with
valid weapon numbers, or weapon names. In the following (constructed) example,
the first player's current pistol ammo count is set to that of the currently
selected weapon:
[source]
----------
local ps = player[0]
ps.ammo_amount.PISTOL = ps.ammo_amount[ps.curr_weapon]
----------
==========
The inventory names are the same as the keys of <<gv_GET,`gv.GET`>>, those for
the weapons coincide with the keys of <<gv_WEAPON,`gv.WEAPON`>>.
.Boolean members
Player members marked _`bool`_ in the listing below yield Lua true or false on
reading and expect one of these values when assigned to.
[[player_members]]
===== `player` members
<<vector_types,_`xmath.ivec3`_>> `vel`::
The vector of the player's current velocity, accounted each time a player's
input is processed. The x and y components are in BUILD x/y units per game tic,
scaled by 2^14^. The z component is given in BUILD z units per game
tic. Processing a player's input and other EDuke32 game code may change `vel`
``behind a user's back'' in a further unspecified fashion.
_`i32`_ `runspeed`::
The factor, scaled by 2^16^, with which the player's current horizontal
velocity is multiplied before calculating its new position. On various
occasions, the ultimate scaled factor is the difference of `runspeed` and at
most 8192.
`curr_weapon`::
The index of the player's currently selected weapon.
_`u16`_ `gotweapon`, {nbsp} _`bitfield`_ `gotweaponbits`::
Indicates whether each weapon is in the possession of the player. If bit 2^`w`^
is set for a <<gv_WEAPON,weapon index>> `w`, the player has got this
weapon. The player methods `has_weapon`, `give_weapon` and `take_weapon` can be
used to query or modify this member.
_`i16`_ +ammo_amount[_weapon_]+::
The current ammo amount for each weapon.
_`i16`_ +max_ammo_amount[_weapon_]+::
The maximum ammo amount for each weapon. Because `ammo_amount` amount and
`max_ammo_amount` are writable without restriction, it is the user's
responsibility to make sure that the former never exceeds the latter and that
both are non-negative at all times. Otherwise, erratic behavior may ensue.
_`bool`_ `jetpack_on`, {nbsp} `scuba_on`, {nbsp} `heat_on`::
Whether the player currently has the jetpack, scuba gear, or night vision
goggles activated, respectively.
[[player_methods]]
===== `player` methods
`ps:has_weapon(widx)`::
Returns a boolean of whether player `ps` has got the weapon with index `widx`.
`ps:give_weapon(widx)`::
Adds the weapon given by index `widx` to player `ps`'s possession without
changing the currently held one.
`ps:take_weapon(widx)`::
Removes the weapon given by index `widx` from player `ps`'s possession. If an
attempt is made to remove the currently selected weapon, the behavior is
undefined.
`ps:fadecol(fadefrac, r, g, b [, speed [, prio]])`::
Initiates a tinting that linearly fades over time and is blended with the whole
screen contents whenever player `ps`'s view is displayed.footnote:[The behavior
is unspecified should more than one player's view be displayed at one time.]
The first argument `fadefrac` specifies the starting blending coefficient; `r`,
`g` and `b` specify the intensities of the red, green and blue color
components, respectively.
+
Both `fadefrac` and the component intensities are first clamped to the range
[0.0 .. 1.0]. The resulting values are interpreted as a proportion, 0.0 meaning
no blending/no color and 1.0 meaning full blending/full
color.footnote:[Currently, for implementation reasons, a value of 1.0 results
in only _almost_ full blending or presence of the specified color component.]
+
The fourth, optional argument `speed` controls the rate at which the tinting
diminishes. At a value of `1` (the default), a tint with a `fadefrac` of 0.5
finishes in approximately one second.
+
The last, optional argument `prio` must be an integer in the range [`-128`
.. `127`], the default being `0`. When a `fadecol` is issued in the presence of
another tint fading in progress, and the `prio` given by the arriving `fadecol`
is greater or equal than the `prio` of the ongoing one, the latter is canceled
and the arriving fading is initiated in its place. (There is no support for
tint fades that overlap in time.)
+
[icon="din_w_crushing.png"]
CAUTION: If Lunatic code that uses `fadecol` is loaded together with CON code
that writes to the player's `pals` members directly at any point, the behavior
is undefined.
[[player_iterators]]
===== `player` iterators
+*for* i *in* player.all()+::
Iterates over the indices of all active players.
// ===== `projectile`
===== `g_tile`
An array of size `gv.MAXTILES`. Currently, access with numeric indices by the
user is [red]#disallowed# for `g_tile` and its elements have [red]#no public
members#.
===== `g_tile` static data
`g_tile.sizx`, {nbsp} `g_tile.sizy`::
Arrays indexable with tile numbers [`0` .. `gv.MAXTILES-1`] that hold the
horizontal and vertical texel sizes of each tile.
Lunatic functions
~~~~~~~~~~~~~~~~~
[[engine_iterators]]
Engine-side iterators
^^^^^^^^^^^^^^^^^^^^^
+*for* w *in* wallsofsect(sectnum)+::
Iterates over the indices of all walls of the sector with index `sectnum`.
+*for* s *in* spritesofstat(statnum [, maydelete])+::
Iterates over the indices of all sprites with status number `statnum`. If
`maydelete` is omitted or false, there must be no deletion of any sprite while
the loop is active. If `maydelete` is true, deleting sprites inside the loop is
allowed. Inserting sprites is always allowed.
+*for* s *in* spritesofsect(sectnum [, maydelete])+::
Iterates over the indices of all sprites contained in the sector with index
`sectnum` with the same meaning for `maydelete` as with `spritesofstat`.
[[sectorsofbunch_1]] +*for* s *in* sectorsofbunch(bunchnum, cf)+::
Iterates over the indices of the sectors whose ceiling's or floor's bunch
equals `bunchnum`, selected by passing `gv.CEILING` or `gv.FLOOR`
(respectively) to `cf`.
[[sectorsofbunch_2]] +*for* s, what *in* sectorsofbunch(bunchnum, gv.BOTH_CF)+::
Iterates over the indices of the sectors whose ceiling's and floor's bunch
equals `bunchnum`. On each iteration, `what` is one of the strings `'ceiling'`
or `'floor'`, denoting whether it's the ceiling or floor of sector `s` that has
the given bunch number.
Sector containment functions
^^^^^^^^^^^^^^^^^^^^^^^^^^^^
`inside(pos, sectnum)`::
Returns a boolean of whether the position `pos` (which can be anything
indexable with `x` and `y`) is considered inside the sector with number
`sectnum`, which must be valid. The `z` component is not taken into account.
===== Sector updating
A number of engine functions take a position `pos` and a starting sector number
`sectnum` and try to find a sector that contains `pos`, assuming it started out
in `sectnum`.footnote:[Note that this is different from CON's `updatesector`,
which takes the starting sector to be the one of the _current sprite_.]
If a valid sector numeric is passed for `sectnum`, these functions first check
whether that sector already contains `pos` (i.e. the position stays in the same
sector) and then attempt to search neighboring sectors. Unless breadth-first
search is requested (see below), if the passed `sectnum` is `-1`, all sectors
are searched in an unspecified order.
On success, these functions return the sector number of the ``updated'' sector,
otherwise `-1`.
[[updatesector]]
`updatesector(pos, sectnum [, flags])`::
Searches for a sector containing `pos`, which can be anything indexable with
`x` and `y`. Thus, the `z` component is not taken into account. If `sectnum` is
a valid sector number, first all its neighboring walls
(<<nextwall,`wall[].nextwall`>>, ``red wall links'') are searched, falling back
to a linear search on failure.
+
However, this strategy can be problematic if the position passes multiple thin
sectors that overlap another, potentially unrelated sector (for example, in a
TROR or sector-over-sector construction). If such a sector is passed without an
`updatesector` call ever made when it contains the position, the next call may
not find the real sector (as it is now two nextwall links away from the initial
one), and wrongly suggest the overlapping one instead.
+
For this reason, the optional argument `flags` accepts
<<sector_UPDATE_FLAGS,`sector.UPDATE_FLAGS.BREADTH`>>, instructing
`updatesector` to look for matching sectors in a _breadth-first_ search
starting from `sectnum`, and following all nextwall links. With this strategy,
there is *no* fallback to a linear search if no matching sector is found.
+
Passing `sector.UPDATE_FLAGS.Z` to `flags` makes the sector updating behave as
if `updatesectorz` was called. This is mainly useful if `updatesector` is
called via the <<sprite_updatesect,sector updating functions>> of sprites.
`updatesectorz(pos, sectnum)`::
Searches for a sector containing `pos`, which can be any value indexable with
`x`, `y` and `z`. Thus, it additionally takes the `z` component into account by
checking against the bounds that would be returned using a sector's
<<sec_cfz_at,`ceilingzat`/`floorzat`>> methods.
+
The `updatesectorz` function first checks the initial sector for containment of
`pos`, then it tries any TROR neighbors of `sectnum`. Finally, it proceeds like
`updatesector` as far as the searching order is concerned.
===== Collision detection and related functions
[[hitscan]]
`hitscan(pos, sectnum, ray, clipmask)`::
Starting from the position `pos` (which is assumed to be contained in
`sectnum`), the `hitscan` function determines the object that would be first
hit by a ray emanating from `pos` into the direction given by `ray`. Both `pos`
and `ray` may be any object indexable with `x`, `y` and `z`, but the components
are <<int_assignment,converted>> to signed 32-bit integers prior to being
passed to the actual engine function. Note that `ray` is interpreted in BUILD
scaling: the z component has 16 times the precision for a given game-world
length compared to x or y.
+
The `clipmask` argument determines what objects are considered being hittable
by the ray and is expected to be an integral number. It is interpreted as two
separate bit masks: the low 16 bits for walls and the high 16 bits for
sprites. Each time there is a potential collision, the respective mask is ANDed
with the `cstat` member of the object, and if the result is non-zero, the ray
is considered having hit the object.
+
The `hitscan` function returns an object with information about the hit object
(if any) as well as the position of its intersection with the ray. It contains
the following members:
+
* `sector`: The sector number of the hit object, or `-1` if no object was
hit. Thus, testing it for being greater or equal to zero is a quick way of
finding out whether any object (ceiling/floor, wall, or sprite) was hit at
all.footnote:[It is recommended to carry out this check for the sake of
cautiousness: while proper `hitscan` invocations should always hit something,
the function may come up empty in certain corner cases (such as a starting
position outside of the designated sector).]
* `wall`: If a wall was hit, its index. Otherwise, `-1`.
* `sprite`: If a sprite was hit, its index. Otherwise, `-1`.
* `pos`: The position that is the intersection of the emanated ray with the hit
object, indexable with `x`, `y` and `z`. Undefined if no object was hit.
//////////
cansee
hitscan
neartag
sectorsofbunch
//////////
Customizing the game
^^^^^^^^^^^^^^^^^^^^
In Lunatic, there are two main ways of customizing the game's behavior. Both
involve the user providing functions that are _called back_ at certain points
in the execution of EDuke32. Game _actors_ are simply sprites that run a
particular piece of code based on their tile number each game tic, unless they
are in a ``dormant'' state. Game _events_ are invoked at predetermined points
in the program flow.
To register custom actor and event code with the game (and define additional
actor information), Lunatic provides two functions in the global environment,
`gameactor` and `gameevent`. As their sole argument, they take a table
containing the appropriate data.
[[gameactor]]
===== The function `gameactor{tilenum [, ...], func}`
:Lua51_FunctionCalls: http://www.lua.org/manual/5.1/manual.html#2.5.8
Registers custom code for the actor given by tile number `tilenum`. For each
non-sleeping actor, the function `func` is called every game tic with three
input arguments: `func(aci, pli, dist)`.
* `aci`: the sprite number of the actor invoking `func`
* `pli`: the index of the player that is nearest to this actor
* `dist`: the 3D Manhattan distance
footnoteref:[mhdist_def,The Manhattan distance between points
_p_~1~=(x~1~&#44; y~1~&#44; z~1~) and _p_~2~=(x~2~&#44; y~2~&#44; z~2~) is
defined as abs(x~2~ -- x~1~) + abs(y~2~ -- y~1~) + abs(z~2~ -- z~1~).]
between actor `aci` and player `pli`
// NOTE: &#44; is the comma; the footnote would be truncated at it otherwise.
// For a related issue, see
// http://www.methods.co.nz/asciidoc/faq.html#_why_am_i_having_trouble_getting_nested_macros_to_work
Additionally, `gameactor` accepts optional input arguments. They can be
specified positionally by following `tilenum`, or be given as values to string
keys of the argument table. Each such input argument may be provided in at most
one of these two forms. Furthermore, `func` may be provided as value to the
key `'func'` as well.
[[gameactor_flags]]
`[2] flags`::
A number that controls both certain aspects of the `gameactor` call as well as
the run-time behavior of the actor itself. A couple of bits for the latter type
are listed in <<actor_FLAGS,`actor.FLAGS`>>, abbreviated `AF` in the following.
+
These values describe the ``type'' of the actor: `AF.enemy`, `AF.enemystayput`
and `AF.rotfixed`. Except for `enemystayput`, they name single bits
(`enemystayput` implies `enemy`).
+
In Lunatic, game actors can be _chained_, that is, a callback function can be
either appended to the end of an already registered one, or prefixed at its
front. In this case, a previous `gameactor` call must have taken place for that
actor (this may have happened from a CON `useractor` block, which gets
translated to `gameactor`). Moreover, this mechanism allows to add run-time
flags to the actor in question.
+
Chaining two callback functions is achieved by creating a new one that calls
the first one, followed by a {Lua51_FunctionCalls}[tail call] of the second
one. This has certain implications if control is transferred non-locally, for
example by using <<nlcf,`con.longjmp`>>.
+
Several flags in `AF` are provided to control how a `gameactor` invocation
handles chaining. In all cases, the actor tile flags are bitwise-ORed with the
existing ones.
+
* `AF.replace`: Replace the callback function. This is the way CON's
`useractor` behaves and is also the Lunatic default.
* `AF.replace_soft`: deprecated alias for `AF.replace`
* `AF.replace_hard`: [red]*deprecated*
* `AF.chain_beg`: Prepend the provided `func` to the existing callback function.
* `AF.chain_end`: Append the provided `func` to the existing callback function.
+
The following members all default to 0 if omitted.
+
`[3] strength`::
The initial strength or health of the actor.
`[4] action`::
The initial action of the actor. May be either an object returned by
<<con_action,`con.action`>>, or the numbers 0 or 1. Both represent actions with
that ID, but all public members set to 0.
[[gameactor_move]] `[5] move`::
The initial move of the actor. May be either an object returned by
<<con_move,`con.move`>>, or the numbers 0 or 1. Both represent moves with that
ID, but all public members set to 0. A move of 0 disables the usual actor
movement, even if its `hvel` or `vvel` subsequently get overridden (and the
corresponding `movflags` set).
`[6] movflags`::
The actor's initial movement flags. Applicable bits are available in the
<<actor_MOVFLAGS,`actor.MOVFLAGS`>> object.
===== The function `gameevent{evtlabel [, flags], func}`
:wiki: http://wiki.eduke32.com
:wiki_eventlist: http://wiki.eduke32.com/wiki/EDuke32_event_list
Registers custom code to be run at specific points in the program. The first
argument `evtlabel` should be a string naming the event. A complete
{wiki_eventlist}[list of events] can be found at the {wiki}[EDuke32 wiki]. The
label may be stripped of the leading ```EVENT_`'', so that e.g. `EVENT_JUMP`
and simply `JUMP` denote the same event.
The arguments `flags` and `func` can alternatively be passed as values to the
same-named keys of the input argument table to `gameevent`. Like with
`gameactor`, each may be provided in at most one of the two forms.
The callback `func` is invoked with the same arguments and meaning as for
<<gameactor,`gameactor`>>, but certain events are run in contexts where no
meaningful `aci` and/or `pli` value can be assigned. In this case, `func`
receives `-1` for the respective input arguments.
Like with actors, game events may be chained or replaced by passing an
appropriate `flags` value. However, it is not necessary for an event to be
already defined when chaining is requested. In that case, it is simply
registered initially. Permissible values for these flags are provided in
`actor.FLAGS` as well (abbreviated `AF` here):
* `AF.replace`: Replace any previously defined event code with the given one.
* `AF.chain_beg`: Prepend the provided `func` to the existing callback
function. This is the behavior of CON's `onevent`.
* `AF.chain_end`: Append the provided `func` to the existing callback
function. This is the default.
// TODO: RETURN handling...
[[ext_api]]
Extended API (Lunatic modules)
------------------------------
The `xmath` module
~~~~~~~~~~~~~~~~~~
Mathematical functions
^^^^^^^^^^^^^^^^^^^^^^
:BitOpUndefined: http://bitop.luajit.org/semantics.html#undefined
Lunatic, being a Lua-based scripting system, provides the user with a single
numeric data type that variables can contain on the Lua side --
double-precision floating point.footnote:[In LuaJIT, variables additionally can
take on ``boxed'' 64-bit integer numeric types, but these should not be used
for numeric calculations.] However, since BUILD, and in turn, EDuke32, almost
exclusively use integer types to represent quantities such as angles or carry
out e.g. trigonometrical calculations, there is a need for convenient
interoperability between the two ``worlds''.
Two pairs of functions calculate the trigonometric sine and cosine, both
accepting a BUILD angle as input argument, but differing in the scaling of
their result. Using these functions is recommended over Lua's `math.sin` or
`math.cos` in cases where the argument is a BUILD angle in the first place, for
example because it is read from an engine or game structure. The computation is
both faster (because it is essentially only a bitwise-AND operation followed by
a table lookup) and the results have the symmetry expected from the
mathematical counterparts.
`xmath.sinb(bang)`, {nbsp} `xmath.cosb(bang)`::
Returns the sine/cosine of the given BUILD angle `bang`, which can be any whole
number in [--2^31^{nbsp}..{nbsp}2^31^--1].footnote:[Passing fractional values
is possible, but discouraged. See the relevant {BitOpUndefined}[subsection] of
the BitOp documentation for more details.] In BUILD, one full cycle is covered
by values from 0 to 2047; in other words, an angle of 2048 corresponds to 360
degrees.
+
The `sinb` and `cosb` functions return values in the range [--1 .. 1], just
like their mathematical counterparts.
+
The following guarantees are made for `sinb` whenever its argument expression
is permissible:
+
* `sinb(-a) == -sinb(a)` (point symmetry around the origin)
* `sinb(a + i*2048) == sinb(a)`, where `i` is any whole number (periodicity)
* `sinb(1024 - a) == sinb(a)` (mirror symmetry around `a`=512)
* `sinb(a - 1024) == -sinb(a)` (point symmetry around `a`=1024)
* The value for `cosb(a)` is derived as `sinb(a + 512)`.
`xmath.ksin(bang)`, {nbsp} `xmath.kcos(bang)`::
Returns the sine/cosine of the given BUILD angle `bang`, multiplied with 16384
and rounded towards zero. The same guarantees as for the `sinb`/`cosb` pair
apply.
`xmath.angvec(ang)`::
Returns a <<vector_types,`vec3`>> with the components `math.cos(ang)`,
`math.sin(ang)` and 0 for x, y and z, respectively.
`xmath.bangvec(bang)`::
Returns a <<vector_types,`vec3`>> with the components `xmath.cosb(bang)`,
`xmath.sinb(bang)` and 0 for x, y and z, respectively.
`xmath.kangvec(bang [, z])`::
Returns an <<vector_types,`ivec3`>> with the components `xmath.kcos(bang)`,
`xmath.ksin(bang)` for x and y, respectively. The z component can be passed in
the optional argument `z`, which defaults to 0 if omitted.
`xmath.dist(pos1, pos2)`::
Returns an approximation of the 3D Euclidean distance between points `pos1` and
`pos2`, both of which can be any object indexable with `x`, `y` and `z`.
<<cf_z,BUILD z units>> are assumed.
`xmath.ldist(pos1, pos2)`::
Returns an approximation of the 2D Euclidean distance between points `pos1` and
`pos2`, both of which can be any object indexable with `x` and `y`.
[[xmath_rotate]] `xmath.rotate(point, bang [, pivot])`::
Returns as an <<vector_types,`xmath.vec3`>> the position of `point` rotated
around the line parallel to the z axis going through `pivot` by `bang` BUILD
angle units in the mathematically negative (clockwise) direction. The arguments
`point` and `pivot` can be anything indexable with `x`, `y` and `z`. The z
component of the result is the difference between that of `point` and
`pivot`. If `pivot` is omitted, it defaults to the origin vector containing
zeros for all components.
[[vector_types]]
The types `xmath.vec3` and `xmath.ivec3` [_serializable_]
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Another purpose of the `xmath` module is to provide _vector_ types that allow
writing concise and clear code involving geometrical calculations. There are
two types, both containing three components (`x`, `y` and `z`), but differing
in their numeric type. For the most part, `vec3` should be used, whose
components are Lua numbers, i.e. floating point. The other type, `ivec3`, is
part of some game structures, and consequently uses 32-bit integers for its
components. With minor differences, the `vec3` and `ivec3` types share the same
operations and methods.
The constructors of the vector types can be called in several ways. In the
following, they are only described for `vec3`. The conventions for `ivec3` are
completely analogous, but since their creation involves a number type
conversion, the rules about <<int_assignment,assignment to integer types>>
apply.
`v = xmath.vec3([x [, y [, z]]])`::
Create a 3-element vector `v` by passing the `x`, `y` and `z` components
separately. Trailing components can be omitted, in which case they are
initialized to 0.
`v = xmath.vec3(t)`::
Create a 3-element vector `v` by passing `t`, which can be any variable
indexable with the strings `x`, `y` and `z` (and yielding numbers for these
lookups). For example, `t` can be another (`i`)`vec3`, a `sprite` or even
<<wall,`wall`>> reference, as each of them can be indexed with these three
keys.
Since the vector types are compound objects, they are always passed around by
reference. For example, consider executing
[source]
----------
v = xmath.vec3(0, 10)
w = v
w.y = 20
----------
After this code, the expression `v.y` yields 20 instead of the initial value
10.
===== Operations for `vec3` and `ivec3`
In the following, `v` denotes a `vec3` or `ivec3` object reference while `t`
denotes any object indexable with `x`, `y` and `z`. Note that for binary
operations, Lua looks for overridden operators in the left operand first and
the right one next. So, where `t` appears on the left hand side of an
arithmetic expression, it is assumed that `t`'s type does not overload the
corresponding operation or provides the same semantics. Arithmetic operations
always return a (reference to a) new `vec3` object, even if any or both of the
operands have `ivec3` type.
`v + t`, {nbsp} `t + v`::
Returns a new `vec3` object whose components are the sum of the respective
components of `v` and `t`.
`v - t`, {nbsp} `t - v`::
Returns a new `vec3` object whose components are the difference of the
respective components of `v` and `t` (in the first case) or `t` and `v` (in the
second case).
`-v`::
Returns a new `vec3` object with the components of `v` negated.
`a*v`, {nbsp} `v*a`::
For a scalar number `a`, returns a new `vec3` object whose components are those
of `v` multiplied with `a`.
`v/a`::
For a scalar number `a`, returns a new `vec3` object whose components are those
of `v` divided by `a`.
`v^zofs`::
Returns an object of the same type as `v` and with the same components, except
that `v.z` is diminished by `zofs`. Also see the <<sprite_power,power
operation>> for `sprite` objects.
`tostring(v)`::
Returns a string representation of `v` for display purposes: ```vec3`'' or
```ivec3`'', followed by the components of `v` in parentheses.
===== Methods for `vec3` and `ivec3`
`v:len()`::
Returns the Euclidean length of `v` in three dimensions.
`v:lensq()`::
Returns the squared Euclidean length of `v` in three dimensions.
`v:len2()`::
Returns the Euclidean length of `v`, taking only the `x` and `y` components
into account.
`v:len2sq()`::
Returns the squared Euclidean length of `v`, taking only the `x` and `y`
components into account.
`v:mhlen()`::
Returns the length of `v` calculated using the Manhattan distance
footnoteref:[mhdist_def] in three dimensions between the origin and the
endpoint.
`v:toivec3()`::
Returns a new `ivec3` object with the same components as `v`, but converted
<<int_assignment,to integers>>.
`v:touniform()`::
Returns a new vector of the same type as `v` which has the same `x` and `y`
components as `v`, but the `z` element divided by 16 (if `v` is a `vec3`) or
arithmetically right-shifted by 4 (if `v` is an
`ivec3`).footnote:[Right-shifting by 4 can be seen as a division by 16 with
subsequent rounding to an integer towards negative infinity.] Also see the
description of the ceiling/floor <<cf_z,`z` member>>.
`v:tobuild()`::
Returns a new vector of the same type as `v` which has the same `x` and `y`
components as `v`, but the `z` element multiplied with 16.
`v:rotate(bang [, pivot])`::
Equivalent to +<<xmath_rotate,xmath.rotate>>(v, bang [, pivot])+.
The `con` module -- game control
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The `con` module on one hand provides functionality to control certain aspects
of the game, such as defining game-side animations for actors. On the other
hand, it hosts various functions that are familiar from CON, although sometimes
under a different name.
[[actions_moves_ais]]
Actions, moves and AIs -- customizing actor behavior
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
In CON, three aspects of an actor can changed using a mechanism that is
syntactically similar for each. _Actions_ carry information about a particular
animation for an actor, such as how many frames it contains. _Moves_ define the
potential motion characteristics of an actor. Finally, _AIs_ are aggregates of
an action and a move, plus _movement flags_ that toggle certain movement
aspects.
At file scope, one first defines each of these composites using directives such
as `action`, and inside code blocks to be executed at game time, one instructs
the game to use a particular composite by passing the chosen label to the
same-named command (i.e. `action` for our example).
Lunatic provides a similar mechanism, but the main difference from CON is that
the definition functions merely return the composite structures, without
registering them under any particular name. Thus, it is up to the user to
organize them, for example by storing those for each class in a separate table
indexed by chosen names. Similar to CON, the creation functions may only be
called when the game is not yet running.
Actor behavior composites contain an additional ``hidden'' ID. Each invocation
of a creation function such as `con.action` returns a composite with a unique
ID per composite type. This ID is used to compare for equality in actor methods
such as `actor[]:has_action()`. All returned composites are immutable.
[[con_action]]
===== The function `con.action{ ... }`
:wiki_action: http://wiki.eduke32.com/wiki/Action
:Lua51_TableConstructors: http://www.lua.org/manual/5.1/manual.html#2.5.7
Returns a new _action_ composite created with the given values. The
`con.action` function expects a single table as input argument, each of whose
keys denote an action member. Each member may be provided by an index in the
table or its name, but not both. Members may be omitted, in which case they
default to either 0 or 1.
Refer to the {Lua51_TableConstructors}[Table Constructors] subsection of the
Lua 5.1 Reference Manual for the syntax and semantics of table initialization.
`[1] startframe`::
The offset of the starting frame of the animation, relative to the
`sprite[].picnum` of an actor (i.e. the tile number, selecting which actor code
is run).
`[2] numframes` (default: 1)::
The total number of frames in the animation.
`[3] viewtype` (default: 1)::
The number of consecutive tiles used to construct one frame of the animation,
as viewed from different angles. Valid values are 1, 3, 5, 7 and 8. In
addition, -5 and -7 are allowed, which behave like the corresponding positive
++viewtype++s, but effectively mirror the actor around the vertical axis. This
can be useful if tile data is available that has the opposite orientation of
what EDuke32 uses. See the {wiki_action}[Action entry] in the EDuke32 wiki for
how the views are constructed for different `viewtype` values.
`[4] incval` (default: 1)::
The value to add the actor's _current frame_ on each frame advance. May be --1,
0, or 1.
// In the wild, sometimes other values, too.
[[action_delay]] `[5] delay`::
Roughly, the number of <<totalclock,`gv.totalclock`>> time units (120 per
second) after which a frame is advanced, at a granularity of one game tic (30
per second, corresponding to a `delay` difference of 4).footnote:[The reason
for the granularity is due to the implementation: each execution of an actor's
code increments its hidden ``action tics'' counter by four (= 120/30).]
// TODO: the above can be more precise. State in terms of floor(delay/4).
.Equivalent `action` definitions
==========
Each of the following calls return an action with the same public members:
[source]
----------
con.action{0, 4, delay=20}
con.action{0, 4, 1, 1, 20}
con.action{startframe=0, numframes=4, viewtype=1, incval=1, delay=20}
----------
==========
[[con_move]]
===== The function `con.move{ ... }`
Returns a new _move_ composite created with the given values, expecting a
single table as input argument. The same conventions as with `con.action` apply
for the following members:
`[1] hvel`::
The (most often) doubled horizontal velocity of the actor, in BUILD x/y units
per game tic. An actor's `sprite[].xvel` will approach this value in an
``exponential'' fashion, halving the difference between the current velocity
and this goal velocity each movement update from the actor execution loop. For
most objects, `sprite[].xvel` is then further halved to yield the ultimate
velocity. Only effective when the actor's `movflags` has
<<actor_MOVFLAGS,`actor.MOVFLAGS.geth`>> is set.
`[2] vvel`::
The (most often) doubled horizontal velocity of the actor, in BUILD x/y (*not*
z) units per game tic. An actor's `sprite[].zvel` will approach 16 times this
value in an ``exponential'' fashion. For most objects, `sprite[].zvel` is then
further halved to yield the ultimate velocity. Only effective when the actor's
`movflags` has <<actor_MOVFLAGS,`actor.MOVFLAGS.getv`>> is set.
[[con_ai]]
===== The function `con.ai([action [, move [, movflags]]])`
The `con.ai` function differs from `con.action` and `con.move` in that it is of
``second order'', i.e. it accepts two composites as input arguments, returning
an _AI_ object containing these. Also, it is called with three positional,
optional arguments. Like for <<gameactor,`gameactor`>>, the numbers 0 and 1 are
permissible for `action` and `move`. Applicable bits for `movflags` are
available in the <<actor_MOVFLAGS,`actor.MOVFLAGS`>> object.
[[nlcf]]
Non-local control flow
^^^^^^^^^^^^^^^^^^^^^^
Two functions in the `con` module make the executed function abort early,
jumping directly to the end of the innermost event or actor callback
``block''. They are used to implement among others CON's `killit` and
(confusingly named) `return` commands. If these functions are used when none of
the mentioned callback functions are active, the behavior is undefined.
`con.longjmp()`::
Silently transfers control to the end of the innermost actor or event callback
block, to the same point an `error()` call would do. Note that since callback
<<gameactor_flags,chaining>> is achieved by creating a new function for each
function pair, calling both unprotected, issuing a `con.longjmp()` inside any
``part'' of a chain aborts the whole block -- functions in the chain that are
called later will not be reached. In contrast, returning from one function
transfers control to the beginning of the next in the chain if it exists.
+
.`con.longjmp` with chained events
==========
The following two chained `EVENT_JUMP` definitions,
[source]
----------
gameevent{"JUMP", function(_, pli)
print("jump:first")
if (player[pli].curr_weapon==gv.WEAPON.PISTOL) then
return
end
print("aborting")
con.longjmp()
end}
gameevent{"JUMP", function() -- second function in EVENT_JUMP chain
print("jump:second")
end}
----------
would print ```jump:first`'' and ```jump:second`'' when holding a
pistol. Otherwise, ```jump:first`'' and ```aborting`'' would be printed and the
second chained callback function would not be reached.
==========
`con.killit()`::
Silently transfers control to the end of the active actor callback block,
notifying the game to delete the executing actor's sprite. If `con.killit` is
called while no execution of actor code is active, the behavior is undefined.
Per-actor variables
^^^^^^^^^^^^^^^^^^^
// XXX: this text is too implementation-centric
Since in EDuke32, sprites in general exist in the world only for a limited
duration, it is wasteful to allocate an array of fixed size `gv.MAXSPRITES` for
the purpose of a variable that holds a value for each actor sprite. On the Lua
side, one could use a plain table, but for actors that are created and
destroyed during the course of a game, this would accumulate ``garbage'' --
values for sprites that have been deleted. Moreover, per-actor variables tend
to be ``topical'', one such variable being potentially only used for a very
specific actor tile. For this reason, per-actor variables are implemented in a
``sparse'' fashion in Lunatic, but provide to the user the illusion of having a
value for every sprite index. They are also ``cleaned'' at unspecified
intervals.
[[con_actorvar]]
===== The type `con.actorvar(defaultval)` [_serializable_]
Creates and returns a new per-actor variable with default value `defaultval`
which can be indexed for reading or assignment in the range
[0{nbsp}..{nbsp}`gv.MAXSPRITES-1`], but access to it is subject to the same
restrictions as to <<sprite,`sprite`>> and other per-sprite structures.
When a sprite is created using `con.insertsprite` or `con.spawn`, its value at
the index of this new sprite is cleared (reset to `defaultval`). After a sprite
has been deleted, the value of a per-actor variable is indeterminate -- it may
be cleared by Lunatic at any point.
Per-actor variables may contain values of any permitted type, which currently
are boolean and number. Mixing values of different types is allowed: per-actor
variables are heterogenous containers.
Sprite insertion
^^^^^^^^^^^^^^^^
In Lunatic, there are two functions that insert a sprite into the game world.
They mainly differ in how they are used, and to which extent they imply
``hard-coded'' behavior.
===== The function `con.insertsprite{tilenum, pos, sectnum [, statnum [, owner]] [key=val...]}`
Inserts a new sprite into the game with the properties given as input
arguments. If the world already contains the maximum number of sprites
(<<gv,`gv.MAXSPRITES`>>), currently the game is aborted and EDuke32
exits.footnote:[This is subject to change and must not be relied on.]
Otherwise, relevant per-sprite data for the newly inserted sprite is
cleared. No additional ``hard-wired'' C code is run.
Returns the index of the inserted sprite.
The function `con.insertsprite` can be used in one of two forms:
* In the `table-call` form specified above, a single table is passed whose
values are taken as the actual arguments. The first three, `tilenum`, `pos` and
`sectnum`, are passed positionally. All other input arguments are passed as
key-value pairs, but `owner` and `statnum` may be provided either positionally
or as key/value pair.
* Passing only the three to five positional arguments is also directly
possible. For example, all of the following calls are equivalent:
+
[source]
----------
local i = con.insertsprite(tile, pos, sect, stat, ow) -- direct-call
local i = con.insertsprite{tile, pos, sect, stat, ow} -- table-call
local i = con.insertsprite{tile, pos, sect, statnum=stat, owner=ow} -- table-call with 2 k/v args
local i = con.insertsprite{tile, pos, sect, stat, owner=ow} -- table-call with one k/v arg
----------
The five main arguments are as follows:
`[1]` (`tilenum`)::
The tile number of the sprite to insert.
`[2]` (`pos`)::
The position at which to insert the sprite (anything indexable with `x`, `y` and `z`).
`[3]` (`sectnum`)::
The index of the sector in which to insert the sprite.
`[4] statnum` (default: `actor.STAT.DEFAULT`)::
The initial status number of the inserted sprite.
`[5] owner` (default: see below)::
The index of the sprite that is in some sense the ``parent'' of the newly
created one. If omitted, it is set to the index of the newly spawned sprite.
These keys are permissible as optional input arguments in the table-call form,
corresponding to the same-named <<sprite,`sprite`>> members:
* `shade`, `ang`, `xvel`, `zvel` (default: 0)
* `xrepeat` and `yrepeat` (default: 48)
===== The function `con.spawn(tilenum, parentspritenum)`
Spawns a new sprite with tile number `tilenum` from a given ``parent'' sprite
with index `parentspritenum`, which must be valid. The sprite is spawned at the
same position as its parent and its `owner` member is set to
`parentspritenum`. Additional ``hard-wired'' code dependent on `tilenum` may be
run afterwards, possibly modifying the sprite.
Returns the index of the spawned sprite on success.
===== The function `con.shoot(tilenum, parentspritenum [, zvel])`
Attempts to shoot a projectile with tile number `tilenum` from the sprite with
index `parentspritenum`. The z velocity can be overridden by passing `zvel`.
// TODO: document how zvel is interpreted
Returns the index of the spawned sprite on success, or --1 otherwise.
The `engine` module
~~~~~~~~~~~~~~~~~~~
Base palette interfaces
^^^^^^^^^^^^^^^^^^^^^^^
The 8-bit (``classic'') Build renderer operates in indexed-color mode: the
pixels of the frame buffer do not contain red/green/blue values themselves, but
only indexes into a color table with 256 entries, the _base palette_.
**********
latexmath:[$\mathrm{ColorComponent} := \mathbb{N}_{64}$] {nbsp}
[gray]#// Build's base palettes have 6 bits of precision per color component# +
latexmath:[$\mathrm{ColorIndex} := \mathbb{N}_{256}$] +
latexmath:[$\mathrm{basepal}: \: \mathrm{ColorIndex} \rightarrow \mathrm{ColorComponent}^3$] +
**********
The following functions provide a bridge between color indices and their
corresponding color components.
`r, g, b = engine.getrgb(i)`::
Returns the red, green and blue color components of the default base palette
for color index `i`. The color components are in the range [0 .. 63].
+
If `i` is 255, `r`, `g` and `b` are all returned as 0, even if the actual base
palette may contain different values for that index.
`i = engine.nearcolor(r, g, b [, lastokcol])`::
Given the red, green and blue components `r`, `g` and `b` of a query color,
returns the color index `i` whose color in the default base palette is closest
to the query color. ``Closeness'' is established using an Euclidean distance
with a weighting on the color components.
+
The optional argument `lastokcol` can be used to restrict the range of color
indices to search: the returned color index is guaranteed to be in the range
[0{nbsp}..{nbsp}`lastokcol`]. It defaults 255, so that all colors are
searched.footnote:[For example, it may be desirable to omit ``fullbright''
colors from being returned. The shade table loaded from Duke3D's PALETTE.DAT
makes color indices 240--254 fullbright, so passing 239 to `lastokcol` achieves
the mentioned filtering.]
[[shade_table_interfaces]]
Shade table interfaces
^^^^^^^^^^^^^^^^^^^^^^
To implement shading and visibility attenuation, Build maintains tables mapping
pairs of a color index and a shade level (Duke3D's table uses 32 such
gradients) to a color index representing the darkness-faded color. Each such
table is called shade or _palookup_ table.
**********
latexmath:[$\mathrm{ShadeLevel} := \mathbb{N}_{\mathrm{Numshades}}$] +
latexmath:[$\mathrm{palookup}: \: \mathrm{ShadeLevel} \times
\mathrm{ColorIndex} \rightarrow \mathrm{ColorIndex}$]
**********
When a pixel is about to be drawn, a palookup table chosen depending on the
object's `pal` is consulted to determine its ultimate color index (in the
absence of blending with the translucency table or see-through texels). Given a
texel's color index as latexmath:[$i_{\mathrm{in}}$], the resulting pixel's one
latexmath:[$i_{\mathrm{out}}$] is computed as
==========
latexmath:[$s_1 = \mathrm{shade} + C \cdot \mathrm{visdist}$] +
latexmath:[$s_2 = \mathrm{clamp}(s_1, \: 0, \: \mathrm{Numshades}-1)$] +
latexmath:[$\mathrm{shade_index} = \mathrm{round}(s_2)$] +
latexmath:[$i_{\mathrm{out}} = \mathrm{palookup}(\mathrm{shade_index}, i_{\mathrm{in}})$] {nbsp}
[gray]#// This is only a table lookup, palookup[shade_index][latexmath:[$i_{\mathrm{in}}$]]# +
==========
Here, latexmath:[$C$] is a positive constant and
latexmath:[$\mathrm{visdist}$] is the product of a. the distance of an object's
sampled pixel to the view plane with b. the object's
``visibility''.footnote:[Visibility would be more appropriately called
``anti-visibility'' or ``co-visibility'': greater values make objects appear
more faded for the same distance. Also, the visibility that is meant here has
the origin at 0, unlike `sector[].visibility`.] Thus, shade and visibility are
inherently confounded in the 8-bit mode and the ultimate shade_index is bounded
below by (the minimum of latexmath:[$\mathrm{Numshades}-1$] and) the shade of
the object.
===== Examples of effects using shade tables
While palookup tables are primarily used for shading and visibility
attenuation, they can be set up in other ways to yield different effects with
respect to how pixels of objects farther away are drawn. For example:
* Distance fading with fog. For a fog color latexmath:[$\mathbf{c} = (c_r, c_g,
c_b)$], the table is set up so that for a source color index latexmath:[$i$]
and a shade level sh, palookup[sh][latexmath:[$i$]] contains a color index
whose color is close to that of latexmath:[$i$] blended with
latexmath:[$\mathbf{c}$], +
+
{nbsp} latexmath:[$\frac{\mathrm{sh} + 0.5}{\mathrm{Numshades}} \cdot
\mathrm{basepal}(i) +
\frac{\mathrm{Numshades}-\mathrm{sh}+0.5}{\mathrm{Numshades}} \cdot
\mathbf{c}$]. +
+
Note that distance fading to black can be seen as a special case of this
fogging effect. However, Duke3D's base shade table (i.e. the table for pal
0) is *not* constructed in this way.
* Color index remapping. Given a mapping latexmath:[$m: \: \mathrm{ColorIndex}
\rightarrow \mathrm{ColorIndex}$], the table is set up so that for each shade
level sh, the 256 color indices are selected or reordered in the same way:
for all color indices latexmath:[$i$],
palookup[sh][latexmath:[$i$]]{nbsp}={nbsp}original_palookup[sh][latexmath:[$m(i)$]]. +
For example, pal 21 remaps the fifth and sixth blocks of consecutive
16-tuples of color indices (a ramp of blue colors) to the fourth and 14^th^
such blocks (red colors, the first one part of a 32-color ramp).
* ``Fullbright'' colors -- those that aren't affected by distance -- with index
latexmath:[$i$] are achieved by setting palookup[sh][latexmath:[$i$]] to
palookup[0][latexmath:[$i$]] for each shade sh.
===== Shade table functions
`sht = engine.shadetab()`::
Creates and returns a new shade table object `sht` with all entries initialized
to zero. This object can be indexed once with a shade index from 0 to 31,
yielding a reference to an array of 256 8-bit unsigned integers. Thus, shade
table objects can be used just as indicated in the notation above: `sht[sh][i]`
is the resulting color index for shade `sh` and input color index `i`.
`sht = engine.getshadetab(palnum)`::
Returns a new shade table object `sht` containing the values for the palookup
table of pal `palnum`, provided it is not an alias for the default one (see
below). Modifying the returned `sht` does not alter the actual engine-side
shade table. An unspecified number of pal indices are reserved from the end of
the hard limit 255; attempting to retrieve a shade table for a reserved pal
raises as error.
+
At engine initialization, the shade tables for all non-zero pal numbers are
aliased to the default pal 0 one. Subsequently, custom palookup tables are
either loaded from LOOKUP.DAT, created by appropriate DEF directives (`fogpal`
or `makepalookup`), or assigned using `engine.setshadetab`. If the table for
pal `palnum` is aliased to the default one when `getshadetab` is called, *nil*
is returned.
[[engine_setshadetab]] `engine.setshadetab(palnum, sht)`::
Copies the shade table `sht` to the engine-side palookup table for pal
`palnum`. An error is issued if an attempt is made to copy to a reserved
`palnum`.
+
When running in EDuke32, there are additional restrictions:
+
* A `palnum` for which a shade table has already been registered (that is, one
which is *not* aliased to the default one) cannot be re-assigned to.
+
* `setshadetab` may only be called at first initialization time, that is, when
the value of `LUNATIC_FIRST_TIME` is *true*. (`LUNATIC_FIRST_TIME` is a
variable in the global environment that indicates whether the Lua game state
is created for the very first time and the game is not yet running.)
===== Shade table methods
`newsht = sht:remap16(tab)`::
Returns a new shade table with consecutive runs of 16 values of every 256-tuple
of `sht` remapped as specified by `tab`. Specifically, `tab` must be a table
whose keys in [0 .. 15] may be set to values in [0 .. 15]. For a shade index
`sh` and a color index `i`, the returned shade table `newsht` then has
+
==========
`newsht[sh][i]` = `sht[sh][newi]`,
==========
+
where
+
==========
`newi` = `16*tab[math.floor(i/16)] + i%16` {nbsp} [gray]#// if `tab[math.floor(i/16)]` is non-*nil*# +
`newi` = `i` {nbsp} [gray]#// otherwise#
==========
+
.Example
[source]
----------
-- Creates a shade table with the same remapping as pal 21 (blue -> red) and
-- registers it under pal 22, overwriting its previous contents.
local newsht = engine.getshadetab(0):remap16({[4]=13, [5]=8})
engine.setshadetab(22, newsht)
----------
[[blending_table_interfaces]]
Blending table interfaces
^^^^^^^^^^^^^^^^^^^^^^^^^
EDuke32 supports installing multiple blending tables used by the 8-bit
renderer. A blending (or translucency) table is used whenever an object with
the ``translucent'' bit set is drawn, and maps pairs of color indices to a
blended color index.
**********
latexmath:[$\mathrm{transluc}: \: \mathrm{ColorIndex} \times
\mathrm{ColorIndex} \rightarrow \mathrm{ColorIndex}$]
**********
Given a background color index `bi` and a color index of an incoming foreground
fragment `fi` (usually obtained by looking up a shade table), when `fi` is
different from 255, the resulting color index is
==========
`transluc[bi][fi]`
==========
if the ``reverse translucency'' bit is clear, and
==========
`transluc[fi][bi]`
==========
if reverse tranlucency is set. If the fragment sampled from the foreground
object has color index 255, it is discarded: translucent rendering is always
``masking''.
Currently, only sprites support rendering with custom blending tables, by
setting their `.blend` member to the number of a blending table.
===== Blending table functions
`tab = engine.blendtab()`::
Creates and returns a new blending table object `tab` with all entries initialized
to zero. This object can be indexed once with a color index from 0 to 255,
yielding a reference to an array of 256 8-bit unsigned integers. Thus, blending
table objects can be used just as indicated in the notation above: `tab[i][j]`
is the blended color index for input color indices `i` and `j`.
`tab = engine.getblendtab(blendnum)`::
Returns a new blending table object `tab` containing the values for the
engine-side translucency table numbered `blendnum`, or *nil* if no blending
table with that number is registered. Modifying the returned `tab` does not
alter the actual engine-side blending table.
//+
//At engine initialization, the default translucency table (with number 0) is
//loaded from PALETTE.DAT.
`engine.setblendtab(blendnum, tab)`::
Copies the blending table `tab` to the engine-side translucency table with
number `blendnum`.
+
Similar to <<engine_setshadetab,`engine.setshadetab`>>, there are certain
restrictions when running in EDuke32:
+
* A `blendnum` for which a table has already been registered cannot be
re-assigned to.
+
* `setblendtab` may only be called at first initialization time, that is, when
the value of `LUNATIC_FIRST_TIME` is *true*.
Mapster32-only functions
^^^^^^^^^^^^^^^^^^^^^^^^
===== `engine.savePaletteDat(filename [, palnum [, blendnum [, moreblends]]])` -> `ok, errmsg`
Writes out a full PALETTE.DAT-formatted file named `filename` with the base
shade table numbered `palnum` and the base translucency table numbered
`blendnum`, both defaulting to 0.
Passing `moreblends` allows to specify additional blending tables to store in
EDuke32's extended PALETTE.DAT format. These must have previously been
registered with `engine.setblendtab`. The `moreblends` argument must be a
sequence table with each element being either
* a blending table number in the range [1{nbsp}..{nbsp}255]
* a table `t` containing a pair of such numbers, in which case it is taken to
mean the inclusive range [`t[1]`{nbsp}..{nbsp}`t[2]`]
There must be no duplicate blending table numbers.
The function returns a status `ok` which is *true* on success and *nil* on
failure. In the latter case, `errmsg` is a diagnostic error message.
===== `engine.saveLookupDat(filename, lookups)` -> `ok, errmsg`
Writes out a LOOKUP.DAT-formatted file named `filename` with the lookup tables
specified by `lookups` at the beginning and the five additional base palettes
at the end.
The `lookups` argument is interpreted analogously to the `moreblends` argument
of `engine.savePaletteDat` (with the numbers being palookup numbers instead of
blending table numbers) and the return values `ok` and `errmsg` have the same
meaning as well.
The `fs` module -- virtual file system facilities
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
[float]
==== `files = fs.listpath(path, mask)`
Returns a sequence table `files` of file names that can be found in a directory
constructed as concatenation of any directory in the search path with `path`,
and matching the wildcard `mask`. Currently, neither ZIP nor GRP files
registered as file containers with EDuke32 are searched.
The `path` argument must separate directories by forward slashes (`/`). If no
suffix is desired (i.e. the directories in the search path themselves are to be
searched), `'/'` should be passed.
The file name `mask` is applied case-insensitively for the 26 characters of the
basic Latin alphabet. It may contain the following meta-characters which are
interpreted in a special way:
* a `*` matches any (potentially empty) sequence of characters
* a `?` matches any single character
While the match with `mask` proceeds case-insensitively, file names are
returned named exactly like on the file system. However, names differing only
in case appear exactly once in the output list.
NOTE: For portability, it is crucial that `path` is specified with the same
case as the actual directory on the file system.
.Example
Suppose the search path contains two directories `foo` and `bar` with the
following file listing:
----------
foo/
myhouse1.MAP
myhouse2.map
bar/
MYHOUSE1.map
MYHOUSE10.MAP
README.txt
----------
Then a query with
[source]
----------
fs.listpath("/", "myhouse?.map")
----------
will return a table with
these strings:
* `myhouse1.MAP` or `MYHOUSE1.map`, but not both
* `myhouse2.map`
/////////////////
APPENDICES FOLLOW
/////////////////
:numbered!:
[appendix]
[[Appendix_Howto_read_PIL]]
How to read _Programming in Lua_
--------------------------------
:PiL50: http://www.lua.org/pil/contents.html
On the Lua homepage, the first edition of _Programming in Lua_ is
{PiL50}[available] online. While targeting Lua 5.0, it still remains applicable
to Lua 5.1 to a large extent. This section gives hints for reading it when
learning to code for Lunatic.
[float]
==== http://www.lua.org/pil/p1.html[Preface]
May be interesting to get an idea of the philosophy behind Lua.
http://www.lua.org/pil/p1.3.html[A Few Typographical Conventions] should be
read to be familiar with them.
[float]
==== http://www.lua.org/pil/1.html[1 -- Getting Started]
Mentions the stand-alone Lua interpreter. When none is available, a LuaJIT
stand-alone binary can be used for experimentation as well.
[float]
==== http://www.lua.org/pil/1.1.html[1.1 -- Chunks]
Introduces chunks as the basic ``blocks'' of Lua code and notes how whitespace
is treated. Mentions `dofile`, which is not available in Lunatic
(<<require,`require`>> is preferred).
[float]
==== http://www.lua.org/pil/1.2.html[1.2 -- Global Variables]
Section may be read, but usage of *`local`* variables is strongly recommended
whenever possible. Also, trying to read a non-existent global or to write any
value to the global environment gives an error in Lunatic (except that global
writes are allowed in in <<modules,module>> context, i.e. after `module(...)`).
[float]
==== http://www.lua.org/pil/1.3.html[_1.3 -- Some Lexical Conventions_]
Must read.
[float]
==== http://www.lua.org/pil/2.html[_2 -- Types and Values_]
Must read, also subsections. However, ``2.7 -- Userdata and Threads'' is
not relevant.
[float]
==== http://www.lua.org/pil/3.html[_3 -- Expressions_]
Must read, also all subsections.
[float]
==== http://www.lua.org/pil/4.html[_4 -- Statements_]
Must read, also all subsections.
[float]
==== http://www.lua.org/pil/5.htmlhttp://www.lua.org/pil/5.html[_5 -- Functions_]
Must read, also all subsections. Subsection 5.2 mentions `io.write`, which is
not available in Lunatic.
[float]
==== http://www.lua.org/pil/6.html[6 -- More about Functions]
May be read (subsections as well) for a more complete understanding of
functions in Lua, as well as the utility of lexical scoping.
[float]
==== http://www.lua.org/pil/7.html[_7 -- Iterators and the Generic_ `for`]
May be read (subsections as well), but for basic programming, the knowledge of
how to merely use (as opposed to write) iterators such as
<<engine_iterators,`spritesofsect`>> suffices.
[float]
==== http://www.lua.org/pil/8.3.html[8.3 -- Errors]
May be read. Provides guidelines on how to write error handling (status code
vs. error).
[float]
==== http://www.lua.org/pil/8.4.html[8.4 -- Error Handling and Exceptions]
May be read. Discusses protected calls, which should be used sparingly.
[float]
==== http://www.lua.org/pil/11.html[_11 -- Data Structures_]
May be read, also subsections. The most relevant subsections are
http://www.lua.org/pil/11.1.html[11.1 -- Arrays],
http://www.lua.org/pil/11.5.html[11.5 -- Sets and Bags] and to some extent,
http://www.lua.org/pil/11.6.html[11.6 -- String Buffers]. The way ``11.2 --
Matrices and Multi-Dimensional Arrays'' suggests to construct matrices is
rather memory-intensive; also it and ``11.3 -- Linked Lists'' and ``11.4 --
Queues and Double Queues'' are not relevant to simple Lunatic coding.
[float]
==== http://www.lua.org/pil/15.html[15 -- Packages]
Lua package system received various additions in 5.1, so the PiL first
edition's section is out-of-sync. For Lunatic, the <<modules,modules>> section
of this manual should be consulted.
+
+
(The rest of Part II deals with advanced concepts not needed for simple Lunatic
coding.)
[float]
==== http://www.lua.org/pil/19.3.html[19.3 -- Sort]
May be read if needed.
[float]
==== http://www.lua.org/pil/20.html[20 -- The String Library]
May be skimmed (also subsections), though ultimately the Lua Reference should
be consulted for the exact semantics.
[appendix]
[[Appendix_event_RETURN]]
Game event `RETURN` usage
-------------------------
The following list notes how the special <<gv_RETURN,`gv.RETURN`>> variable
(known simply as `RETURN` from CON) is treated for the various events. The game
may either pass some value to a particular event as additional information, or
it can examine `RETURN` after the event has finished, invoking some behavior
conditional on its value. If an event is not listed here, its usage of `RETURN`
is unspecified.
[float]
Receives zero, checks for non-zero
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
These events get passed a value of 0 for `RETURN`, and after finishing, check
it for being non-zero, in which case some hard-coded behavior is suppressed:
`AIMDOWN`, `AIMUP`, `CROUCH`, `DISPLAYSBAR`, `DISPLAYWEAPON`, `DOFIRE`,
`DRAWWEAPON`, `FIRE`, `HOLODUKEOFF`, `HOLODUKEON`, `HOLSTER`, `INCURDAMAGE`,
`INVENTORY`, `JUMP`, `LOOKDOWN`, `LOOKLEFT`, `LOOKRIGHT`, `LOOKUP`,
`QUICKKICK`, `RETURNTOCENTER`, `SOARDOWN`, `SOARUP`, `SWIMDOWN`, `SWIMUP`,
`TURNAROUND`, `USEJETPACK`, `USEMEDKIT`, `USENIGHTVISION`, `USESTEROIDS`.
`KILLIT` (deprecated from Lua)::
If non-zero, the pending sprite deletion is aborted.
`DISPLAYROOMS`::
Don't draw scene if `RETURN` is 1. Values other than 0 and 1 are
reserved.
`PRESSEDFIRE`, `USE`::
If non-zero, the ``fire'' or ``use'' shared key bits are cleared
(respectively).
[float]
Game considers post-event `RETURN` an index
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For some events, the game examines `RETURN` after they have finished, and
potentially uses its value as some kind of index.
`CHANGEMENU` (deprecated from Lua)::
Receives and examines `RETURN` as a menu index to change to.
`DISPLAYCROSSHAIR`::
Receives 0. If the post-event `RETURN` equals 1, no crosshair is drawn. If
it is greater than one, `RETURN` is the tile index of the crosshair to be
displayed. The value 0 makes it draw using the `CROSSHAIR` tile.
`GETLOADTILE`::
Receives and examines `RETURN` as a background tile for the loading screen.
A negative value suppresses drawing it and running the subsequent
`EVENT_DISPLAYLOADINGSCREEN` entirely.
`GETMENUTILE`::
Receives and examines `RETURN` as a background tile for the menu.
`SOUND`::
Receives and examines `RETURN` as an index of a sound to start playing.
[float]
Cheat events
~~~~~~~~~~~~
The cheat events receive a hard-coded, item-dependent target amount in
`RETURN`. It can be overridden to a different value to make the respective
cheat give a different ``full'' amount. A negative value is ignored.
`CHEATGETSTEROIDS`, `CHEATGETHEAT`, `CHEATGETBOOT`, `CHEATGETSHIELD`,
`CHEATGETSCUBA`, `CHEATGETHOLODUKE`, `CHEATGETJETPACK`, `CHEATGETFIRSTAID`.
[float]
`EVENT_DAMAGEHPLANE`
~~~~~~~~~~~~~~~~~~~~
Triggered when a ceiling or a floor (collectively called ``hplane'') is
determined as being damaged. The event receives `RETURN` in the variable
`gv.RETURN` as well as the third, `dist` argument to the event
<<gameactor,callback function>>.footnote:[Passing `RETURN` in the `dist`
argument serves the possibility to create chained callbacks for
`EVENT_DAMAGEHPLANE`. Otherwise, once `gv.RETURN` were assigned to, there would
be no way to obtain its original value in subsequent chained callbacks.] This
value can be decoded into two parts by passing it to
`sector.damagehplane_whatsect`:
[source]
----------
function(aci, pli, RETURN)
local what, sectnum = sector.damagehplane_whatsect(RETURN)
-- (...)
----------
Then,
* `what` is one of the strings `'ceiling'` or `'floor'` and
* `sectnum` is the sector whose hplane is considered to be damaged.
When `EVENT_DAMAGEHPLANE` is left, `gv.RETURN` is examined to determine the
further action. It may be one of three values given by `sector.DAMAGEHPLANE`
(abbreviated `DHP` in the following):
* `DHP.SUPPRESS`: the hard-wired code that would subsequently be run is
suppressed entirely
* `DHP.DEFAULT`: The default code for hplane damaging is run. For floors, it
does nothing. For ceilings, it checks whether it has a tile number in a
hard-coded set of values depicting a breakable light. In that case, the tile
number is changed to the ``broken'' version and a ``glass breaking'' effect
consisting of playing a sound and spawning glass sprites is started. Also,
certain code related to SE3 and SE12 effects is run.
* `DHP.GLASSBREAK`: The light-breaking effect described above is run
unconditionally, but *without* changing the hplane's tile number, which is
assumed to have been done by the event.
If value last assigned to `RETURN` is not one in the above-mentioned set when
`EVENT_DAMAGEHPLANE` is left, the behavior is undefined.
[float]
TODO
~~~~
`CHANGEWEAPON`, `CHECKFLOORDAMAGE`, `CHECKTOUCHDAMAGE`, `NEXTWEAPON`,
`PREVIOUSWEAPON`, `SELECTWEAPON`, `WEAPKEY*`.