dfhack/docs/Lua API.rst

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.. highlight:: lua
.. _lua-api:
##############
DFHack Lua API
##############
DFHack has extensive support for
the Lua_ scripting language, providing access to:
.. _Lua: https://www.lua.org
1. Raw data structures used by the game.
2. Many C++ functions for high-level access to these
structures, and interaction with dfhack itself.
3. Some functions exported by C++ plugins.
Lua code can be used both for writing scripts, which
are treated by DFHack command line prompt almost as
native C++ commands, and invoked by plugins written in C++.
This document describes native API available to Lua in detail.
It does not describe all of the utility functions
implemented by Lua files located in :file:`hack/lua/*`
(:file:`library/lua/*` in the git repo).
.. contents:: Contents
:local:
:depth: 2
=========================
DF data structure wrapper
=========================
.. contents::
:local:
Data structures of the game are defined in XML files located in :file:`library/xml`
(and `online <https://github.com/DFHack/df-structures>`_, and automatically exported
to lua code as a tree of objects and functions under the ``df`` global, which
also broadly maps to the ``df`` namespace in the headers generated for C++.
.. warning::
The wrapper provides almost raw access to the memory of the game, so
mistakes in manipulating objects are as likely to crash the game as
equivalent plain C++ code would be - e.g. null pointer access is safely
detected, but dangling pointers aren't.
Objects managed by the wrapper can be broadly classified into the following groups:
1. Typed object pointers (references).
References represent objects in DF memory with a known type.
In addition to fields and methods defined by the wrapped type,
every reference has some built-in properties and methods.
2. Untyped pointers
Represented as lightuserdata.
In assignment to a pointer NULL can be represented either as
``nil``, or a NULL lightuserdata; reading a NULL pointer field
returns ``nil``.
3. Named types
Objects in the ``df`` tree that represent identity of struct, class,
enum and bitfield types. They host nested named types, static
methods, builtin properties & methods, and, for enums and bitfields,
the bi-directional mapping between key names and values.
4. The ``global`` object
``df.global`` corresponds to the ``df::global`` namespace, and
behaves as a mix between a named type and a reference, containing
both nested types and fields corresponding to global symbols.
In addition to the ``global`` object and top-level types the ``df``
global also contains a few global builtin utility functions.
Typed object references
=======================
The underlying primitive lua object is userdata with a metatable.
Every structured field access produces a new userdata instance.
All typed objects have the following built-in features:
* ``ref1 == ref2``, ``tostring(ref)``
References implement equality by type & pointer value, and string conversion.
* ``pairs(ref)``
Returns an iterator for the sequence of actual C++ field names
and values. Fields are enumerated in memory order. Methods and
lua wrapper properties are not included in the iteration.
.. warning::
a few of the data structures (like ui_look_list)
contain unions with pointers to different types with vtables.
Using pairs on such structs is an almost sure way to crash with
an access violation.
* ``ref._kind``
Returns one of: ``primitive``, ``struct``, ``container``,
or ``bitfield``, as appropriate for the referenced object.
* ``ref._type``
Returns the named type object or a string that represents
the referenced object type.
* ``ref:sizeof()``
Returns *size, address*
* ``ref:new()``
Allocates a new instance of the same type, and copies data
from the current object.
* ``ref:delete()``
Destroys the object with the C++ ``delete`` operator. If the destructor is not
available, returns *false*. (This typically only occurs when trying to delete
an instance of a DF class with virtual methods whose vtable address has not
been found; it is impossible for ``delete()`` to determine the validity of
``ref``.)
.. warning::
``ref`` **must** be an object allocated with ``new``, like in C++. Calling
``obj.field:delete()`` where ``obj`` was allocated with ``new`` will not
work. After ``delete()`` returns, ``ref`` remains as a dangling pointer,
like a raw C++ pointer would. Any accesses to ``ref`` after ``ref:delete()``
has been called are undefined behavior.
* ``ref:assign(object)``
Assigns data from object to ref. Object must either be another
ref of a compatible type, or a lua table; in the latter case
special recursive assignment rules are applied.
* ``ref:_displace(index[,step])``
Returns a new reference with the pointer adjusted by index*step.
Step defaults to the natural object size.
Primitive references
--------------------
References of the *_kind* ``'primitive'`` are used for objects
that don't fit any of the other reference types. Such
references can only appear as a value of a pointer field,
or as a result of calling the ``_field()`` method.
They behave as structs with a ``value`` field of the right type. If the
object's XML definition has a ``ref-target`` attribute, they will also have
a read-only ``ref_target`` field set to the corresponding type object.
To make working with numeric buffers easier, they also allow
numeric indices. Note that other than excluding negative values
no bound checking is performed, since buffer length is not available.
Index 0 is equivalent to the ``value`` field.
Struct references
-----------------
Struct references are used for class and struct objects.
They implement the following features:
* ``ref.field``, ``ref.field = value``
Valid fields of the structure may be accessed by subscript.
Primitive typed fields, i.e. numbers & strings, are converted
to/from matching lua values. The value of a pointer is a reference
to the target, or ``nil``/NULL. Complex types are represented by
a reference to the field within the structure; unless recursive
lua table assignment is used, such fields can only be read.
.. note::
In case of inheritance, *superclass* fields have precedence
over the subclass, but fields shadowed in this way can still
be accessed as ``ref['subclasstype.field']``.
This shadowing order is necessary because vtable-based classes
are automatically exposed in their exact type, and the reverse
rule would make access to superclass fields unreliable.
* ``ref._field(field)``
Returns a reference to a valid field. That is, unlike regular
subscript, it returns a reference to the field within the structure
even for primitive typed fields and pointers.
* ``ref:vmethod(args...)``
Named virtual methods are also exposed, subject to the same
shadowing rules.
* ``pairs(ref)``
Enumerates all real fields (but not methods) in memory
order, which is the same as declaration order.
Container references
--------------------
Containers represent vectors and arrays, possibly resizable.
A container field can associate an enum to the container
reference, which allows accessing elements using string keys
instead of numerical indices.
Note that two-dimensional arrays in C++ (ie pointers to pointers)
are exposed to lua as one-dimensional. The best way to handle this
is probably ``array[x].value:_displace(y)``.
Implemented features:
* ``ref._enum``
If the container has an associated enum, returns the matching
named type object.
* ``#ref``
Returns the *length* of the container.
* ``ref[index]``
Accesses the container element, using either a *0-based* numerical
index, or, if an enum is associated, a valid enum key string.
Accessing an invalid index is an error, but some container types
may return a default value, or auto-resize instead for convenience.
Currently this relaxed mode is implemented by df-flagarray aka BitArray.
* ``ref._field(index)``
Like with structs, returns a pointer to the array element, if possible.
Flag and bit arrays cannot return such pointer, so it fails with an error.
* ``pairs(ref)``, ``ipairs(ref)``
If the container has no associated enum, both behave identically,
iterating over numerical indices in order. Otherwise, ipairs still
uses numbers, while pairs tries to substitute enum keys whenever
possible.
* ``ref:resize(new_size)``
Resizes the container if supported, or fails with an error.
* ``ref:insert(index,item)``
Inserts a new item at the specified index. To add at the end,
use ``#ref``, or just ``'#'`` as index.
* ``ref:erase(index)``
Removes the element at the given valid index.
Bitfield references
-------------------
Bitfields behave like special fixed-size containers.
Consider them to be something in between structs and
fixed-size vectors.
The ``_enum`` property points to the bitfield type.
Numerical indices correspond to the shift value,
and if a subfield occupies multiple bits, the
``ipairs`` order would have a gap.
Since currently there is no API to allocate a bitfield
object fully in GC-managed lua heap, consider using the
lua table assignment feature outlined below in order to
pass bitfield values to dfhack API functions that need
them, e.g. ``matinfo:matches{metal=true}``.
Named types
===========
Named types are exposed in the ``df`` tree with names identical
to the C++ version, except for the ``::`` vs ``.`` difference.
All types and the global object have the following features:
* ``type._kind``
Evaluates to one of ``struct-type``, ``class-type``, ``enum-type``,
``bitfield-type`` or ``global``.
* ``type._identity``
Contains a lightuserdata pointing to the underlying
``DFHack::type_instance`` object.
Types excluding the global object also support:
* ``type:sizeof()``
Returns the size of an object of the type.
* ``type:new()``
Creates a new instance of an object of the type.
* ``type:is_instance(object)``
Returns true if object is same or subclass type, or a reference
to an object of same or subclass type. It is permissible to pass
``nil``, NULL or non-wrapper value as object; in this case the
method returns ``nil``.
In addition to this, enum and bitfield types contain a
bi-directional mapping between key strings and values, and
also map ``_first_item`` and ``_last_item`` to the min and
max values.
Struct and class types with instance-vector attribute in the
xml have a ``type.find(key)`` function that wraps the find
method provided in C++.
Global functions
================
The ``df`` table itself contains the following functions and values:
* ``NULL``, ``df.NULL``
Contains the NULL lightuserdata.
* ``df.isnull(obj)``
Evaluates to true if obj is nil or NULL; false otherwise.
* ``df.isvalid(obj[,allow_null])``
For supported objects returns one of ``type``, ``voidptr``, ``ref``.
If *allow_null* is true, and obj is nil or NULL, returns ``null``.
Otherwise returns *nil*.
* ``df.sizeof(obj)``
For types and refs identical to ``obj:sizeof()``.
For lightuserdata returns *nil, address*
* ``df.new(obj)``, ``df.delete(obj)``, ``df.assign(obj, obj2)``
Equivalent to using the matching methods of obj.
* ``df._displace(obj,index[,step])``
For refs equivalent to the method, but also works with
lightuserdata (step is mandatory then).
* ``df.is_instance(type,obj)``
Equivalent to the method, but also allows a reference as proxy for its type.
* ``df.new(ptype[,count])``
Allocate a new instance, or an array of built-in types.
The ``ptype`` argument is a string from the following list:
``string``, ``int8_t``, ``uint8_t``, ``int16_t``, ``uint16_t``,
``int32_t``, ``uint32_t``, ``int64_t``, ``uint64_t``, ``bool``,
``float``, ``double``. All of these except ``string`` can be
used with the count argument to allocate an array.
* ``df.reinterpret_cast(type,ptr)``
Converts ptr to a ref of specified type. The type may be anything
acceptable to ``df.is_instance``. Ptr may be *nil*, a ref,
a lightuserdata, or a number.
Returns *nil* if NULL, or a ref.
.. _lua-api-table-assignment:
Recursive table assignment
==========================
Recursive assignment is invoked when a lua table is assigned
to a C++ object or field, i.e. one of:
* ``ref:assign{...}``
* ``ref.field = {...}``
The general mode of operation is that all fields of the table
are assigned to the fields of the target structure, roughly
emulating the following code::
function rec_assign(ref,table)
for key,value in pairs(table) do
ref[key] = value
end
end
Since assigning a table to a field using = invokes the same
process, it is recursive.
There are however some variations to this process depending
on the type of the field being assigned to:
1. If the table contains an ``assign`` field, it is
applied first, using the ``ref:assign(value)`` method.
It is never assigned as a usual field.
2. When a table is assigned to a non-NULL pointer field
using the ``ref.field = {...}`` syntax, it is applied
to the target of the pointer instead.
If the pointer is NULL, the table is checked for a ``new`` field:
a. If it is *nil* or *false*, assignment fails with an error.
b. If it is *true*, the pointer is initialized with a newly
allocated object of the declared target type of the pointer.
c. Otherwise, ``table.new`` must be a named type, or an
object of a type compatible with the pointer. The pointer
is initialized with the result of calling ``table.new:new()``.
After this auto-vivification process, assignment proceeds
as if the pointer wasn't NULL.
Obviously, the ``new`` field inside the table is always skipped
during the actual per-field assignment processing.
3. If the target of the assignment is a container, a separate
rule set is used:
a. If the table contains neither ``assign`` nor ``resize``
fields, it is interpreted as an ordinary *1-based* lua
array. The container is resized to the #-size of the
table, and elements are assigned in numeric order::
ref:resize(#table);
for i=1,#table do ref[i-1] = table[i] end
b. Otherwise, ``resize`` must be *true*, *false*, or
an explicit number. If it is not false, the container
is resized. After that the usual struct-like 'pairs'
assignment is performed.
In case ``resize`` is *true*, the size is computed
by scanning the table for the largest numeric key.
This means that in order to reassign only one element of
a container using this system, it is necessary to use::
{ resize=false, [idx]=value }
Since ``nil`` inside a table is indistinguishable from missing key,
it is necessary to use ``df.NULL`` as a null pointer value.
This system is intended as a way to define a nested object
tree using pure lua data structures, and then materialize it in
C++ memory in one go. Note that if pointer auto-vivification
is used, an error in the middle of the recursive walk would
not destroy any objects allocated in this way, so the user
should be prepared to catch the error and do the necessary
cleanup.
==========
DFHack API
==========
.. contents::
:local:
DFHack utility functions are placed in the ``dfhack`` global tree.
Native utilities
================
Input & Output
--------------
* ``dfhack.print(args...)``
Output tab-separated args as standard lua print would do,
but without a newline.
* ``print(args...)``, ``dfhack.println(args...)``
A replacement of the standard library print function that
works with DFHack output infrastructure.
* ``dfhack.printerr(args...)``
Same as println; intended for errors. Uses red color and logs to stderr.log.
* ``dfhack.color([color])``
Sets the current output color. If color is *nil* or *-1*, resets to default.
Returns the previous color value.
* ``dfhack.is_interactive()``
Checks if the thread can access the interactive console and returns *true* or *false*.
* ``dfhack.lineedit([prompt[,history_filename]])``
If the thread owns the interactive console, shows a prompt
and returns the entered string. Otherwise returns *nil, error*.
Depending on the context, this function may actually yield the
running coroutine and let the C++ code release the core suspend
lock. Using an explicit ``dfhack.with_suspend`` will prevent
this, forcing the function to block on input with lock held.
* ``dfhack.interpreter([prompt[,history_filename[,env]]])``
Starts an interactive lua interpreter, using the specified prompt
string, global environment and command-line history file.
If the interactive console is not accessible, returns *nil, error*.
Exception handling
------------------
* ``dfhack.error(msg[,level[,verbose]])``
Throws a dfhack exception object with location and stack trace.
The verbose parameter controls whether the trace is printed by default.
* ``qerror(msg[,level])``
Calls ``dfhack.error()`` with ``verbose`` being *false*. Intended to
be used for user-caused errors in scripts, where stack traces are not
desirable.
* ``dfhack.pcall(f[,args...])``
Invokes f via xpcall, using an error function that attaches
a stack trace to the error. The same function is used by SafeCall
in C++, and dfhack.safecall.
* ``safecall(f[,args...])``, ``dfhack.safecall(f[,args...])``
Just like pcall, but also prints the error using printerr before
returning. Intended as a convenience function.
* ``dfhack.saferesume(coroutine[,args...])``
Compares to coroutine.resume like dfhack.safecall vs pcall.
* ``dfhack.exception``
Metatable of error objects used by dfhack. The objects have the
following properties:
``err.where``
The location prefix string, or *nil*.
``err.message``
The base message string.
``err.stacktrace``
The stack trace string, or *nil*.
``err.cause``
A different exception object, or *nil*.
``err.thread``
The coroutine that has thrown the exception.
``err.verbose``
Boolean, or *nil*; specifies if where and stacktrace should be printed.
``tostring(err)``, or ``err:tostring([verbose])``
Converts the exception to string.
* ``dfhack.exception.verbose``
The default value of the ``verbose`` argument of ``err:tostring()``.
Miscellaneous
-------------
* ``dfhack.VERSION``
DFHack version string constant.
* ``dfhack.curry(func,args...)``, or ``curry(func,args...)``
Returns a closure that invokes the function with args combined
both from the curry call and the closure call itself. I.e.
``curry(func,a,b)(c,d)`` equals ``func(a,b,c,d)``.
Locking and finalization
------------------------
* ``dfhack.with_suspend(f[,args...])``
Calls ``f`` with arguments after grabbing the DF core suspend lock.
Suspending is necessary for accessing a consistent state of DF memory.
Returned values and errors are propagated through after releasing
the lock. It is safe to nest suspends.
Every thread is allowed only one suspend per DF frame, so it is best
to group operations together in one big critical section. A plugin
can choose to run all lua code inside a C++-side suspend lock.
* ``dfhack.call_with_finalizer(num_cleanup_args,always,cleanup_fn[,cleanup_args...],fn[,args...])``
Invokes ``fn`` with ``args``, and after it returns or throws an
error calls ``cleanup_fn`` with ``cleanup_args``. Any return values from
``fn`` are propagated, and errors are re-thrown.
The ``num_cleanup_args`` integer specifies the number of ``cleanup_args``,
and the ``always`` boolean specifies if cleanup should be called in any case,
or only in case of an error.
* ``dfhack.with_finalize(cleanup_fn,fn[,args...])``
Calls ``fn`` with arguments, then finalizes with ``cleanup_fn``.
Implemented using ``call_with_finalizer(0,true,...)``.
* ``dfhack.with_onerror(cleanup_fn,fn[,args...])``
Calls ``fn`` with arguments, then finalizes with ``cleanup_fn`` on any thrown error.
Implemented using ``call_with_finalizer(0,false,...)``.
* ``dfhack.with_temp_object(obj,fn[,args...])``
Calls ``fn(obj,args...)``, then finalizes with ``obj:delete()``.
Persistent configuration storage
--------------------------------
This api is intended for storing configuration options in the world itself.
It probably should be restricted to data that is world-dependent.
Entries are identified by a string ``key``, but it is also possible to manage
multiple entries with the same key; their identity is determined by ``entry_id``.
Every entry has a mutable string ``value``, and an array of 7 mutable ``ints``.
* ``dfhack.persistent.get(key)``, ``entry:get()``
Retrieves a persistent config record with the given string key,
or refreshes an already retrieved entry. If there are multiple
entries with the same key, it is undefined which one is retrieved
by the first version of the call.
Returns entry, or *nil* if not found.
* ``dfhack.persistent.delete(key)``, ``entry:delete()``
Removes an existing entry. Returns *true* if succeeded.
* ``dfhack.persistent.get_all(key[,match_prefix])``
Retrieves all entries with the same key, or starting with key..'/'.
Calling ``get_all('',true)`` will match all entries.
If none found, returns nil; otherwise returns an array of entries.
* ``dfhack.persistent.save({key=str1, ...}[,new])``, ``entry:save([new])``
Saves changes in an entry, or creates a new one. Passing true as
new forces creation of a new entry even if one already exists;
otherwise the existing one is simply updated.
Returns *entry, did_create_new*
Since the data is hidden in data structures owned by the DF world,
and automatically stored in the save game, these save and retrieval
functions can just copy values in memory without doing any actual I/O.
However, currently every entry has a 180+-byte dead-weight overhead.
It is also possible to associate one bit per map tile with an entry,
using these two methods:
* ``entry:getTilemask(block[, create])``
Retrieves the tile bitmask associated with this entry in the given map
block. If ``create`` is *true*, an empty mask is created if none exists;
otherwise the function returns *nil*, which must be assumed to be the same
as an all-zero mask.
* ``entry:deleteTilemask(block)``
Deletes the associated tile mask from the given map block.
Note that these masks are only saved in fortress mode, and also that deleting
the persistent entry will **NOT** delete the associated masks.
Material info lookup
--------------------
A material info record has fields:
* ``type``, ``index``, ``material``
DF material code pair, and a reference to the material object.
* ``mode``
One of ``'builtin'``, ``'inorganic'``, ``'plant'``, ``'creature'``.
* ``inorganic``, ``plant``, ``creature``
If the material is of the matching type, contains a reference to the raw object.
* ``figure``
For a specific creature material contains a ref to the historical figure.
Functions:
* ``dfhack.matinfo.decode(type,index)``
Looks up material info for the given number pair; if not found, returs *nil*.
* ``....decode(matinfo)``, ``....decode(item)``, ``....decode(obj)``
Uses ``matinfo.type``/``matinfo.index``, item getter vmethods,
or ``obj.mat_type``/``obj.mat_index`` to get the code pair.
* ``dfhack.matinfo.find(token[,token...])``
Looks up material by a token string, or a pre-split string token sequence.
* ``dfhack.matinfo.getToken(...)``, ``info:getToken()``
Applies ``decode`` and constructs a string token.
* ``info:toString([temperature[,named]])``
Returns the human-readable name at the given temperature.
* ``info:getCraftClass()``
Returns the classification used for craft skills.
* ``info:matches(obj)``
Checks if the material matches job_material_category or job_item.
Accept dfhack_material_category auto-assign table.
.. _lua_api_random:
Random number generation
------------------------
* ``dfhack.random.new([seed[,perturb_count]])``
Creates a new random number generator object. Without any
arguments, the object is initialized using current time.
Otherwise, the seed must be either a non-negative integer,
or a list of such integers. The second argument may specify
the number of additional randomization steps performed to
improve the initial state.
* ``rng:init([seed[,perturb_count]])``
Re-initializes an already existing random number generator object.
* ``rng:random([limit])``
Returns a random integer. If ``limit`` is specified, the value
is in the range [0, limit); otherwise it uses the whole 32-bit
unsigned integer range.
* ``rng:drandom()``
Returns a random floating-point number in the range [0,1).
* ``rng:drandom0()``
Returns a random floating-point number in the range (0,1).
* ``rng:drandom1()``
Returns a random floating-point number in the range [0,1].
* ``rng:unitrandom()``
Returns a random floating-point number in the range [-1,1].
* ``rng:unitvector([size])``
Returns multiple values that form a random vector of length 1,
uniformly distributed over the corresponding sphere surface.
The default size is 3.
* ``fn = rng:perlin([dim]); fn(x[,y[,z]])``
Returns a closure that computes a classical Perlin noise function
of dimension *dim*, initialized from this random generator.
Dimension may be 1, 2 or 3 (default).
.. _lua-cpp-func-wrappers:
C++ function wrappers
=====================
.. contents::
:local:
Thin wrappers around C++ functions, similar to the ones for virtual methods.
One notable difference is that these explicit wrappers allow argument count
adjustment according to the usual lua rules, so trailing false/nil arguments
can be omitted.
* ``dfhack.getOSType()``
Returns the OS type string from ``symbols.xml``.
* ``dfhack.getDFVersion()``
Returns the DF version string from ``symbols.xml``.
* ``dfhack.getDFHackVersion()``
* ``dfhack.getDFHackRelease()``
* ``dfhack.getDFHackBuildID()``
* ``dfhack.getCompiledDFVersion()``
* ``dfhack.getGitDescription()``
* ``dfhack.getGitCommit()``
* ``dfhack.getGitXmlCommit()``
* ``dfhack.getGitXmlExpectedCommit()``
* ``dfhack.gitXmlMatch()``
* ``dfhack.isRelease()``
Return information about the DFHack build in use.
.. note::
``getCompiledDFVersion()`` returns the DF version specified at compile time,
while ``getDFVersion()`` returns the version and typically the OS as well.
These do not necessarily match - for example, DFHack 0.34.11-r5 worked with
DF 0.34.10 and 0.34.11, so the former function would always return ``0.34.11``
while the latter would return ``v0.34.10 <platform>`` or ``v0.34.11 <platform>``.
* ``dfhack.getDFPath()``
Returns the DF directory path.
* ``dfhack.getHackPath()``
Returns the dfhack directory path, i.e. ``".../df/hack/"``.
* ``dfhack.getSavePath()``
Returns the path to the current save directory, or *nil* if no save loaded.
* ``dfhack.getTickCount()``
Returns the tick count in ms, exactly as DF ui uses.
* ``dfhack.isWorldLoaded()``
Checks if the world is loaded.
* ``dfhack.isMapLoaded()``
Checks if the world and map are loaded.
* ``dfhack.TranslateName(name[,in_english,only_last_name])``
Convert a language_name or only the last name part to string.
* ``dfhack.df2utf(string)``
Convert a string from DF's CP437 encoding to UTF-8.
* ``dfhack.df2console()``
Convert a string from DF's CP437 encoding to the correct encoding for the
DFHack console.
.. warning::
When printing CP437-encoded text to the console (for example, names returned
from ``dfhack.TranslateName()``), use ``print(dfhack.df2console(text))`` to
ensure proper display on all platforms.
* ``dfhack.utf2df(string)``
Convert a string from UTF-8 to DF's CP437 encoding.
* ``dfhack.toSearchNormalized(string)``
Replace non-ASCII alphabetic characters in a CP437-encoded string with their
nearest ASCII equivalents, if possible, and returns a CP437-encoded string.
Note that the returned string may be longer than the input string. For
example, ``ä`` is replaced with ``a``, and ``æ`` is replaced with ``ae``.
* ``dfhack.run_command(command[, ...])``
Run an arbitrary DFHack command, with the core suspended, and send output to
the DFHack console. The command can be passed as a table, multiple string
arguments, or a single string argument (not recommended - in this case, the
usual DFHack console tokenization is used).
A ``command_result`` constant starting with ``CR_`` is returned, where ``CR_OK``
indicates success.
The following examples are equivalent::
dfhack.run_command({'ls', '-a'})
dfhack.run_command('ls', '-a')
dfhack.run_command('ls -a') -- not recommended
* ``dfhack.run_command_silent(command[, ...])``
Similar to ``run_command()``, but instead of printing to the console,
returns an ``output, command_result`` pair. ``output`` is a single string -
see ``dfhack.internal.runCommand()`` to obtain colors as well.
Gui module
----------
Screens
~~~~~~~
* ``dfhack.gui.getCurViewscreen([skip_dismissed])``
Returns the topmost viewscreen. If ``skip_dismissed`` is *true*,
ignores screens already marked to be removed.
* ``dfhack.gui.getFocusString(viewscreen)``
Returns a string representation of the current focus position
in the ui. The string has a "screen/foo/bar/baz..." format.
* ``dfhack.gui.getCurFocus([skip_dismissed])``
Returns the focus string of the current viewscreen.
* ``dfhack.gui.getViewscreenByType(type [, depth])``
Returns the topmost viewscreen out of the top ``depth`` viewscreens with
the specified type (e.g. ``df.viewscreen_titlest``), or ``nil`` if none match.
If ``depth`` is not specified or is less than 1, all viewscreens are checked.
General-purpose selections
~~~~~~~~~~~~~~~~~~~~~~~~~~
* ``dfhack.gui.getSelectedWorkshopJob([silent])``
When a job is selected in :kbd:`q` mode, returns the job, else
prints error unless silent and returns *nil*.
* ``dfhack.gui.getSelectedJob([silent])``
Returns the job selected in a workshop or unit/jobs screen.
* ``dfhack.gui.getSelectedUnit([silent])``
Returns the unit selected via :kbd:`v`, :kbd:`k`, unit/jobs, or
a full-screen item view of a cage or suchlike.
* ``dfhack.gui.getSelectedItem([silent])``
Returns the item selected via :kbd:`v` ->inventory, :kbd:`k`, :kbd:`t`, or
a full-screen item view of a container. Note that in the
last case, the highlighted *contained item* is returned, not
the container itself.
* ``dfhack.gui.getSelectedBuilding([silent])``
Returns the building selected via :kbd:`q`, :kbd:`t`, :kbd:`k` or :kbd:`i`.
* ``dfhack.gui.getSelectedPlant([silent])``
Returns the plant selected via :kbd:`k`.
* ``dfhack.gui.getAnyUnit(screen)``
* ``dfhack.gui.getAnyItem(screen)``
* ``dfhack.gui.getAnyBuilding(screen)``
* ``dfhack.gui.getAnyPlant(screen)``
Similar to the corresponding ``getSelected`` functions, but operate on the
screen given instead of the current screen and always return ``nil`` silently
on failure.
Fortress mode
~~~~~~~~~~~~~
* ``dfhack.gui.getDwarfmodeViewDims()``
Returns dimensions of the main fortress mode screen. See ``getPanelLayout()``
in the ``gui.dwarfmode`` module for a more Lua-friendly version.
* ``dfhack.gui.resetDwarfmodeView([pause])``
Resets the fortress mode sidebar menus and cursors to their default state. If
``pause`` is true, also pauses the game.
* ``dfhack.gui.revealInDwarfmodeMap(pos)``
Centers the view on the given position, which can be a ``df.coord`` instance
or a table assignable to a ``df.coord`` (see `lua-api-table-assignment`),
e.g.::
{x = 5, y = 7, z = 11}
getSelectedUnit().pos
copyall(df.global.cursor)
Returns false if unsuccessful.
* ``dfhack.gui.refreshSidebar()``
Refreshes the fortress mode sidebar. This can be useful when making changes to
the map, for example, because DF only updates the sidebar when the cursor
position changes.
* ``dfhack.gui.inRenameBuilding()``
Returns ``true`` if a building is being renamed.
Announcements
~~~~~~~~~~~~~
* ``dfhack.gui.writeToGamelog(text)``
Writes a string to :file:`gamelog.txt` without doing an announcement.
* ``dfhack.gui.makeAnnouncement(type,flags,pos,text,color[,is_bright])``
Adds an announcement with given announcement_type, text, color, and brightness.
The is_bright boolean actually seems to invert the brightness.
The announcement is written to :file:`gamelog.txt`. The announcement_flags
argument provides a custom set of :file:`announcements.txt` options,
which specify if the message should actually be displayed in the
announcement list, and whether to recenter or show a popup.
Returns the index of the new announcement in ``df.global.world.status.reports``, or -1.
* ``dfhack.gui.addCombatReport(unit,slot,report_index)``
Adds the report with the given index (returned by makeAnnouncement)
to the specified group of the given unit. Returns *true* on success.
* ``dfhack.gui.addCombatReportAuto(unit,flags,report_index)``
Adds the report with the given index to the appropriate group(s)
of the given unit, as requested by the flags.
* ``dfhack.gui.showAnnouncement(text,color[,is_bright])``
Adds a regular announcement with given text, color, and brightness.
The is_bright boolean actually seems to invert the brightness.
* ``dfhack.gui.showZoomAnnouncement(type,pos,text,color[,is_bright])``
Like above, but also specifies a position you can zoom to from the announcement menu.
* ``dfhack.gui.showPopupAnnouncement(text,color[,is_bright])``
Pops up a titan-style modal announcement window.
* ``dfhack.gui.showAutoAnnouncement(type,pos,text,color[,is_bright,unit1,unit2])``
Uses the type to look up options from announcements.txt, and calls the above
operations accordingly. The units are used to call ``addCombatReportAuto``.
Other
~~~~~
* ``dfhack.gui.getDepthAt(x, y)``
Returns the distance from the z-level of the tile at map coordinates (x, y) to
the closest ground z-level below. Defaults to 0, unless overriden by plugins.
Job module
----------
* ``dfhack.job.cloneJobStruct(job)``
Creates a deep copy of the given job.
* ``dfhack.job.printJobDetails(job)``
Prints info about the job.
* ``dfhack.job.printItemDetails(jobitem,idx)``
Prints info about the job item.
* ``dfhack.job.getGeneralRef(job, type)``
Searches for a general_ref with the given type.
* ``dfhack.job.getSpecificRef(job, type)``
Searches for a specific_ref with the given type.
* ``dfhack.job.getHolder(job)``
Returns the building holding the job.
* ``dfhack.job.getWorker(job)``
Returns the unit performing the job.
* ``dfhack.job.setJobCooldown(building,worker,cooldown)``
Prevent the worker from taking jobs at the specified workshop for the
specified cooldown period (in ticks). This doesn't decrease the cooldown
period in any circumstances.
* ``dfhack.job.removeWorker(job,cooldown)``
Removes the worker from the specified workshop job, and sets the cooldown
period (using the same logic as ``setJobCooldown``). Returns *true* on
success.
* ``dfhack.job.checkBuildingsNow()``
Instructs the game to check buildings for jobs next frame and assign workers.
* ``dfhack.job.checkDesignationsNow()``
Instructs the game to check designations for jobs next frame and assign workers.
* ``dfhack.job.is_equal(job1,job2)``
Compares important fields in the job and nested item structures.
* ``dfhack.job.is_item_equal(job_item1,job_item2)``
Compares important fields in the job item structures.
* ``dfhack.job.linkIntoWorld(job,new_id)``
Adds job into ``df.global.job_list``, and if new_id
is true, then also sets its id and increases
``df.global.job_next_id``
* ``dfhack.job.listNewlyCreated(first_id)``
Returns the current value of ``df.global.job_next_id``, and
if there are any jobs with ``first_id <= id < job_next_id``,
a lua list containing them.
* ``dfhack.job.isSuitableItem(job_item, item_type, item_subtype)``
Does basic sanity checks to verify if the suggested item type matches
the flags in the job item.
* ``dfhack.job.isSuitableMaterial(job_item, mat_type, mat_index, item_type)``
Likewise, if replacing material.
* ``dfhack.job.getName(job)``
Returns the job's description, as seen in the Units and Jobs screens.
Units module
------------
* ``dfhack.units.getPosition(unit)``
Returns true *x,y,z* of the unit, or *nil* if invalid; may be not equal to unit.pos if caged.
* ``dfhack.units.getUnitsInBox(x1,y1,z1,x2,y2,z2[,filter])``
Returns a table of all units within the specified coordinates. If the ``filter``
argument is given, only units where ``filter(unit)`` returns true will be included.
Note that ``pos2xyz()`` cannot currently be used to convert coordinate objects to
the arguments required by this function.
* ``dfhack.units.teleport(unit, pos)``
Moves the specified unit and any riders to the target coordinates, setting
tile occupancy flags appropriately. Returns true if successful.
* ``dfhack.units.getGeneralRef(unit, type)``
Searches for a general_ref with the given type.
* ``dfhack.units.getSpecificRef(unit, type)``
Searches for a specific_ref with the given type.
* ``dfhack.units.getContainer(unit)``
Returns the container (cage) item or *nil*.
* ``dfhack.units.setNickname(unit,nick)``
Sets the unit's nickname properly.
* ``dfhack.units.getOuterContainerRef(unit)``
Returns a table (in the style of a ``specific_ref`` struct) of the outermost object that contains the unit (or one of the unit itself.)
The ``type`` field contains a ``specific_ref_type`` of ``UNIT``, ``ITEM_GENERAL``, or ``VERMIN_EVENT``.
The ``object`` field contains a pointer to a unit, item, or vermin, respectively.
* ``dfhack.units.getVisibleName(unit)``
Returns the language_name object visible in game, accounting for false identities.
* ``dfhack.units.getIdentity(unit)``
Returns the false identity of the unit if it has one, or *nil*.
* ``dfhack.units.getNemesis(unit)``
Returns the nemesis record of the unit if it has one, or *nil*.
* ``dfhack.units.isHidingCurse(unit)``
Checks if the unit hides improved attributes from its curse.
* ``dfhack.units.getPhysicalAttrValue(unit, attr_type)``
* ``dfhack.units.getMentalAttrValue(unit, attr_type)``
Computes the effective attribute value, including curse effect.
* ``dfhack.units.isCrazed(unit)``
* ``dfhack.units.isOpposedToLife(unit)``
* ``dfhack.units.hasExtravision(unit)``
* ``dfhack.units.isBloodsucker(unit)``
Simple checks of caste attributes that can be modified by curses.
* ``dfhack.units.getMiscTrait(unit, type[, create])``
Finds (or creates if requested) a misc trait object with the given id.
* ``dfhack.units.isActive(unit)``
The unit is active (alive and on the map).
* ``dfhack.units.isAlive(unit)``
The unit isn't dead or undead.
* ``dfhack.units.isDead(unit)``
The unit is completely dead and passive, or a ghost. Equivalent to
``dfhack.units.isKilled(unit) or dfhack.units.isGhost(unit)``.
* ``dfhack.units.isKilled(unit)``
The unit has been killed.
* ``dfhack.units.isGhost(unit)``
The unit is a ghost.
* ``dfhack.units.isSane(unit)``
The unit is capable of rational action, i.e. not dead, insane, zombie, or active werewolf.
* ``dfhack.units.isDwarf(unit)``
The unit is of the correct race of the fortress.
* ``dfhack.units.isCitizen(unit)``
The unit is an alive sane citizen of the fortress; wraps the
same checks the game uses to decide game-over by extinction.
* ``dfhack.units.isFortControlled(unit)``
Similar to ``dfhack.units.isCitizen(unit)``, but is based on checks for units hidden in ambush, and includes tame animals. Returns *false* if not in fort mode.
* ``dfhack.units.isVisible(unit)``
The unit is visible on the map.
* ``dfhack.units.isHidden(unit)``
The unit is hidden to the player, accounting for sneaking. Works for any game mode.
* ``dfhack.units.getAge(unit[,true_age])``
Returns the age of the unit in years as a floating-point value.
If ``true_age`` is true, ignores false identities.
* ``dfhack.units.isValidLabor(unit, unit_labor)``
Returns whether the indicated labor is settable for the given unit.
* ``dfhack.units.setLaborValidity(unit_labor, isValid)``
Sets the given labor to the given (boolean) validity for all units that are
part of your fortress civilization. Valid labors are allowed to be toggled
in the in-game labor management screens (including DFHack's `labor manipulator
screen <manipulator>`).
* ``dfhack.units.getNominalSkill(unit, skill[, use_rust])``
Retrieves the nominal skill level for the given unit. If ``use_rust``
is *true*, subtracts the rust penalty.
* ``dfhack.units.getEffectiveSkill(unit, skill)``
Computes the effective rating for the given skill, taking into account exhaustion, pain etc.
* ``dfhack.units.getExperience(unit, skill[, total])``
Returns the experience value for the given skill. If ``total`` is true, adds experience implied by the current rating.
* ``dfhack.units.computeMovementSpeed(unit)``
Computes number of frames * 100 it takes the unit to move in its current state of mind and body.
* ``dfhack.units.computeSlowdownFactor(unit)``
Meandering and floundering in liquid introduces additional slowdown. It is
random, but the function computes and returns the expected mean factor as a float.
* ``dfhack.units.getNoblePositions(unit)``
Returns a list of tables describing noble position assignments, or *nil*.
Every table has fields ``entity``, ``assignment`` and ``position``.
* ``dfhack.units.getProfessionName(unit[,ignore_noble,plural])``
Retrieves the profession name using custom profession, noble assignments
or raws. The ``ignore_noble`` boolean disables the use of noble positions.
* ``dfhack.units.getCasteProfessionName(race,caste,prof_id[,plural])``
Retrieves the profession name for the given race/caste using raws.
* ``dfhack.units.getProfessionColor(unit[,ignore_noble])``
Retrieves the color associated with the profession, using noble assignments
or raws. The ``ignore_noble`` boolean disables the use of noble positions.
* ``dfhack.units.getCasteProfessionColor(race,caste,prof_id)``
Retrieves the profession color for the given race/caste using raws.
* ``dfhack.units.getGoalType(unit[,goalIndex])``
Retrieves the goal type of the dream that the given unit has.
By default the goal of the first dream is returned.
The goalIndex parameter may be used to retrieve additional dream goals.
Currently only one dream per unit is supported by Dwarf Fortress.
Support for multiple dreams may be added in future versions of Dwarf Fortress.
* ``dfhack.units.getGoalName(unit[,goalIndex])``
Retrieves the short name describing the goal of the dream that the given unit has.
By default the goal of the first dream is returned.
The goalIndex parameter may be used to retrieve additional dream goals.
Currently only one dream per unit is supported by Dwarf Fortress.
Support for multiple dreams may be added in future versions of Dwarf Fortress.
* ``dfhack.units.isGoalAchieved(unit[,goalIndex])``
Checks if given unit has achieved the goal of the dream.
By default the status of the goal of the first dream is returned.
The goalIndex parameter may be used to check additional dream goals.
Currently only one dream per unit is supported by Dwarf Fortress.
Support for multiple dreams may be added in future versions of Dwarf Fortress.
* ``dfhack.units.getStressCategory(unit)``
Returns a number from 0-6 indicating stress. 0 is most stressed; 6 is least.
Note that 0 is guaranteed to remain the most stressed but 6 could change in the future.
* ``dfhack.units.getStressCategoryRaw(stress_level)``
Identical to ``getStressCategory`` but takes a raw stress level instead of a unit.
* ``dfhack.units.getStressCutoffs()``
Returns a table of the cutoffs used by the above stress level functions.
Items module
------------
* ``dfhack.items.getPosition(item)``
Returns true *x,y,z* of the item, or *nil* if invalid; may be not equal to item.pos if in inventory.
* ``dfhack.items.getBookTitle(item)``
Returns the title of the "book" item, or an empty string if the item isn't a "book" or it doesn't
have a title. A "book" is a codex or a tool item that has page or writings improvements, such as
scrolls and quires.
* ``dfhack.items.getDescription(item, type[, decorate])``
Returns the string description of the item, as produced by the ``getItemDescription``
method. If decorate is true, also adds markings for quality and improvements.
* ``dfhack.items.getGeneralRef(item, type)``
Searches for a general_ref with the given type.
* ``dfhack.items.getSpecificRef(item, type)``
Searches for a specific_ref with the given type.
* ``dfhack.items.getOwner(item)``
Returns the owner unit or *nil*.
* ``dfhack.items.setOwner(item,unit)``
Replaces the owner of the item. If unit is *nil*, removes ownership.
Returns *false* in case of error.
* ``dfhack.items.getContainer(item)``
Returns the container item or *nil*.
* ``dfhack.items.getOuterContainerRef(item)``
Returns a table (in the style of a ``specific_ref`` struct) of the outermost object that contains the item (or one of the item itself.)
The ``type`` field contains a ``specific_ref_type`` of ``UNIT``, ``ITEM_GENERAL``, or ``VERMIN_EVENT``.
The ``object`` field contains a pointer to a unit, item, or vermin, respectively.
* ``dfhack.items.getContainedItems(item)``
Returns a list of items contained in this one.
* ``dfhack.items.getHolderBuilding(item)``
Returns the holder building or *nil*.
* ``dfhack.items.getHolderUnit(item)``
Returns the holder unit or *nil*.
* ``dfhack.items.moveToGround(item,pos)``
Move the item to the ground at position. Returns *false* if impossible.
* ``dfhack.items.moveToContainer(item,container)``
Move the item to the container. Returns *false* if impossible.
* ``dfhack.items.moveToBuilding(item,building[,use_mode[,force_in_building])``
Move the item to the building. Returns *false* if impossible.
``use_mode`` defaults to 0. If set to 2, the item will be treated as part of the building.
If ``force_in_building`` is true, the item will be considered to be stored by the building
(used for items temporarily used in traps in vanilla DF)
* ``dfhack.items.moveToInventory(item,unit,use_mode,body_part)``
Move the item to the unit inventory. Returns *false* if impossible.
* ``dfhack.items.remove(item[, no_uncat])``
Removes the item, and marks it for garbage collection unless ``no_uncat`` is true.
* ``dfhack.items.makeProjectile(item)``
Turns the item into a projectile, and returns the new object, or *nil* if impossible.
* ``dfhack.items.isCasteMaterial(item_type)``
Returns *true* if this item type uses a creature/caste pair as its material.
* ``dfhack.items.getSubtypeCount(item_type)``
Returns the number of raw-defined subtypes of the given item type, or *-1* if not applicable.
* ``dfhack.items.getSubtypeDef(item_type, subtype)``
Returns the raw definition for the given item type and subtype, or *nil* if invalid.
* ``dfhack.items.getItemBaseValue(item_type, subtype, material, mat_index)``
Calculates the base value for an item of the specified type and material.
* ``dfhack.items.getValue(item)``
Calculates the Basic Value of an item, as seen in the View Item screen.
* ``dfhack.items.createItem(item_type, item_subtype, mat_type, mat_index, unit)``
Creates an item, similar to the `createitem` plugin.
* ``dfhack.items.checkMandates(item)``
Returns true if the item is free from mandates, or false if mandates prevent trading the item.
* ``dfhack.items.canTrade(item)``
Checks whether the item can be traded.
* ``dfhack.items.canTradeWithContents(item)``
Checks whether the item and all items it contains, if any, can be traded.
* ``dfhack.items.isRouteVehicle(item)``
Checks whether the item is an assigned hauling vehicle.
* ``dfhack.items.isSquadEquipment(item)``
Checks whether the item is assigned to a squad.
.. _lua-maps:
Maps module
-----------
* ``dfhack.maps.getSize()``
Returns map size in blocks: *x, y, z*
* ``dfhack.maps.getTileSize()``
Returns map size in tiles: *x, y, z*
* ``dfhack.maps.getBlock(x,y,z)``
Returns a map block object for given x,y,z in local block coordinates.
* ``dfhack.maps.isValidTilePos(coords)``, or ``isValidTilePos(x,y,z)``
Checks if the given df::coord or x,y,z in local tile coordinates are valid.
* ``dfhack.maps.isTileVisible(coords)``, or ``isTileVisible(x,y,z)``
Checks if the given df::coord or x,y,z in local tile coordinates is visible.
* ``dfhack.maps.getTileBlock(coords)``, or ``getTileBlock(x,y,z)``
Returns a map block object for given df::coord or x,y,z in local tile coordinates.
* ``dfhack.maps.ensureTileBlock(coords)``, or ``ensureTileBlock(x,y,z)``
Like ``getTileBlock``, but if the block is not allocated, try creating it.
* ``dfhack.maps.getTileType(coords)``, or ``getTileType(x,y,z)``
Returns the tile type at the given coordinates, or *nil* if invalid.
* ``dfhack.maps.getTileFlags(coords)``, or ``getTileFlags(x,y,z)``
Returns designation and occupancy references for the given coordinates, or *nil, nil* if invalid.
* ``dfhack.maps.getRegionBiome(region_coord2d)``, or ``getRegionBiome(x,y)``
Returns the biome info struct for the given global map region.
* ``dfhack.maps.enableBlockUpdates(block[,flow,temperature])``
Enables updates for liquid flow or temperature, unless already active.
* ``dfhack.maps.spawnFlow(pos,type,mat_type,mat_index,dimension)``
Spawns a new flow (i.e. steam/mist/dust/etc) at the given pos, and with
the given parameters. Returns it, or *nil* if unsuccessful.
* ``dfhack.maps.getGlobalInitFeature(index)``
Returns the global feature object with the given index.
* ``dfhack.maps.getLocalInitFeature(region_coord2d,index)``
Returns the local feature object with the given region coords and index.
* ``dfhack.maps.getTileBiomeRgn(coords)``, or ``getTileBiomeRgn(x,y,z)``
Returns *x, y* for use with ``getRegionBiome``.
* ``dfhack.maps.getPlantAtTile(pos)``, or ``getPlantAtTile(x,y,z)``
Returns the plant struct that owns the tile at the specified position.
* ``dfhack.maps.canWalkBetween(pos1, pos2)``
Checks if a dwarf may be able to walk between the two tiles,
using a pathfinding cache maintained by the game.
.. note::
This cache is only updated when the game is unpaused, and thus
can get out of date if doors are forbidden or unforbidden, or
tools like `liquids` or `tiletypes` are used. It also cannot possibly
take into account anything that depends on the actual units, like
burrows, or the presence of invaders.
* ``dfhack.maps.hasTileAssignment(tilemask)``
Checks if the tile_bitmask object is not *nil* and contains any set bits; returns *true* or *false*.
* ``dfhack.maps.getTileAssignment(tilemask,x,y)``
Checks if the tile_bitmask object is not *nil* and has the relevant bit set; returns *true* or *false*.
* ``dfhack.maps.setTileAssignment(tilemask,x,y,enable)``
Sets the relevant bit in the tile_bitmask object to the *enable* argument.
* ``dfhack.maps.resetTileAssignment(tilemask[,enable])``
Sets all bits in the mask to the *enable* argument.
Burrows module
--------------
* ``dfhack.burrows.findByName(name)``
Returns the burrow pointer or *nil*.
* ``dfhack.burrows.clearUnits(burrow)``
Removes all units from the burrow.
* ``dfhack.burrows.isAssignedUnit(burrow,unit)``
Checks if the unit is in the burrow.
* ``dfhack.burrows.setAssignedUnit(burrow,unit,enable)``
Adds or removes the unit from the burrow.
* ``dfhack.burrows.clearTiles(burrow)``
Removes all tiles from the burrow.
* ``dfhack.burrows.listBlocks(burrow)``
Returns a table of map block pointers.
* ``dfhack.burrows.isAssignedTile(burrow,tile_coord)``
Checks if the tile is in burrow.
* ``dfhack.burrows.setAssignedTile(burrow,tile_coord,enable)``
Adds or removes the tile from the burrow. Returns *false* if invalid coords.
* ``dfhack.burrows.isAssignedBlockTile(burrow,block,x,y)``
Checks if the tile within the block is in burrow.
* ``dfhack.burrows.setAssignedBlockTile(burrow,block,x,y,enable)``
Adds or removes the tile from the burrow. Returns *false* if invalid coords.
Buildings module
----------------
General
~~~~~~~
* ``dfhack.buildings.getGeneralRef(building, type)``
Searches for a general_ref with the given type.
* ``dfhack.buildings.getSpecificRef(building, type)``
Searches for a specific_ref with the given type.
* ``dfhack.buildings.setOwner(item,unit)``
Replaces the owner of the building. If unit is *nil*, removes ownership.
Returns *false* in case of error.
* ``dfhack.buildings.getSize(building)``
Returns *width, height, centerx, centery*.
* ``dfhack.buildings.findAtTile(pos)``, or ``findAtTile(x,y,z)``
Scans the buildings for the one located at the given tile.
Does not work on civzones. Warning: linear scan if the map
tile indicates there are buildings at it.
* ``dfhack.buildings.findCivzonesAt(pos)``, or ``findCivzonesAt(x,y,z)``
Scans civzones, and returns a lua sequence of those that touch
the given tile, or *nil* if none.
* ``dfhack.buildings.getCorrectSize(width, height, type, subtype, custom, direction)``
Computes correct dimensions for the specified building type and orientation,
using width and height for flexible dimensions.
Returns *is_flexible, width, height, center_x, center_y*.
* ``dfhack.buildings.checkFreeTiles(pos,size[,extents,change_extents,allow_occupied,allow_wall])``
Checks if the rectangle defined by ``pos`` and ``size``, and possibly extents,
can be used for placing a building. If ``change_extents`` is true, bad tiles
are removed from extents. If ``allow_occupied``, the occupancy test is skipped.
Set ``allow_wall`` to true if the building is unhindered by walls (such as an
activity zone).
* ``dfhack.buildings.countExtentTiles(extents,defval)``
Returns the number of tiles included by extents, or defval.
* ``dfhack.buildings.containsTile(building, x, y[, room])``
Checks if the building contains the specified tile, either directly, or as room.
* ``dfhack.buildings.hasSupport(pos,size)``
Checks if a bridge constructed at specified position would have
support from terrain, and thus won't collapse if retracted.
* ``dfhack.buildings.getStockpileContents(stockpile)``
Returns a list of items stored on the given stockpile.
Ignores empty bins, barrels, and wheelbarrows assigned as storage and transport for that stockpile.
* ``dfhack.buildings.getCageOccupants(cage)``
Returns a list of units in the given built cage. Note that this is different
from the list of units assigned to the cage, which can be accessed with
``cage.assigned_units``.
Low-level
~~~~~~~~~
Low-level building creation functions:
* ``dfhack.buildings.allocInstance(pos, type, subtype, custom)``
Creates a new building instance of given type, subtype and custom type,
at specified position. Returns the object, or *nil* in case of an error.
* ``dfhack.buildings.setSize(building, width, height, direction)``
Configures an object returned by ``allocInstance``, using specified
parameters wherever appropriate. If the building has fixed size along
any dimension, the corresponding input parameter will be ignored.
Returns *false* if the building cannot be placed, or *true, width,
height, rect_area, true_area*. Returned width and height are the
final values used by the building; true_area is less than rect_area
if any tiles were removed from designation. You can specify a non-rectangular
designation for building types that support extents by setting the
``room.extents`` bitmap before calling this function. The extents will be
reset, however, if the size returned by this function doesn't match the
input size parameter.
* ``dfhack.buildings.constructAbstract(building)``
Links a fully configured object created by ``allocInstance`` into the
world. The object must be an abstract building, i.e. a stockpile or civzone.
Returns *true*, or *false* if impossible.
* ``dfhack.buildings.constructWithItems(building, items)``
Links a fully configured object created by ``allocInstance`` into the
world for construction, using a list of specific items as material.
Returns *true*, or *false* if impossible.
* ``dfhack.buildings.constructWithFilters(building, job_items)``
Links a fully configured object created by ``allocInstance`` into the
world for construction, using a list of job_item filters as inputs.
Returns *true*, or *false* if impossible. Filter objects are claimed
and possibly destroyed in any case.
Use a negative ``quantity`` field value to auto-compute the amount
from the size of the building.
* ``dfhack.buildings.deconstruct(building)``
Destroys the building, or queues a deconstruction job.
Returns *true* if the building was destroyed and deallocated immediately.
* ``dfhack.buildings.markedForRemoval(building)``
Returns *true* if the building is marked for removal (with :kbd:`x`), *false*
otherwise.
* ``dfhack.buildings.getRoomDescription(building[, unit])``
If the building is a room, returns a description including quality modifiers, e.g. "Royal Bedroom".
Otherwise, returns an empty string.
The unit argument is passed through to DF and may modify the room's value depending on the unit given.
High-level
~~~~~~~~~~
More high-level functions are implemented in lua and can be loaded by
``require('dfhack.buildings')``. See ``hack/lua/dfhack/buildings.lua``.
Among them are:
* ``dfhack.buildings.getFiltersByType(argtable,type,subtype,custom)``
Returns a sequence of lua structures, describing input item filters
suitable for the specified building type, or *nil* if unknown or invalid.
The returned sequence is suitable for use as the ``job_items`` argument
of ``constructWithFilters``.
Uses tables defined in ``buildings.lua``.
Argtable members ``material`` (the default name), ``bucket``, ``barrel``,
``chain``, ``mechanism``, ``screw``, ``pipe``, ``anvil``, ``weapon`` are used to
augment the basic attributes with more detailed information if the
building has input items with the matching name (see the tables for naming details).
Note that it is impossible to *override* any properties this way, only supply those that
are not mentioned otherwise; one exception is that flags2.non_economic
is automatically cleared if an explicit material is specified.
* ``dfhack.buildings.constructBuilding{...}``
Creates a building in one call, using options contained
in the argument table. Returns the building, or *nil, error*.
.. note::
Despite the name, unless the building is abstract,
the function creates it in an 'unconstructed' stage, with
a queued in-game job that will actually construct it. I.e.
the function replicates programmatically what can be done
through the construct building menu in the game ui, except
that it does less environment constraint checking.
The following options can be used:
- ``pos = coordinates``, or ``x = ..., y = ..., z = ...``
Mandatory. Specifies the left upper corner of the building.
- ``type = df.building_type.FOO, subtype = ..., custom = ...``
Mandatory. Specifies the type of the building. Obviously, subtype
and custom are only expected if the type requires them.
- ``fields = { ... }``
Initializes fields of the building object after creation with
``df.assign``. If ``room.extents`` is assigned this way and this function
returns with error, the memory allocated for the extents is freed.
- ``width = ..., height = ..., direction = ...``
Sets size and orientation of the building. If it is
fixed-size, specified dimensions are ignored.
- ``full_rectangle = true``
For buildings like stockpiles or farm plots that can normally
accomodate individual tile exclusion, forces an error if any
tiles within the specified width*height are obstructed.
- ``items = { item, item ... }``, or ``filters = { {...}, {...}... }``
Specifies explicit items or item filters to use in construction.
It is the job of the user to ensure they are correct for the building type.
- ``abstract = true``
Specifies that the building is abstract and does not require construction.
Required for stockpiles and civzones; an error otherwise.
- ``material = {...}, mechanism = {...}, ...``
If none of ``items``, ``filter``, or ``abstract`` is used,
the function uses ``getFiltersByType`` to compute the input
item filters, and passes the argument table through. If no filters
can be determined this way, ``constructBuilding`` throws an error.
Constructions module
--------------------
* ``dfhack.constructions.designateNew(pos,type,item_type,mat_index)``
Designates a new construction at given position. If there already is
a planned but not completed construction there, changes its type.
Returns *true*, or *false* if obstructed.
Note that designated constructions are technically buildings.
* ``dfhack.constructions.designateRemove(pos)``, or ``designateRemove(x,y,z)``
If there is a construction or a planned construction at the specified
coordinates, designates it for removal, or instantly cancels the planned one.
Returns *true, was_only_planned* if removed; or *false* if none found.
Kitchen module
--------------
* ``dfhack.kitchen.findExclusion(type, item_type, item_subtype, mat_type, mat_index)``
Finds a kitchen exclusion in the vectors in ``df.global.ui.kitchen``. Returns
-1 if not found.
* ``type`` is a ``df.kitchen_exc_type``, i.e. ``df.kitchen_exc_type.Cook`` or
``df.kitchen_exc_type.Brew``.
* ``item_type`` is a ``df.item_type``
* ``item_subtype``, ``mat_type``, and ``mat_index`` are all numeric
* ``dfhack.kitchen.addExclusion(type, item_type, item_subtype, mat_type, mat_index)``
* ``dfhack.kitchen.removeExclusion(type, item_type, item_subtype, mat_type, mat_index)``
Adds or removes a kitchen exclusion, using the same parameters as
``findExclusion``. Both return ``true`` on success and ``false`` on failure,
e.g. when adding an exclusion that already exists or removing one that does
not.
Screen API
----------
The screen module implements support for drawing to the tiled screen of the game.
Note that drawing only has any effect when done from callbacks, so it can only
be feasibly used in the `core context <lua-core-context>`.
.. contents::
:local:
Basic painting functions
~~~~~~~~~~~~~~~~~~~~~~~~
Common parameters to these functions include:
* ``x``, ``y``: screen coordinates in tiles; the upper left corner of the screen
is ``x = 0, y = 0``
* ``pen``: a `pen object <lua-screen-pen>`
* ``map``: a boolean indicating whether to draw to a separate map buffer
(defaults to false, which is suitable for off-map text or a screen that hides
the map entirely). Note that only third-party plugins like TWBT currently
implement a separate map buffer. If no such plugins are enabled, passing
``true`` has no effect. However, this parameter should still be used to ensure
that scripts work properly with such plugins.
Functions:
* ``dfhack.screen.getWindowSize()``
Returns *width, height* of the screen.
* ``dfhack.screen.getMousePos()``
Returns *x,y* of the tile the mouse is over.
* ``dfhack.screen.inGraphicsMode()``
Checks if [GRAPHICS:YES] was specified in init.
* ``dfhack.screen.paintTile(pen,x,y[,char,tile,map])``
Paints a tile using given parameters. `See below <lua-screen-pen>` for a description of ``pen``.
Returns *false* on error, e.g. if coordinates are out of bounds
* ``dfhack.screen.readTile(x,y[,map])``
Retrieves the contents of the specified tile from the screen buffers.
Returns a `pen object <lua-screen-pen>`, or *nil* if invalid or TrueType.
* ``dfhack.screen.paintString(pen,x,y,text[,map])``
Paints the string starting at *x,y*. Uses the string characters
in sequence to override the ``ch`` field of `pen <lua-screen-pen>`.
Returns *true* if painting at least one character succeeded.
* ``dfhack.screen.fillRect(pen,x1,y1,x2,y2[,map])``
Fills the rectangle specified by the coordinates with the given `pen <lua-screen-pen>`.
Returns *true* if painting at least one character succeeded.
* ``dfhack.screen.findGraphicsTile(pagename,x,y)``
Finds a tile from a graphics set (i.e. the raws used for creatures),
if in graphics mode and loaded.
Returns: *tile, tile_grayscale*, or *nil* if not found.
The values can then be used for the *tile* field of *pen* structures.
* ``dfhack.screen.clear()``
Fills the screen with blank background.
* ``dfhack.screen.invalidate()``
Requests repaint of the screen by setting a flag. Unlike other
functions in this section, this may be used at any time.
* ``dfhack.screen.getKeyDisplay(key)``
Returns the string that should be used to represent the given
logical keybinding on the screen in texts like "press Key to ...".
* ``dfhack.screen.keyToChar(key)``
Returns the integer character code of the string input
character represented by the given logical keybinding,
or *nil* if not a string input key.
* ``dfhack.screen.charToKey(charcode)``
Returns the keybinding representing the given string input
character, or *nil* if impossible.
.. _lua-screen-pen:
Pen API
~~~~~~~
The ``pen`` argument used by ``dfhack.screen`` functions may be represented by
a table with the following possible fields:
``ch``
Provides the ordinary tile character, as either a 1-character string or a number.
Can be overridden with the ``char`` function parameter.
``fg``
Foreground color for the ordinary tile. Defaults to COLOR_GREY (7).
``bg``
Background color for the ordinary tile. Defaults to COLOR_BLACK (0).
``bold``
Bright/bold text flag. If *nil*, computed based on (fg & 8); fg is masked to 3 bits.
Otherwise should be *true/false*.
``tile``
Graphical tile id. Ignored unless [GRAPHICS:YES] was in init.txt.
``tile_color = true``
Specifies that the tile should be shaded with *fg/bg*.
``tile_fg, tile_bg``
If specified, overrides *tile_color* and supplies shading colors directly.
Alternatively, it may be a pre-parsed native object with the following API:
* ``dfhack.pen.make(base[,pen_or_fg,bg,bold])``
Creates a new pre-parsed pen by combining its arguments according to the
following rules:
1. The ``base`` argument may be a pen object, a pen table as specified above,
or a single color value. In the single value case, it is split into
``fg`` and ``bold`` properties, and others are initialized to 0.
This argument will be converted to a pre-parsed object and returned
if there are no other arguments.
2. If the ``pen_or_fg`` argument is specified as a table or object, it
completely replaces the base, and is returned instead of it.
3. Otherwise, the non-nil subset of the optional arguments is used
to update the ``fg``, ``bg`` and ``bold`` properties of the base.
If the ``bold`` flag is *nil*, but *pen_or_fg* is a number, ``bold``
is deduced from it like in the simple base case.
This function always returns a new pre-parsed pen, or *nil*.
* ``dfhack.pen.parse(base[,pen_or_fg,bg,bold])``
Exactly like the above function, but returns ``base`` or ``pen_or_fg``
directly if they are already a pre-parsed native object.
* ``pen.property``, ``pen.property = value``, ``pairs(pen)``
Pre-parsed pens support reading and setting their properties,
but don't behave exactly like a simple table would; for instance,
assigning to ``pen.tile_color`` also resets ``pen.tile_fg`` and
``pen.tile_bg`` to *nil*.
Screen management
~~~~~~~~~~~~~~~~~
In order to actually be able to paint to the screen, it is necessary
to create and register a viewscreen (basically a modal dialog) with
the game.
.. warning::
As a matter of policy, in order to avoid user confusion, all
interface screens added by dfhack should bear the "DFHack" signature.
Screens are managed with the following functions:
* ``dfhack.screen.show(screen[,below])``
Displays the given screen, possibly placing it below a different one.
The screen must not be already shown. Returns *true* if success.
* ``dfhack.screen.dismiss(screen[,to_first])``
Marks the screen to be removed when the game enters its event loop.
If ``to_first`` is *true*, all screens up to the first one will be deleted.
* ``dfhack.screen.isDismissed(screen)``
Checks if the screen is already marked for removal.
Apart from a native viewscreen object, these functions accept a table
as a screen. In this case, ``show`` creates a new native viewscreen
that delegates all processing to methods stored in that table.
.. note::
* The `gui.Screen class <lua-gui-screen>` provides stubs for all of the
functions listed below, and its use is recommended
* Lua-implemented screens are only supported in the `core context <lua-core-context>`.
Supported callbacks and fields are:
* ``screen._native``
Initialized by ``show`` with a reference to the backing viewscreen
object, and removed again when the object is deleted.
* ``function screen:onShow()``
Called by ``dfhack.screen.show`` if successful.
* ``function screen:onDismiss()``
Called by ``dfhack.screen.dismiss`` if successful.
* ``function screen:onDestroy()``
Called from the destructor when the viewscreen is deleted.
* ``function screen:onResize(w, h)``
Called before ``onRender`` or ``onIdle`` when the window size has changed.
* ``function screen:onRender()``
Called when the viewscreen should paint itself. This is the only context
where the above painting functions work correctly.
If omitted, the screen is cleared; otherwise it should do that itself.
In order to make a see-through dialog, call ``self._native.parent:render()``.
* ``function screen:onIdle()``
Called every frame when the screen is on top of the stack.
* ``function screen:onHelp()``
Called when the help keybinding is activated (usually '?').
* ``function screen:onInput(keys)``
Called when keyboard or mouse events are available.
If any keys are pressed, the keys argument is a table mapping them to *true*.
Note that this refers to logical keybingings computed from real keys via
options; if multiple interpretations exist, the table will contain multiple keys.
The table also may contain special keys:
``_STRING``
Maps to an integer in range 0-255. Duplicates a separate "STRING_A???" code for convenience.
``_MOUSE_L, _MOUSE_R``
If the left or right mouse button is being pressed.
``_MOUSE_L_DOWN, _MOUSE_R_DOWN``
If the left or right mouse button was just pressed.
If this method is omitted, the screen is dismissed on receival of the ``LEAVESCREEN`` key.
* ``function screen:onGetSelectedUnit()``
* ``function screen:onGetSelectedItem()``
* ``function screen:onGetSelectedJob()``
* ``function screen:onGetSelectedBuilding()``
Implement these to provide a return value for the matching
``dfhack.gui.getSelected...`` function.
PenArray class
--------------
Screens that require significant computation in their onRender() method can use
a ``dfhack.penarray`` instance to cache their output.
* ``dfhack.penarray.new(w, h)``
Creates a new penarray instance with an internal buffer of ``w * h`` tiles.
These dimensions currently cannot be changed after a penarray is instantiated.
* ``penarray:clear()``
Clears the internal buffer, similar to ``dfhack.screen.clear()``.
* ``penarray:get_dims()``
Returns the x and y dimensions of the internal buffer.
* ``penarray:get_tile(x, y)``
Returns a pen corresponding to the tile at (``x``, ``y``) in the internal buffer.
Note that indices are 0-based.
* ``penarray:set_tile(x, y, pen)``
Sets the tile at (``x``, ``y``) in the internal buffer to the pen given.
* ``penarray:draw(x, y, w, h, bufferx, buffery)``
Draws the contents of the internal buffer, beginning at
(``bufferx``, ``buffery``) and spanning ``w`` columns and ``h`` rows, to the
screen starting at (``x``, ``y``). Any invalid screen and buffer coordinates
are skipped.
``bufferx`` and ``buffery`` default to 0.
Filesystem module
-----------------
Most of these functions return ``true`` on success and ``false`` on failure,
unless otherwise noted.
* ``dfhack.filesystem.exists(path)``
Returns ``true`` if ``path`` exists.
* ``dfhack.filesystem.isfile(path)``
Returns ``true`` if ``path`` exists and is a file.
* ``dfhack.filesystem.isdir(path)``
Returns ``true`` if ``path`` exists and is a directory.
* ``dfhack.filesystem.getcwd()``
Returns the current working directory. To retrieve the DF path, use ``dfhack.getDFPath()`` instead.
* ``dfhack.filesystem.chdir(path)``
Changes the current directory to ``path``. Use with caution.
* ``dfhack.filesystem.restore_cwd()``
Restores the current working directory to what it was when DF started.
* ``dfhack.filesystem.get_initial_cwd()``
Returns the value of the working directory when DF was started.
* ``dfhack.filesystem.mkdir(path)``
Creates a new directory. Returns ``false`` if unsuccessful, including if ``path`` already exists.
* ``dfhack.filesystem.mkdir_recursive(path)``
Creates a new directory, including any intermediate directories that don't exist yet.
Returns ``true`` if the folder was created or already existed, or ``false`` if unsuccessful.
* ``dfhack.filesystem.rmdir(path)``
Removes a directory. Only works if the directory is already empty.
* ``dfhack.filesystem.mtime(path)``
Returns the modification time (in seconds) of the file or directory specified by ``path``,
or -1 if ``path`` does not exist. This depends on the system clock and should only be used locally.
* ``dfhack.filesystem.atime(path)``
* ``dfhack.filesystem.ctime(path)``
Return values vary across operating systems - return the ``st_atime`` and ``st_ctime``
fields of a C++ stat struct, respectively.
* ``dfhack.filesystem.listdir(path)``
Lists files/directories in a directory. Returns ``{}`` if ``path`` does not exist.
* ``dfhack.filesystem.listdir_recursive(path [, depth = 10[, include_prefix = true]])``
Lists all files/directories in a directory and its subdirectories. All directories
are listed before their contents. Returns a table with subtables of the format::
{path: 'path to file', isdir: true|false}
Note that ``listdir()`` returns only the base name of each directory entry, while
``listdir_recursive()`` returns the initial path and all components following it
for each entry. Set ``include_prefix`` to false if you don't want the ``path``
string prepended to the returned filenames.
Console API
-----------
* ``dfhack.console.clear()``
Clears the console; equivalent to the ``cls`` built-in command.
* ``dfhack.console.flush()``
Flushes all output to the console. This can be useful when printing text that
does not end in a newline but should still be displayed.
.. _lua-api-internal:
Internal API
------------
These functions are intended for the use by dfhack developers,
and are only documented here for completeness:
* ``dfhack.internal.getPE()``
Returns the PE timestamp of the DF executable (only on Windows)
* ``dfhack.internal.getMD5()``
Returns the MD5 of the DF executable (only on OS X and Linux)
* ``dfhack.internal.getAddress(name)``
Returns the global address ``name``, or *nil*.
* ``dfhack.internal.setAddress(name, value)``
Sets the global address ``name``. Returns the value of ``getAddress`` before the change.
* ``dfhack.internal.getVTable(name)``
Returns the pre-extracted vtable address ``name``, or *nil*.
* ``dfhack.internal.getImageBase()``
Returns the mmap base of the executable.
* ``dfhack.internal.getRebaseDelta()``
Returns the ASLR rebase offset of the DF executable.
* ``dfhack.internal.adjustOffset(offset[,to_file])``
Returns the re-aligned offset, or *nil* if invalid.
If ``to_file`` is true, the offset is adjusted from memory to file.
This function returns the original value everywhere except windows.
* ``dfhack.internal.getMemRanges()``
Returns a sequence of tables describing virtual memory ranges of the process.
* ``dfhack.internal.patchMemory(dest,src,count)``
Like memmove below, but works even if dest is read-only memory, e.g. code.
If destination overlaps a completely invalid memory region, or another error
occurs, returns false.
* ``dfhack.internal.patchBytes(write_table[, verify_table])``
The first argument must be a lua table, which is interpreted as a mapping from
memory addresses to byte values that should be stored there. The second argument
may be a similar table of values that need to be checked before writing anything.
The function takes care to either apply all of ``write_table``, or none of it.
An empty ``write_table`` with a nonempty ``verify_table`` can be used to reasonably
safely check if the memory contains certain values.
Returns *true* if successful, or *nil, error_msg, address* if not.
* ``dfhack.internal.memmove(dest,src,count)``
Wraps the standard memmove function. Accepts both numbers and refs as pointers.
* ``dfhack.internal.memcmp(ptr1,ptr2,count)``
Wraps the standard memcmp function.
* ``dfhack.internal.memscan(haystack,count,step,needle,nsize)``
Searches for ``needle`` of ``nsize`` bytes in ``haystack``,
using ``count`` steps of ``step`` bytes.
Returns: *step_idx, sum_idx, found_ptr*, or *nil* if not found.
* ``dfhack.internal.diffscan(old_data, new_data, start_idx, end_idx, eltsize[, oldval, newval, delta])``
Searches for differences between buffers at ptr1 and ptr2, as integers of size eltsize.
The oldval, newval or delta arguments may be used to specify additional constraints.
Returns: *found_index*, or *nil* if end reached.
* ``dfhack.internal.getDir(path)``
Lists files/directories in a directory.
Returns: *file_names* or empty table if not found. Identical to ``dfhack.filesystem.listdir(path)``.
* ``dfhack.internal.strerror(errno)``
Wraps strerror() - returns a string describing a platform-specific error code
* ``dfhack.internal.addScriptPath(path, search_before)``
Registers ``path`` as a `script path <script-paths>`.
If ``search_before`` is passed and ``true``, the path will be searched before
the default paths (e.g. ``raw/scripts``, ``hack/scripts``); otherwise, it will
be searched after.
Returns ``true`` if successful or ``false`` otherwise (e.g. if the path does
not exist or has already been registered).
* ``dfhack.internal.removeScriptPath(path)``
Removes ``path`` from the list of `script paths <script-paths>` and returns
``true`` if successful.
* ``dfhack.internal.getScriptPaths()``
Returns the list of `script paths <script-paths>` in the order they are
searched, including defaults. (This can change if a world is loaded.)
* ``dfhack.internal.findScript(name)``
Searches `script paths <script-paths>` for the script ``name`` and returns the
path of the first file found, or ``nil`` on failure.
.. note::
This requires an extension to be specified (``.lua`` or ``.rb``) - use
``dfhack.findScript()`` to include the ``.lua`` extension automatically.
* ``dfhack.internal.runCommand(command[, use_console])``
Runs a DFHack command with the core suspended. Used internally by the
``dfhack.run_command()`` family of functions.
- ``command``: either a table of strings or a single string which is parsed by
the default console tokenization strategy (not recommended)
- ``use_console``: if true, output is sent directly to the DFHack console
Returns a table with a ``status`` key set to a ``command_result`` constant
(``status = CR_OK`` indicates success). Additionally, if ``use_console`` is
not true, enumerated table entries of the form ``{color, text}`` are included,
e.g. ``result[1][0]`` is the color of the first piece of text printed (a
``COLOR_`` constant). These entries can be iterated over with ``ipairs()``.
* ``dfhack.internal.md5(string)``
Returns the MD5 hash of the given string.
* ``dfhack.internal.md5File(filename[,first_kb])``
Computes the MD5 hash of the given file. Returns ``hash, length`` on success
(where ``length`` is the number of bytes read from the file), or ``nil,
error`` on failure.
If the parameter ``first_kb`` is specified and evaluates to ``true``, and the
hash was computed successfully, a table containing the first 1024 bytes of the
file is returned as the third return value.
* ``dfhack.internal.threadid()``
Returns a numeric identifier of the current thread.
.. _lua-core-context:
Core interpreter context
========================
While plugins can create any number of interpreter instances,
there is one special context managed by the DFHack core. It is the
only context that can receive events from DF and plugins.
Core context specific functions:
* ``dfhack.is_core_context``
Boolean value; *true* in the core context.
* ``dfhack.timeout(time,mode,callback)``
Arranges for the callback to be called once the specified
period of time passes. The ``mode`` argument specifies the
unit of time used, and may be one of ``'frames'`` (raw FPS),
``'ticks'`` (unpaused FPS), ``'days'``, ``'months'``,
``'years'`` (in-game time). All timers other than
``'frames'`` are cancelled when the world is unloaded,
and cannot be queued until it is loaded again.
Returns the timer id, or *nil* if unsuccessful due to
world being unloaded.
* ``dfhack.timeout_active(id[,new_callback])``
Returns the active callback with the given id, or *nil*
if inactive or nil id. If called with 2 arguments, replaces
the current callback with the given value, if still active.
Using ``timeout_active(id,nil)`` cancels the timer.
* ``dfhack.onStateChange.foo = function(code)``
Creates a handler for state change events. Receives the same
`SC_ codes <lua-globals>` as ``plugin_onstatechange()`` in C++.
Event type
----------
An event is a native object transparently wrapping a lua table,
and implementing a __call metamethod. When it is invoked, it loops
through the table with next and calls all contained values.
This is intended as an extensible way to add listeners.
This type itself is available in any context, but only the
`core context <lua-core-context>` has the actual events defined by C++ code.
Features:
* ``dfhack.event.new()``
Creates a new instance of an event.
* ``event[key] = function``
Sets the function as one of the listeners. Assign *nil* to remove it.
.. note::
The ``df.NULL`` key is reserved for the use by
the C++ owner of the event; it is an error to try setting it.
* ``#event``
Returns the number of non-nil listeners.
* ``pairs(event)``
Iterates over all listeners in the table.
* ``event(args...)``
Invokes all listeners contained in the event in an arbitrary
order using ``dfhack.safecall``.
===========
Lua Modules
===========
.. contents::
:local:
DFHack sets up the lua interpreter so that the built-in ``require``
function can be used to load shared lua code from :file:`hack/lua/`.
The ``dfhack`` namespace reference itself may be obtained via
``require('dfhack')``, although it is initially created as a
global by C++ bootstrap code.
The following module management functions are provided:
* ``mkmodule(name)``
Creates an environment table for the module. Intended to be used as::
local _ENV = mkmodule('foo')
...
return _ENV
If called the second time, returns the same table; thus providing reload support.
* ``reload(name)``
Reloads a previously ``require``-d module *"name"* from the file.
Intended as a help for module development.
* ``dfhack.BASE_G``
This variable contains the root global environment table, which is
used as a base for all module and script environments. Its contents
should be kept limited to the standard Lua library and API described
in this document.
.. _lua-globals:
Global environment
==================
A number of variables and functions are provided in the base global
environment by the mandatory init file dfhack.lua:
* Color constants
These are applicable both for ``dfhack.color()`` and color fields
in DF functions or structures::
COLOR_RESET, COLOR_BLACK, COLOR_BLUE, COLOR_GREEN, COLOR_CYAN,
COLOR_RED, COLOR_MAGENTA, COLOR_BROWN, COLOR_GREY, COLOR_DARKGREY,
COLOR_LIGHTBLUE, COLOR_LIGHTGREEN, COLOR_LIGHTCYAN, COLOR_LIGHTRED,
COLOR_LIGHTMAGENTA, COLOR_YELLOW, COLOR_WHITE
* State change event codes, used by ``dfhack.onStateChange``
Available only in the `core context <lua-core-context>`, as is the event itself:
SC_WORLD_LOADED, SC_WORLD_UNLOADED, SC_MAP_LOADED,
SC_MAP_UNLOADED, SC_VIEWSCREEN_CHANGED, SC_CORE_INITIALIZED
* Command result constants (equivalent to ``command_result`` in C++), used by
``dfhack.run_command()`` and related functions:
CR_OK, CR_LINK_FAILURE, CR_NEEDS_CONSOLE, CR_NOT_IMPLEMENTED, CR_FAILURE,
CR_WRONG_USAGE, CR_NOT_FOUND
* Functions already described above
safecall, qerror, mkmodule, reload
* Miscellaneous constants
``NEWLINE``, ``COMMA``, ``PERIOD``
evaluate to the relevant character strings.
``DEFAULT_NIL``
is an unspecified unique token used by the class module below.
* ``printall(obj)``
If the argument is a lua table or DF object reference, prints all fields.
* ``printall_recurse(obj)``
If the argument is a lua table or DF object reference, prints all fields recursively.
* ``copyall(obj)``
Returns a shallow copy of the table or reference as a lua table.
* ``pos2xyz(obj)``
The object must have fields x, y and z. Returns them as 3 values.
If obj is *nil*, or x is -30000 (the usual marker for undefined
coordinates), returns *nil*.
* ``xyz2pos(x,y,z)``
Returns a table with x, y and z as fields.
* ``same_xyz(a,b)``
Checks if ``a`` and ``b`` have the same x, y and z fields.
* ``get_path_xyz(path,i)``
Returns ``path.x[i], path.y[i], path.z[i]``.
* ``pos2xy(obj)``, ``xy2pos(x,y)``, ``same_xy(a,b)``, ``get_path_xy(a,b)``
Same as above, but for 2D coordinates.
* ``safe_index(obj,index...)``
Walks a sequence of dereferences, which may be represented by numbers or strings.
Returns *nil* if any of obj or indices is *nil*, or a numeric index is out of array bounds.
* ``ensure_key(t, key[, default_value])``
If the Lua table ``t`` doesn't include the specified ``key``, ``t[key]`` is
set to the value of ``default_value``, which defaults to ``{}`` if not set.
The new or existing value of ``t[key]`` is then returned.
.. _lua-string:
String class extentions
-----------------------
DFHack extends Lua's basic string class to include a number of convenience
functions. These are invoked just like standard string functions, e.g.::
if imastring:startswith('imaprefix') then
* ``string:startswith(prefix)``
Returns ``true`` if the first ``#prefix`` characters of the string are equal
to ``prefix``. Note that ``prefix`` is not interpreted as a pattern.
* ``string:endswith(suffix)``
Returns ``true`` if the last ``#suffix`` characters of the string are equal
to ``suffix``. Note that ``suffix`` is not interpreted as a pattern.
* ``string:split([delimiter[, plain]])``
Split a string by the given delimiter. If no delimiter is specified, space
(``' '``) is used. The delimter is treated as a pattern unless a ``plain`` is
specified and set to ``true``. To treat multiple successive delimiter
characters as a single delimiter, e.g. to avoid getting empty string elements,
pass a pattern like ``' +'``. Be aware that passing patterns that match empty
strings (like ``' *'``) will result in improper string splits.
* ``string:trim()``
Removes spaces (i.e. everything that matches ``'%s'``) from the start and end
of a string. Spaces between non-space characters are left untouched.
* ``string:wrap([width])``
Inserts newlines into a string so no individual line exceeds the given width.
Lines are split at space-separated word boundaries. Any existing newlines are
kept in place. If a single word is longer than width, it is split over
multiple lines. If width is not specified, 72 is used.
* ``string:escape_pattern()``
Escapes regex special chars in a string. E.g. ``'a+b'`` -> ``'a%+b'``.
utils
=====
* ``utils.compare(a,b)``
Comparator function; returns *-1* if a<b, *1* if a>b, *0* otherwise.
* ``utils.compare_name(a,b)``
Comparator for names; compares empty string last.
* ``utils.is_container(obj)``
Checks if obj is a container ref.
* ``utils.make_index_sequence(start,end)``
Returns a lua sequence of numbers in start..end.
* ``utils.make_sort_order(data, ordering)``
Computes a sorted permutation of objects in data, as a table of integer
indices into the data sequence. Uses ``data.n`` as input length
if present.
The ordering argument is a sequence of ordering specs, represented
as lua tables with following possible fields:
ord.key = *function(value)*
Computes comparison key from input data value. Not called on nil.
If omitted, the comparison key is the value itself.
ord.key_table = *function(data)*
Computes a key table from the data table in one go.
ord.compare = *function(a,b)*
Comparison function. Defaults to ``utils.compare`` above.
Called on non-nil keys; nil sorts last.
ord.nil_first = *true/false*
If true, nil keys are sorted first instead of last.
ord.reverse = *true/false*
If true, sort non-nil keys in descending order.
For every comparison during sorting the specs are applied in
order until an unambiguous decision is reached. Sorting is stable.
Example of sorting a sequence by field foo::
local spec = { key = function(v) return v.foo end }
local order = utils.make_sort_order(data, { spec })
local output = {}
for i = 1,#order do output[i] = data[order[i]] end
Separating the actual reordering of the sequence in this
way enables applying the same permutation to multiple arrays.
This function is used by the sort plugin.
* ``for link,item in utils.listpairs(list)``
Iterates a df-list structure, for example ``df.global.world.job_list``.
* ``utils.assign(tgt, src)``
Does a recursive assignment of src into tgt.
Uses ``df.assign`` if tgt is a native object ref; otherwise
recurses into lua tables.
* ``utils.clone(obj, deep)``
Performs a shallow, or semi-deep copy of the object as a lua table tree.
The deep mode recurses into lua tables and subobjects, except pointers
to other heap objects.
Null pointers are represented as ``df.NULL``. Zero-based native containers
are converted to 1-based lua sequences.
* ``utils.clone_with_default(obj, default, force)``
Copies the object, using the ``default`` lua table tree
as a guide to which values should be skipped as uninteresting.
The ``force`` argument makes it always return a non-*nil* value.
* ``utils.parse_bitfield_int(value, type_ref)``
Given an int ``value``, and a bitfield type in the ``df`` tree,
it returns a lua table mapping the enabled bit keys to *true*,
unless value is 0, in which case it returns *nil*.
* ``utils.list_bitfield_flags(bitfield[, list])``
Adds all enabled bitfield keys to ``list`` or a newly-allocated
empty sequence, and returns it. The ``bitfield`` argument may
be *nil*.
* ``utils.sort_vector(vector,field,cmpfun)``
Sorts a native vector or lua sequence using the comparator function.
If ``field`` is not *nil*, applies the comparator to the field instead
of the whole object.
* ``utils.linear_index(vector,key[,field])``
Searches for ``key`` in the vector, and returns *index, found_value*,
or *nil* if none found.
* ``utils.binsearch(vector,key,field,cmpfun,min,max)``
Does a binary search in a native vector or lua sequence for
``key``, using ``cmpfun`` and ``field`` like sort_vector.
If ``min`` and ``max`` are specified, they are used as the
search subrange bounds.
If found, returns *item, true, idx*. Otherwise returns
*nil, false, insert_idx*, where *insert_idx* is the correct
insertion point.
* ``utils.insert_sorted(vector,item,field,cmpfun)``
Does a binary search, and inserts item if not found.
Returns *did_insert, vector[idx], idx*.
* ``utils.insert_or_update(vector,item,field,cmpfun)``
Like ``insert_sorted``, but also assigns the item into
the vector cell if insertion didn't happen.
As an example, you can use this to set skill values::
utils.insert_or_update(soul.skills, {new=true, id=..., rating=...}, 'id')
(For an explanation of ``new=true``, see `lua-api-table-assignment`)
* ``utils.erase_sorted_key(vector,key,field,cmpfun)``
Removes the item with the given key from the list. Returns: *did_erase, vector[idx], idx*.
* ``utils.erase_sorted(vector,item,field,cmpfun)``
Exactly like ``erase_sorted_key``, but if field is specified, takes the key from ``item[field]``.
* ``utils.call_with_string(obj,methodname,...)``
Allocates a temporary string object, calls ``obj:method(tmp,...)``, and
returns the value written into the temporary after deleting it.
* ``utils.getBuildingName(building)``
Returns the string description of the given building.
* ``utils.getBuildingCenter(building)``
Returns an x/y/z table pointing at the building center.
* ``utils.split_string(string, delimiter)``
Splits the string by the given delimiter, and returns a sequence of results.
* ``utils.prompt_yes_no(prompt, default)``
Presents a yes/no prompt to the user. If ``default`` is not *nil*,
allows just pressing Enter to submit the default choice.
If the user enters ``'abort'``, throws an error.
* ``utils.prompt_input(prompt, checkfun, quit_str)``
Presents a prompt to input data, until a valid string is entered.
Once ``checkfun(input)`` returns *true, ...*, passes the values
through. If the user enters the quit_str (defaults to ``'~~~'``),
throws an error.
* ``utils.check_number(text)``
A ``prompt_input`` ``checkfun`` that verifies a number input.
argparse
========
The ``argparse`` module provides functions to help scripts process commandline
parameters.
* ``argparse.processArgs(args, validArgs)``
A basic commandline processing function with simple syntax, useful if your
script doesn't need the more advanced features of
``argparse.processArgsGetopt()``.
If ``validArgs`` is specified, it should contain a set of valid option names
(without the leading dashes). For example::
argparse.processArgs(args, utils.invert{'opt1', 'opt2', 'opt3'})
``processArgs`` returns a map of option names it found in ``args`` to:
- the token that came after the option
- ``''`` if the next token was another option
- a list of strings if the next token was ``'['`` (see below)
Options in ``args`` from the commandline can be prefixed with either one dash
(``'-'``) or two dashes (``'--'``). The user can add a backslash before the
dash to allow a string to be identified as an option value instead of another
option. For example: ``yourscript --opt1 \-arg1``.
If a ``'['`` token is found in ``args``, the subsequent tokens will be
interpreted as elements of a list until the matching closing ``']'`` is found.
Brackets can be nested, but the inner brackets will be added to the list of
tokens as literal ``'['`` and ``']'`` strings.
Example commandlines::
yourscript --optName --opt2
yourscript --optName value
yourscript --optName [ list of values ]
yourscript --optName [ list of [ nested values ] [ in square brackets ] ]
yourscript --optName \--value
Note that ``processArgs`` does not support non-option ("positional")
parameters. They are supported by ``processArgsGetopt`` (see below).
* ``argparse.processArgsGetopt(args, optionActions)``
A fully-featured commandline processing function, with behavior based on the
popular ``getopt`` library. You would use this instead of the simpler
``processArgs`` function if any of the following are true:
* You want both short (e.g. ``-f``) and aliased long-form (e.g.
``--filename``) options
* You have commandline components that are not arguments to options (e.g. you
want to run your script like ``yourscript command --verbose arg1 arg2 arg3``
instead of
``yourscript command --verbose --opt1 arg1 --opt2 arg2 --opt3 arg3)``.
* You want the convenience of combining options into shorter strings (e.g.
``'-abcarg'`` instead of ``'-a -b -c arg``)
* You want to be able to parse and validate the option arguments as the
commandline is being processed, as opposed to validating everything after
commandline processing is complete.
Commandlines processed by ``processArgsGetopt`` can have both "short" and
"long" options, with each short option often having a long-form alias that
behaves exactly the same as the short form. Short options have properties that
make them very easy to type quickly by users who are familiar with your script
options. Long options, on the other hand, are easily understandable by
everyone and are useful in places where clarity is more important than
brevity, e.g. in example commands. Each option can be configured to take an
argument, which will be the string token that follows the option name on the
commandline.
Short options are a single letter long and are specified on a commandline by
prefixing them with a single dash (e.g. the short option ``a`` would appear
on the commandline as ``-a``). Multiple successive short options that do not
take arguments can be combined into a single option string (e.g. ``'-abc'``
instead of ``'-a -b -c'``). Moreover, the argument for a short option can be
appended directly to the single-letter option without an intervening space
(e.g. ``-d param`` can be written as ``-dparam``). These two convenience
shorthand forms can be combined, allowing groups of short parameters to be
written together, as long as at most the last short option takes an argument
(e.g. combining the previous two examples into ``-abcdparam``)
Long options focus on clarity. They are usually entire words, or several words
combined with hypens (``-``) or underscores (``_``). If they take an argument,
the argument can be separated from the option name by a space or an equals
sign (``=``). For example, the following two commandlines are equivalent:
``yourscript --style pretty`` and ``yourscript --style=pretty``.
Another reason to use long options is if they represent an esoteric parameter
that you don't expect to be commonly used and that you don't want to "waste" a
single-letter option on. In this case, you can define a long option without a
corresponding short option.
``processArgsGetopt`` takes two parameters::
args: list of space-separated strings the user wrote on the commandline
optionActions: list of option specifications
and returns a list of positional parameters -- that is, all strings that are
neither options nor argruments to options. Options and positional parameters
can appear in any order on the commandline, as long as arguments to options
immediately follow the option itself.
Each option specification in ``optionActions`` has the following format:
``{shortOptionName, longOptionAlias, hasArg=boolean, handler=fn}``
* ``shortOptionName`` is a one-character string (or ``''`` or ``nil`` if the
parameter only has a long form). Numbers cannot be short options, and
negative numbers (e.g. ``'-10'``) will be interpreted as positional
parameters and returned in the positional parameters list.
* ``longOptionAlias`` is an optional longer form of the short option name. If
no short option name is specified, then this element is required.
* ``hasArg`` indicates whether the handler function for the option takes a
parameter.
* ``handler`` is the handler function for the option. If ``hasArg`` is
``true`` then the next token on the commandline is passed to the handler
function as an argument.
Example usage::
local args = {...}
local open_readonly, filename = false, nil -- set defaults
local positionals = argparse.processArgsGetopt(args, {
{'r', handler=function() open_readonly = true end},
{'f', 'filename', hasArg=true,
handler=function(optarg) filename = optarg end}
})
In this example, if ``args`` is ``{'first', '-rf', 'fname', 'second'}`` or,
equivalently, ``{'first', '-r', '--filename', 'myfile.txt', 'second'}`` (note
the double dash in front of the long option alias), then ``open_readonly``
will be ``true``, ``filename`` will be ``'myfile.txt'`` and ``positionals``
will be ``{'first', 'second'}``.
* ``argparse.stringList(arg, arg_name, list_length)``
Parses a comma-separated sequence of strings and returns a lua list. Leading
and trailing spaces are trimmed from the strings. If ``arg_name`` is
specified, it is used to make error messages more useful. If ``list_length``
is specified and greater than ``0``, then exactly that number of elements must
be found or the function will error. Example::
stringList('hello , world,alist', 'words') => {'hello', 'world', 'alist'}
* ``argparse.numberList(arg, arg_name, list_length)``
Parses a comma-separated sequence of numeric strings and returns a list of
the discovered numbers (as numbers, not strings). If ``arg_name`` is
specified, it is used to make error messages more useful. If ``list_length``
is specified and greater than ``0``, exactly that number of elements must be
found or the function will error. Example::
numberList('10, -20 , 30.5') => {10, -20, 30.5}
* ``argparse.coords(arg, arg_name, skip_validation)``
Parses a comma-separated coordinate string and returns a coordinate table of
``{x, y, z}``. If the string ``'here'`` is passed, returns the coordinates of
the active game cursor, or throws an error if the cursor is not active. This
function also verifies that the coordinates are valid for the current map and
throws if they are not (unless ``skip_validation`` is set to true).
* ``argparse.positiveInt(arg, arg_name)``
Throws if ``tonumber(arg)`` is not a positive integer; otherwise returns
``tonumber(arg)``. If ``arg_name`` is specified, it is used to make error
messages more useful.
* ``argparse.nonnegativeInt(arg, arg_name)``
Throws if ``tonumber(arg)`` is not a non-negative integer; otherwise returns
``tonumber(arg)``. If ``arg_name`` is specified, it is used to make error
messages more useful.
dumper
======
A third-party lua table dumper module from
http://lua-users.org/wiki/DataDumper. Defines one
function:
* ``dumper.DataDumper(value, varname, fastmode, ident, indent_step)``
Returns ``value`` converted to a string. The ``indent_step``
argument specifies the indentation step size in spaces. For
the other arguments see the original documentation link above.
profiler
========
A third-party lua profiler module from
http://lua-users.org/wiki/PepperfishProfiler. Module defines one function to
create profiler objects which can be used to profile and generate report.
* ``profiler.newProfiler([variant[, sampling_frequency]])``
Returns an profile object with ``variant`` either ``'time'`` or ``'call'``.
``'time'`` variant takes optional ``sampling_frequency`` parameter to select
lua instruction counts between samples. Default is ``'time'`` variant with
``10*1000`` frequency.
``'call'`` variant has much higher runtime cost which will increase the
runtime of profiled code by factor of ten. For the extreme costs it provides
accurate function call counts that can help locate code which takes much time
in native calls.
* ``obj:start()``
Resets collected statistics. Then it starts collecting new statistics.
* ``obj:stop()``
Stops profile collection.
* ``obj:report(outfile[, sort_by_total_time])``
Write a report from previous statistics collection to ``outfile``.
``outfile`` should be writeable io file object (``io.open`` or
``io.stdout``). Passing ``true`` as second parameter ``sort_by_total_time``
switches sorting order to use total time instead of default self time order.
* ``obj:prevent(function)``
Adds an ignore filter for a ``function``. It will ignore the pointed function
and all of it children.
Examples
--------
::
local prof = profiler.newProfiler()
prof:start()
profiledCode()
prof:stop()
local out = io.open( "lua-profile.txt", "w+")
prof:report(out)
out:close()
class
=====
Implements a trivial single-inheritance class system.
* ``Foo = defclass(Foo[, ParentClass])``
Defines or updates class Foo. The ``Foo = defclass(Foo)`` syntax
is needed so that when the module or script is reloaded, the
class identity will be preserved through the preservation of
global variable values.
The ``defclass`` function is defined as a stub in the global
namespace, and using it will auto-load the class module.
* ``Class.super``
This class field is set by defclass to the parent class, and
allows a readable ``Class.super.method(self, ...)`` syntax for
calling superclass methods.
* ``Class.ATTRS { foo = xxx, bar = yyy }``
Declares certain instance fields to be attributes, i.e. auto-initialized
from fields in the table used as the constructor argument. If omitted,
they are initialized with the default values specified in this declaration.
If the default value should be *nil*, use ``ATTRS { foo = DEFAULT_NIL }``.
Declaring an attribute is mostly the same as defining your ``init`` method like this::
function Class.init(args)
self.attr1 = args.attr1 or default1
self.attr2 = args.attr2 or default2
...
end
The main difference is that attributes are processed as a separate
initialization step, before any ``init`` methods are called. They
also make the directy relation between instance fields and constructor
arguments more explicit.
* ``new_obj = Class{ foo = arg, bar = arg, ... }``
Calling the class as a function creates and initializes a new instance.
Initialization happens in this order:
1. An empty instance table is created, and its metatable set.
2. The ``preinit`` methods are called via ``invoke_before`` (see below)
with the table used as argument to the class. These methods are intended
for validating and tweaking that argument table.
3. Declared ATTRS are initialized from the argument table or their default values.
4. The ``init`` methods are called via ``invoke_after`` with the argument table.
This is the main constructor method.
5. The ``postinit`` methods are called via ``invoke_after`` with the argument table.
Place code that should be called after the object is fully constructed here.
Predefined instance methods:
* ``instance:assign{ foo = xxx }``
Assigns all values in the input table to the matching instance fields.
* ``instance:callback(method_name, [args...])``
Returns a closure that invokes the specified method of the class,
properly passing in self, and optionally a number of initial arguments too.
The arguments given to the closure are appended to these.
* ``instance:cb_getfield(field_name)``
Returns a closure that returns the specified field of the object when called.
* ``instance:cb_setfield(field_name)``
Returns a closure that sets the specified field to its argument when called.
* ``instance:invoke_before(method_name, args...)``
Navigates the inheritance chain of the instance starting from the most specific
class, and invokes the specified method with the arguments if it is defined in
that specific class. Equivalent to the following definition in every class::
function Class:invoke_before(method, ...)
if rawget(Class, method) then
rawget(Class, method)(self, ...)
end
Class.super.invoke_before(method, ...)
end
* ``instance:invoke_after(method_name, args...)``
Like invoke_before, only the method is called after the recursive call to super,
i.e. invocations happen in the parent to child order.
These two methods are inspired by the Common Lisp before and after methods, and
are intended for implementing similar protocols for certain things. The class
library itself uses them for constructors.
To avoid confusion, these methods cannot be redefined.
.. _custom-raw-tokens:
custom-raw-tokens
=================
A module for reading custom tokens added to the raws by mods.
* ``customRawTokens.getToken(typeDefinition, token)``
Where ``typeDefinition`` is a type definition struct as seen in ``df.global.world.raws``
(e.g.: ``dfhack.gui.getSelectedItem().subtype``) and ``token`` is the name of the custom token
you want read. The arguments from the token will then be returned as strings using single or
multiple return values. If the token is not present, the result is false; if it is present
but has no arguments, the result is true. For ``creature_raw``, it checks against no caste.
For ``plant_raw``, it checks against no growth.
* ``customRawTokens.getToken(typeInstance, token)``
Where ``typeInstance`` is a unit, entity, item, job, projectile, building, plant, or interaction
instance. Gets ``typeDefinition`` and then returns the same as ``getToken(typeDefinition, token)``.
For units, it gets the token from the race or caste instead if appplicable. For plants growth items,
it gets the token from the plant or plant growth instead if applicable. For plants it does the same
but with growth number -1.
* ``customRawTokens.getToken(raceDefinition, casteNumber, token)``
The same as ``getToken(unit, token)`` but with a specified race and caste. Caste number -1 is no caste.
* ``customRawTokens.getToken(raceDefinition, casteName, token)``
The same as ``getToken(unit, token)`` but with a specified race and caste, using caste name (e.g. "FEMALE")
instead of number.
* ``customRawTokens.getToken(plantDefinition, growthNumber, token)``
The same as ``getToken(plantGrowthItem, token)`` but with a specified plant and growth. Growth number -1
is no growth.
* ``customRawTokens.getToken(plantDefinition, growthName, token)``
The same as ``getToken(plantGrowthItem, token)`` but with a specified plant and growth, using growth name
(e.g. "LEAVES") instead of number.
Examples:
* Using an eventful onReactionComplete hook, something for disturbing dwarven science::
if customRawTokens.getToken(reaction, "DFHACK_CAUSES_INSANITY") then
-- make unit who performed reaction go insane
* Using an eventful onProjItemCheckMovement hook, a fast or slow-firing crossbow::
-- check projectile distance flown is zero, get firer, etc...
local multiplier = tonumber(customRawTokens.getToken(bow, "DFHACK_FIRE_RATE_MULTIPLIER")) or 1
firer.counters.think_counter = firer.counters.think_counter * multiplier
* Something for a script that prints help text about different types of units::
local unit = dfhack.gui.getSelectedUnit()
if not unit then return end
local helpText = customRawTokens.getToken(unit, "DFHACK_HELP_TEXT")
if helpText then print(helpText) end
* Healing armour::
-- (per unit every tick)
local healAmount = 0
for _, entry in ipairs(unit.inventory) do
if entry.mode == 2 then -- Worn
healAmount = healAmount + tonumber((customRawTokens.getToken(entry.item, "DFHACK_HEAL_AMOUNT")) or 0)
end
end
unit.body.blood_count = math.min(unit.body.blood_max, unit.body.blood_count + healAmount)
==================
In-game UI Library
==================
.. contents::
:local:
A number of lua modules with names starting with ``gui`` are dedicated
to wrapping the natives of the ``dfhack.screen`` module in a way that
is easy to use. This allows relatively easily and naturally creating
dialogs that integrate in the main game UI window.
These modules make extensive use of the ``class`` module, and define
things ranging from the basic ``Painter``, ``View`` and ``Screen``
classes, to fully functional predefined dialogs.
gui
===
This module defines the most important classes and functions for
implementing interfaces. This documents those of them that are
considered stable.
Misc
----
* ``USE_GRAPHICS``
Contains the value of ``dfhack.screen.inGraphicsMode()``, which cannot be
changed without restarting the game and thus is constant during the session.
* ``CLEAR_PEN``
The black pen used to clear the screen.
* ``simulateInput(screen, keys...)``
This function wraps an undocumented native function that passes a set of
keycodes to a screen, and is the official way to do that.
Every argument after the initial screen may be *nil*, a numeric keycode,
a string keycode, a sequence of numeric or string keycodes, or a mapping
of keycodes to *true* or *false*. For instance, it is possible to use the
table passed as argument to ``onInput``.
* ``mkdims_xy(x1,y1,x2,y2)``
Returns a table containing the arguments as fields, and also ``width`` and
``height`` that contains the rectangle dimensions.
* ``mkdims_wh(x1,y1,width,height)``
Returns the same kind of table as ``mkdims_xy``, only this time it computes
``x2`` and ``y2``.
* ``is_in_rect(rect,x,y)``
Checks if the given point is within a rectangle, represented by a table produced
by one of the ``mkdims`` functions.
* ``blink_visible(delay)``
Returns *true* or *false*, with the value switching to the opposite every ``delay``
msec. This is intended for rendering blinking interface objects.
* ``getKeyDisplay(keycode)``
Wraps ``dfhack.screen.getKeyDisplay`` in order to allow using strings for the keycode argument.
ViewRect class
--------------
This class represents an on-screen rectangle with an associated independent
clip area rectangle. It is the base of the ``Painter`` class, and is used by
``Views`` to track their client area.
* ``ViewRect{ rect = ..., clip_rect = ..., view_rect = ..., clip_view = ... }``
The constructor has the following arguments:
:rect: The ``mkdims`` rectangle in screen coordinates of the logical viewport.
Defaults to the whole screen.
:clip_rect: The clip rectangle in screen coordinates. Defaults to ``rect``.
:view_rect: A ViewRect object to copy from; overrides both ``rect`` and ``clip_rect``.
:clip_view: A ViewRect object to intersect the specified clip area with.
* ``rect:isDefunct()``
Returns *true* if the clip area is empty, i.e. no painting is possible.
* ``rect:inClipGlobalXY(x,y)``
Checks if these global coordinates are within the clip rectangle.
* ``rect:inClipLocalXY(x,y)``
Checks if these coordinates (specified relative to ``x1,y1``) are within the clip rectangle.
* ``rect:localXY(x,y)``
Converts a pair of global coordinates to local; returns *x_local,y_local*.
* ``rect:globalXY(x,y)``
Converts a pair of local coordinates to global; returns *x_global,y_global*.
* ``rect:viewport(x,y,w,h)`` or ``rect:viewport(subrect)``
Returns a ViewRect representing a sub-rectangle of the current one.
The arguments are specified in local coordinates; the ``subrect``
argument must be a ``mkdims`` table. The returned object consists of
the exact specified rectangle, and a clip area produced by intersecting
it with the clip area of the original object.
Painter class
-------------
The painting natives in ``dfhack.screen`` apply to the whole screen, are
completely stateless and don't implement clipping.
The Painter class inherits from ViewRect to provide clipping and local
coordinates, and tracks current cursor position and current pen. It also
supports drawing to a separate map buffer if applicable (see ``map()`` below
for details).
* ``Painter{ ..., pen = ..., key_pen = ... }``
In addition to ViewRect arguments, Painter accepts a suggestion of
the initial value for the main pen, and the keybinding pen. They
default to COLOR_GREY and COLOR_LIGHTGREEN otherwise.
There are also some convenience functions that wrap this constructor:
- ``Painter.new(rect,pen)``
- ``Painter.new_view(view_rect,pen)``
- ``Painter.new_xy(x1,y1,x2,y2,pen)``
- ``Painter.new_wh(x1,y1,width,height,pen)``
* ``painter:isValidPos()``
Checks if the current cursor position is within the clip area.
* ``painter:viewport(x,y,w,h)``
Like the superclass method, but returns a Painter object.
* ``painter:cursor()``
Returns the current cursor *x,y* in screen coordinates.
* ``painter:cursorX()``
Returns just the current *x* cursor coordinate
* ``painter:cursorY()``
Returns just the current *y* cursor coordinate
* ``painter:seek(x,y)``
Sets the current cursor position, and returns *self*.
Either of the arguments may be *nil* to keep the current value.
* ``painter:advance(dx,dy)``
Adds the given offsets to the cursor position, and returns *self*.
Either of the arguments may be *nil* to keep the current value.
* ``painter:newline([dx])``
Advances the cursor to the start of the next line plus the given x offset, and returns *self*.
* ``painter:pen(...)``
Sets the current pen to ``dfhack.pen.parse(old_pen,...)``, and returns *self*.
* ``painter:color(fg[,bold[,bg]])``
Sets the specified colors of the current pen and returns *self*.
* ``painter:key_pen(...)``
Sets the current keybinding pen to ``dfhack.pen.parse(old_pen,...)``, and returns *self*.
* ``painter:map(to_map)``
Enables or disables drawing to a separate map buffer. ``to_map`` is a boolean
that will be passed as the ``map`` parameter to any ``dfhack.screen`` functions
that accept it. Note that only third-party plugins like TWBT currently implement
a separate map buffer; if none are enabled, this function has no effect (but
should still be used to ensure proper support for such plugins). Returns *self*.
* ``painter:clear()``
Fills the whole clip rectangle with ``CLEAR_PEN``, and returns *self*.
* ``painter:fill(x1,y1,x2,y2[,...])`` or ``painter:fill(rect[,...])``
Fills the specified local coordinate rectangle with ``dfhack.pen.parse(cur_pen,...)``,
and returns *self*.
* ``painter:char([char[, ...]])``
Paints one character using ``char`` and ``dfhack.pen.parse(cur_pen,...)``; returns *self*.
The ``char`` argument, if not nil, is used to override the ``ch`` property of the pen.
* ``painter:tile([char, tile[, ...]])``
Like ``char()`` above, but also allows overriding the ``tile`` property on ad-hoc basis.
* ``painter:string(text[, ...])``
Paints the string with ``dfhack.pen.parse(cur_pen,...)``; returns *self*.
* ``painter:key(keycode[, ...])``
Paints the description of the keycode using ``dfhack.pen.parse(cur_key_pen,...)``; returns *self*.
* ``painter:key_string(keycode, text, ...)``
A convenience wrapper around both ``key()`` and ``string()`` that prints both
the specified keycode description and text, separated by ``:``. Any extra
arguments are passed directly to ``string()``. Returns *self*.
Unless specified otherwise above, all Painter methods return *self*, in order to allow chaining them like this::
painter:pen(foo):seek(x,y):char(1):advance(1):string('bar')...
View class
----------
This class is the common abstract base of both the stand-alone screens
and common widgets to be used inside them. It defines the basic layout,
rendering and event handling framework.
The class defines the following attributes:
:visible: Specifies that the view should be painted.
:active: Specifies that the view should receive events, if also visible.
:view_id: Specifies an identifier to easily identify the view among subviews.
This is reserved for use by script writers and should not be set by
library widgets for their internal subviews.
:on_focus: Called when the view gains keyboard focus; see ``setFocus()`` below.
:on_unfocus: Called when the view loses keyboard focus.
It also always has the following fields:
:subviews: Contains a table of all subviews. The sequence part of the
table is used for iteration. In addition, subviews are also
indexed under their ``view_id``, if any; see ``addviews()`` below.
:parent_view: A reference to the parent view. This field is ``nil`` until the
view is added as a subview to another view with ``addviews()``.
:focus_group: The list of widgets in a hierarchy. This table is unique and empty
when a view is initialized, but is replaced by a shared table when
the view is added to a parent via ``addviews()``. If a view in the
focus group has keyboard focus, that widget can be accessed via
``focus_group.cur``.
:focus: A boolean indicating whether the view currently has keyboard focus.
These fields are computed by the layout process:
:frame_parent_rect: The ViewRect represeting the client area of the parent view.
:frame_rect: The ``mkdims`` rect of the outer frame in parent-local coordinates.
:frame_body: The ViewRect representing the body part of the View's own frame.
The class has the following methods:
* ``view:addviews(list)``
Adds the views in the list to the ``subviews`` sequence. If any of the views
in the list have ``view_id`` attributes that don't conflict with existing keys
in ``subviews``, also stores them under the string keys. Finally, copies any
non-conflicting string keys from the ``subviews`` tables of the listed views.
Thus, doing something like this::
self:addviews{
Panel{
view_id = 'panel',
subviews = {
Label{ view_id = 'label' }
}
}
}
Would make the label accessible as both ``self.subviews.label`` and
``self.subviews.panel.subviews.label``.
* ``view:getWindowSize()``
Returns the dimensions of the ``frame_body`` rectangle.
* ``view:getMousePos()``
Returns the mouse *x,y* in coordinates local to the ``frame_body``
rectangle if it is within its clip area, or nothing otherwise.
* ``view:updateLayout([parent_rect])``
Recomputes layout of the view and its subviews. If no argument is
given, re-uses the previous parent rect. The process goes as follows:
1. Calls ``preUpdateLayout(parent_rect)`` via ``invoke_before``.
2. Uses ``computeFrame(parent_rect)`` to compute the desired frame.
3. Calls ``postComputeFrame(frame_body)`` via ``invoke_after``.
4. Calls ``updateSubviewLayout(frame_body)`` to update children.
5. Calls ``postUpdateLayout(frame_body)`` via ``invoke_after``.
* ``view:computeFrame(parent_rect)`` *(for overriding)*
Called by ``updateLayout`` in order to compute the frame rectangle(s).
Should return the ``mkdims`` rectangle for the outer frame, and optionally
also for the body frame. If only one rectangle is returned, it is used
for both frames, and the margin becomes zero.
* ``view:updateSubviewLayout(frame_body)``
Calls ``updateLayout`` on all children.
* ``view:render(painter)``
Given the parent's painter, renders the view via the following process:
1. Calls ``onRenderFrame(painter, frame_rect)`` to paint the outer frame.
2. Creates a new painter using the ``frame_body`` rect.
3. Calls ``onRenderBody(new_painter)`` to paint the client area.
4. Calls ``renderSubviews(new_painter)`` to paint visible children.
* ``view:renderSubviews(painter)``
Calls ``render`` on all ``visible`` subviews in the order they
appear in the ``subviews`` sequence.
* ``view:onRenderFrame(painter, rect)`` *(for overriding)*
Called by ``render`` to paint the outer frame; by default does nothing.
* ``view:onRenderBody(painter)`` *(for overriding)*
Called by ``render`` to paint the client area; by default does nothing.
* ``view:onInput(keys)`` *(for overriding)*
Override this to handle events. By default directly calls ``inputToSubviews``.
Return a true value from this method to signal that the event has been handled
and should not be passed on to more views.
* ``view:inputToSubviews(keys)``
Calls ``onInput`` on all visible active subviews, iterating the ``subviews``
sequence in *reverse order*, so that topmost subviews get events first.
Returns ``true`` if any of the subviews handled the event. If a subview within
the view's ``focus_group`` has focus and it and all of its ancestors are
active and visible, that subview is offered the chance to handle the input
before any other subviews.
* ``view:getPreferredFocusState()``
Returns ``false`` by default, but should be overridden by subclasses that may
want to take keyboard focus (if it is unclaimed) when they are added to a
parent view with ``addviews()``.
* ``view:setFocus(focus)``
Sets the keyboard focus to the view if ``focus`` is ``true``, or relinquishes
keyboard focus if ``focus`` is ``false``. Views that newly acquire keyboard
focus will trigger the ``on_focus`` callback, and views that lose keyboard
focus will trigger the ``on_unfocus`` callback. While a view has focus, all
keyboard input is sent to that view before any of its siblings or parents.
Keyboard input is propagated as normal (see ``inputToSubviews()`` above) if
there is no view with focus or if the view with focus returns ``false`` from
its ``onInput()`` function.
.. _lua-gui-screen:
Screen class
------------
This is a View subclass intended for use as a stand-alone dialog or screen.
It adds the following methods:
* ``screen:isShown()``
Returns *true* if the screen is currently in the game engine's display stack.
* ``screen:isDismissed()``
Returns *true* if the screen is dismissed.
* ``screen:isActive()``
Returns *true* if the screen is shown and not dismissed.
* ``screen:invalidate()``
Requests a repaint. Note that currently using it is not necessary, because
repaints are constantly requested automatically, due to issues with native
screens happening otherwise.
* ``screen:renderParent()``
Asks the parent native screen to render itself, or clears the screen if impossible.
* ``screen:sendInputToParent(...)``
Uses ``simulateInput`` to send keypresses to the native parent screen.
* ``screen:show([parent])``
Adds the screen to the display stack with the given screen as the parent;
if parent is not specified, places this one one topmost. Before calling
``dfhack.screen.show``, calls ``self:onAboutToShow(parent)``. Note that
``onAboutToShow()`` can dismiss active screens, and therefore change the
potential parent. If parent is not specified, this function will re-detect the
current topmost window after ``self:onAboutToShow(parent)`` returns.
* ``screen:onAboutToShow(parent)`` *(for overriding)*
Called when ``dfhack.screen.show`` is about to be called.
* ``screen:onShow()``
Called by ``dfhack.screen.show`` once the screen is successfully shown.
* ``screen:dismiss()``
Dismisses the screen. A dismissed screen does not receive any more
events or paint requests, but may remain in the display stack for
a short time until the game removes it.
* ``screen:onDismiss()`` *(for overriding)*
Called by ``dfhack.screen.dismiss()``.
* ``screen:onDestroy()`` *(for overriding)*
Called by the native code when the screen is fully destroyed and removed
from the display stack. Place code that absolutely must be called whenever
the screen is removed by any means here.
* ``screen:onResize``, ``screen:onRender``
Defined as callbacks for native code.
FramedScreen class
------------------
A Screen subclass that paints a visible frame around its body.
Most dialogs should inherit from this class.
A framed screen has the following attributes:
:frame_style: A table that defines a set of pens to draw various parts of the frame.
:frame_title: A string to display in the middle of the top of the frame.
:frame_width: Desired width of the client area. If *nil*, the screen will occupy the whole width.
:frame_height: Likewise, for height.
:frame_inset: The gap between the frame and the client area. Defaults to 0.
:frame_background: The pen to fill in the frame with. Defaults to CLEAR_PEN.
There are the following predefined frame style tables:
* ``GREY_FRAME``
A plain grey-colored frame.
* ``BOUNDARY_FRAME``
The same frame as used by the usual full-screen DF views, like dwarfmode.
* ``GREY_LINE_FRAME``
A frame consisting of grey lines, similar to the one used by titan announcements.
gui.widgets
===========
This module implements some basic widgets based on the View infrastructure.
Widget class
------------
Base of all the widgets. Inherits from View and has the following attributes:
* ``frame = {...}``
Specifies the constraints on the outer frame of the widget.
If omitted, the widget will occupy the whole parent rectangle.
The frame is specified as a table with the following possible fields:
:l: gap between the left edges of the frame and the parent.
:t: gap between the top edges of the frame and the parent.
:r: gap between the right edges of the frame and the parent.
:b: gap between the bottom edges of the frame and the parent.
:w: maximum width of the frame.
:h: maximum heigth of the frame.
:xalign: X alignment of the frame.
:yalign: Y alignment of the frame.
First the ``l,t,r,b`` fields restrict the available area for
placing the frame. If ``w`` and ``h`` are not specified or
larger then the computed area, it becomes the frame. Otherwise
the smaller frame is placed within the are based on the
``xalign/yalign`` fields. If the align hints are omitted, they
are assumed to be 0, 1, or 0.5 based on which of the ``l/r/t/b``
fields are set.
* ``frame_inset = {...}``
Specifies the gap between the outer frame, and the client area.
The attribute may be a simple integer value to specify a uniform
inset, or a table with the following fields:
:l: left margin.
:t: top margin.
:r: right margin.
:b: bottom margin.
:x: left/right margin, if ``l`` and/or ``r`` are omitted.
:y: top/bottom margin, if ``t`` and/or ``b`` are omitted.
Omitted fields are interpreted as having the value of 0.
* ``frame_background = pen``
The pen to fill the outer frame with. Defaults to no fill.
Panel class
-----------
Inherits from Widget, and intended for grouping a number of subviews.
Has attributes:
* ``subviews = {}``
Used to initialize the subview list in the constructor.
* ``on_render = function(painter)``
Called from ``onRenderBody``.
* ``autoarrange_subviews = bool`` (default: false)
* ``autoarrange_gap = int`` (default: 0)
If ``autoarrange_subviews`` is set to ``true``, the Panel will
automatically handle subview layout. Subviews are laid out vertically
according to their current height, with ``autoarrange_gap`` empty lines
between subviews. This allows you to have widgets dynamically change
height or become visible/hidden and you don't have to worry about
recalculating subview positions.
ResizingPanel class
-------------------
Subclass of Panel; automatically adjusts its own frame height according to
the size, position, and visibility of its subviews. Pairs nicely with a
parent Panel that has ``autoarrange_subviews`` enabled.
Pages class
-----------
Subclass of Panel; keeps exactly one child visible.
* ``Pages{ ..., selected = ... }``
Specifies which child to select initially; defaults to the first one.
* ``pages:getSelected()``
Returns the selected *index, child*.
* ``pages:setSelected(index)``
Selects the specified child, hiding the previous selected one.
It is permitted to use the subview object, or its ``view_id`` as index.
EditField class
---------------
Subclass of Widget; implements a simple edit field.
Attributes:
:label_text: The optional text label displayed before the editable text.
:text: The current contents of the field.
:text_pen: The pen to draw the text with.
:on_char: Input validation callback; used as ``on_char(new_char,text)``.
If it returns false, the character is ignored.
:on_change: Change notification callback; used as ``on_change(new_text,old_text)``.
:on_submit: Enter key callback; if set the field will handle the key and call ``on_submit(text)``.
:on_submit2: Shift-Enter key callback; if set the field will handle the key and call ``on_submit2(text)``.
:key: If specified, the field is disabled until this key is pressed. Must be given as a string.
:key_sep: If specified, will be used to customize how the activation key is
displayed. See ``token.key_sep`` in the ``Label`` documentation below.
:modal: Whether the ``EditField`` should prevent input from propagating to other
widgets while it has focus. You can set this to ``true``, for example,
if you don't want a ``List`` widget to react to arrow keys while the
user is editing.
An ``EditField`` will only read and process text input if it has keyboard focus.
It will automatically acquire keyboard focus when it is added as a subview to
a parent that has not already granted keyboard focus to another widget. If you
have more than one ``EditField`` on a screen, you can select which has focus by
calling ``setFocus(true)`` on the field object.
If an activation ``key`` is specified, the ``EditField`` will manage its own
focus. It will start in the unfocused state, and pressing the activation key
will acquire keyboard focus. Pressing the Enter key will release keyboard focus
and then call the ``on_submit`` callback. Pressing the Escape key will also
release keyboard focus, but first it will restore the text that was displayed
before the ``EditField`` gained focus and then call the ``on_change`` callback.
The ``EditField`` cursor can be moved to where you want to insert/remove text.
You can click where you want the cursor to move or you can use any of the
following keyboard hotkeys:
- Left/Right arrow: move the cursor one character to the left or right.
- Ctrl-Left/Right arrow: move the cursor one word to the left or right.
- Alt-Left/Right arrow: move the cursor to the beginning/end of the text.
Label class
-----------
This Widget subclass implements flowing semi-static text.
It has the following attributes:
:text_pen: Specifies the pen for active text.
:text_dpen: Specifies the pen for disabled text.
:text_hpen: Specifies the pen for text hovered over by the mouse, if a click handler is registered.
:disabled: Boolean or a callback; if true, the label is disabled.
:enabled: Boolean or a callback; if false, the label is disabled.
:auto_height: Sets self.frame.h from the text height.
:auto_width: Sets self.frame.w from the text width.
:on_click: A callback called when the label is clicked (optional)
:on_rclick: A callback called when the label is right-clicked (optional)
:scroll_keys: Specifies which keys the label should react to as a table. The table should map
keys to the number of lines to scroll as positive or negative integers or one of the keywords
supported by the ``scroll`` method. The default is up/down arrows scrolling by one line and page
up/down scrolling by one page.
:show_scroll_icons: Controls scroll icons' behaviour: ``false`` for no icons, ``'right'`` or ``'left'`` for
icons next to the text in an additional column (``frame_inset`` is adjusted to have ``.r`` or ``.l`` greater than ``0``),
``nil`` same as ``'right'`` but changes ``frame_inset`` only if a scroll icon is actually necessary
(if ``getTextHeight()`` is greater than ``frame_body.height``). Default is ``nil``.
:up_arrow_icon: The symbol for scroll up arrow. Default is ``string.char(24)`` (``↑``).
:down_arrow_icon: The symbol for scroll down arrow. Default is ``string.char(25)`` (``↓``).
:scroll_icon_pen: Specifies the pen for scroll icons. Default is ``COLOR_LIGHTCYAN``.
The text itself is represented as a complex structure, and passed
to the object via the ``text`` argument of the constructor, or via
the ``setText`` method, as one of:
* A simple string, possibly containing newlines.
* A sequence of tokens.
Every token in the sequence in turn may be either a string, possibly
containing newlines, or a table with the following possible fields:
* ``token.text = ...``
Specifies the main text content of a token, and may be a string, or
a callback returning a string.
* ``token.gap = ...``
Specifies the number of character positions to advance on the line
before rendering the token.
* ``token.tile = pen``
Specifies a pen to paint as one tile before the main part of the token.
* ``token.width = ...``
If specified either as a value or a callback, the text field is padded
or truncated to the specified number.
* ``token.pad_char = '?'``
If specified together with ``width``, the padding area is filled with
this character instead of just being skipped over.
* ``token.key = '...'``
Specifies the keycode associated with the token. The string description
of the key binding is added to the text content of the token.
* ``token.key_sep = '...'``
Specifies the separator to place between the keybinding label produced
by ``token.key``, and the main text of the token. If the separator starts with
'()', the token is formatted as ``text..' ('..binding..sep:sub(2)``. Otherwise
it is simply ``binding..sep..text``.
* ``token.enabled``, ``token.disabled``
Same as the attributes of the label itself, but applies only to the token.
* ``token.pen``, ``token.dpen``
Specify the pen and disabled pen to be used for the token's text.
The field may be either the pen itself, or a callback that returns it.
* ``token.on_activate``
If this field is not nil, and ``token.key`` is set, the token will actually
respond to that key binding unless disabled, and call this callback. Eventually
this may be extended with mouse click support.
* ``token.id``
Specifies a unique identifier for the token.
* ``token.line``, ``token.x1``, ``token.x2``
Reserved for internal use.
The Label widget implements the following methods:
* ``label:setText(new_text)``
Replaces the text currently contained in the widget.
* ``label:itemById(id)``
Finds a token by its ``id`` field.
* ``label:getTextHeight()``
Computes the height of the text.
* ``label:getTextWidth()``
Computes the width of the text.
* ``label:scroll(nlines)``
This method takes the number of lines to scroll as positive or negative
integers or one of the following keywords: ``+page``, ``-page``,
``+halfpage``, or ``-halfpage``.
WrappedLabel class
------------------
This Label subclass represents text that you want to be able to dynamically
wrap. This frees you from having to pre-split long strings into multiple lines
in the Label ``text`` list.
It has the following attributes:
:text_to_wrap: The string (or a table of strings or a function that returns a
string or a table of strings) to display. The text will be autowrapped to
the width of the widget, though any existing newlines will be kept.
:indent: The number of spaces to indent the text from the left margin. The
default is ``0``.
The displayed text is refreshed and rewrapped whenever the widget bounds change.
To force a refresh (to pick up changes in the string that ``text_to_wrap``
returns, for example), all ``updateLayout()`` on this widget or on a widget that
contains this widget.
TooltipLabel class
------------------
This WrappedLabel subclass represents text that you want to be able to
dynamically hide, like help text in a tooltip.
It has the following attributes:
:show_tooltip: Boolean or a callback; if true, the widget is visible.
The ``text_pen`` attribute of the ``Label`` class is overridden with a default
of ``COLOR_GREY`` and the ``indent`` attribute of the ``WrappedLabel`` class is
overridden with a default of ``2``.
The text of the tooltip can be passed in the inherited ``text_to_wrap``
attribute so it can be autowrapped, or in the basic ``text`` attribute if no
wrapping is required.
HotkeyLabel class
-----------------
This Label subclass is a convenience class for formatting text that responds to
a hotkey or mouse click.
It has the following attributes:
:key: The hotkey keycode to display, e.g. ``'CUSTOM_A'``.
:key_sep: If specified, will be used to customize how the activation key is
displayed. See ``token.key_sep`` in the ``Label`` documentation.
:label: The string (or a function that returns a string) to display after the
hotkey.
:on_activate: If specified, it is the callback that will be called whenever
the hotkey is pressed or the label is clicked.
CycleHotkeyLabel class
----------------------
This Label subclass represents a group of related options that the user can
cycle through by pressing a specified hotkey or clicking on the text.
It has the following attributes:
:key: The hotkey keycode to display, e.g. ``'CUSTOM_A'``.
:label: The string (or a function that returns a string) to display after the
hotkey.
:label_width: The number of spaces to allocate to the ``label`` (for use in
aligning a column of ``CycleHotkeyLabel`` labels).
:options: A list of strings or tables of ``{label=string, value=string}``.
String options use the same string for the label and value.
:initial_option: The value or numeric index of the initial option.
:on_change: The callback to call when the selected option changes. It is called
as ``on_change(new_option_value, old_option_value)``.
The index of the currently selected option in the ``options`` list is kept in
the ``option_idx`` instance variable.
The CycleHotkeyLabel widget implements the following methods:
* ``cyclehotkeylabel:cycle()``
Cycles the selected option and triggers the ``on_change`` callback.
* ``cyclehotkeylabel:getOptionLabel([option_idx])``
Retrieves the option label at the given index, or the label of the
currently selected option if no index is given.
* ``cyclehotkeylabel:getOptionValue([option_idx])``
Retrieves the option value at the given index, or the value of the
currently selected option if no index is given.
ToggleHotkeyLabel
-----------------
This is a specialized subclass of CycleHotkeyLabel that has two options:
``On`` (with a value of ``true``) and ``Off`` (with a value of ``false``).
List class
----------
The List widget implements a simple list with paging. You can click on a list
item to call the ``on_submit`` callback for that item.
It has the following attributes:
:text_pen: Specifies the pen for deselected list entries.
:cursor_pen: Specifies the pen for the selected entry.
:inactive_pen: If specified, used for the cursor when the widget is not active.
:icon_pen: Default pen for icons.
:on_select: Selection change callback; called as ``on_select(index,choice)``.
This is also called with *nil* arguments if ``setChoices`` is called
with an empty list.
:on_submit: Enter key or mouse click callback; if specified, the list reacts to the
key/click and calls the callback as ``on_submit(index,choice)``.
:on_submit2: Shift-Enter key callback; if specified, the list reacts to the key
and calls it as ``on_submit2(index,choice)``.
:row_height: Height of every row in text lines.
:icon_width: If not *nil*, the specified number of character columns
are reserved to the left of the list item for the icons.
:scroll_keys: Specifies which keys the list should react to as a table.
Every list item may be specified either as a string, or as a lua table
with the following fields:
:text: Specifies the label text in the same format as the Label text.
:caption, [1]: Deprecated legacy aliases for **text**.
:text_*: Reserved for internal use.
:key: Specifies a keybinding that acts as a shortcut for the specified item.
:icon: Specifies an icon string, or a pen to paint a single character. May be a callback.
:icon_pen: When the icon is a string, used to paint it.
The list supports the following methods:
* ``List{ ..., choices = ..., selected = ... }``
Same as calling ``setChoices`` after construction.
* ``list:setChoices(choices[, selected])``
Replaces the list of choices, possibly also setting the currently selected index.
* ``list:setSelected(selected)``
Sets the currently selected index. Returns the index after validation.
* ``list:getChoices()``
Returns the list of choices.
* ``list:getSelected()``
Returns the selected *index, choice*, or nothing if the list is empty.
* ``list:getContentWidth()``
Returns the minimal width to draw all choices without clipping.
* ``list:getContentHeight()``
Returns the minimal width to draw all choices without scrolling.
* ``list:submit()``
Call the ``on_submit`` callback, as if the Enter key was handled.
* ``list:submit2()``
Call the ``on_submit2`` callback, as if the Shift-Enter key was handled.
FilteredList class
------------------
This widget combines List, EditField and Label into a combo-box like
construction that allows filtering the list by subwords of its items.
In addition to passing through all attributes supported by List, it
supports:
:edit_pen: If specified, used instead of ``cursor_pen`` for the edit field.
:edit_below: If true, the edit field is placed below the list instead of above.
:edit_key: If specified, the edit field is disabled until this key is pressed.
:not_found_label: Specifies the text of the label shown when no items match the filter.
The list choices may include the following attributes:
:search_key: If specified, used instead of **text** to match against the filter.
This is required for any entries where **text** is not a string.
The widget implements:
* ``list:setChoices(choices[, selected])``
Resets the filter, and passes through to the inner list.
* ``list:getChoices()``
Returns the list of *all* choices.
* ``list:getVisibleChoices()``
Returns the *filtered* list of choices.
* ``list:getFilter()``
Returns the current filter string, and the *filtered* list of choices.
* ``list:setFilter(filter[,pos])``
Sets the new filter string, filters the list, and selects the item at
index ``pos`` in the *unfiltered* list if possible.
* ``list:canSubmit()``
Checks if there are currently any choices in the filtered list.
* ``list:getSelected()``, ``list:getContentWidth()``, ``list:getContentHeight()``, ``list:submit()``
Same as with an ordinary list.
.. _lua-plugins:
=======
Plugins
=======
.. contents::
:local:
DFHack plugins may export native functions and events to Lua contexts. These are
exposed as ``plugins.<name>`` modules, which can be imported with
``require('plugins.<name>')``. The plugins listed in this section expose
functions and/or data to Lua in this way.
In addition to any native functions documented here, plugins that can be
enabled (that is, plugins that support the `enable/disable API <enable>`) will
have the following functions defined:
* ``isEnabled()`` returns whether the plugin is enabled.
* ``setEnabled(boolean)`` sets whether the plugin is enabled.
For plugin developers, note that a Lua file in ``plugins/lua`` is required for
``require()`` to work, even if it contains no pure-Lua functions. This file must
contain ``mkmodule('plugins.<name>')`` to import any native functions defined in
the plugin. See existing files in ``plugins/lua`` for examples.
blueprint
=========
Lua functions provided by the `blueprint` plugin to programmatically generate
blueprint files:
* ``dig(start, end, name)``
* ``build(start, end, name)``
* ``place(start, end, name)``
* ``query(start, end, name)``
``start`` and ``end`` are tables containing positions (see ``xyz2pos``).
``name`` is used as the basis for the generated filenames.
The names of the functions are also available as the keys of the
``valid_phases`` table.
.. _building-hacks:
building-hacks
==============
This plugin overwrites some methods in workshop df class so that mechanical workshops are possible. Although
plugin export a function it's recommended to use lua decorated function.
.. contents::
:local:
Functions
---------
``registerBuilding(table)`` where table must contain name, as a workshop raw name, the rest are optional:
:name:
custom workshop id e.g. ``SOAPMAKER``
.. note:: this is the only mandatory field.
:fix_impassible:
if true make impassible tiles impassible to liquids too
:consume:
how much machine power is needed to work.
Disables reactions if not supplied enough and ``needs_power==1``
:produce:
how much machine power is produced.
:needs_power:
if produced in network < consumed stop working, default true
:gears:
a table or ``{x=?,y=?}`` of connection points for machines.
:action:
a table of number (how much ticks to skip) and a function which
gets called on shop update
:animate:
a table of frames which can be a table of:
a. tables of 4 numbers ``{tile,fore,back,bright}`` OR
b. empty table (tile not modified) OR
c. ``{x=<number> y=<number> + 4 numbers like in first case}``,
this generates full frame useful for animations that change little (1-2 tiles)
:canBeRoomSubset:
a flag if this building can be counted in room. 1 means it can, 0 means it can't and -1 default building behaviour
:auto_gears:
a flag that automatically fills up gears and animate. It looks over building definition for gear icons and maps them.
Animate table also might contain:
:frameLength:
how many ticks does one frame take OR
:isMechanical:
a bool that says to try to match to mechanical system (i.e. how gears are turning)
``getPower(building)`` returns two number - produced and consumed power if building can be modified and returns nothing otherwise
``setPower(building,produced,consumed)`` sets current productiona and consumption for a building.
Examples
--------
Simple mechanical workshop::
require('plugins.building-hacks').registerBuilding{name="BONE_GRINDER",
consume=15,
gears={x=0,y=0}, --connection point
animate={
isMechanical=true, --animate the same conn. point as vanilla gear
frames={
{{x=0,y=0,42,7,0,0}}, --first frame, 1 changed tile
{{x=0,y=0,15,7,0,0}} -- second frame, same
}
}
Or with auto_gears::
require('plugins.building-hacks').registerBuilding{name="BONE_GRINDER",
consume=15,
auto_gears=true
}
buildingplan
============
Native functions provided by the `buildingplan` plugin:
* ``bool isPlannableBuilding(df::building_type type, int16_t subtype, int32_t custom)`` returns whether the building type is handled by buildingplan.
* ``bool isPlanModeEnabled(df::building_type type, int16_t subtype, int32_t custom)`` returns whether the buildingplan UI is enabled for the specified building type.
* ``bool isPlannedBuilding(df::building *bld)`` returns whether the given building is managed by buildingplan.
* ``void addPlannedBuilding(df::building *bld)`` suspends the building jobs and adds the building to the monitor list.
* ``void doCycle()`` runs a check for whether buildlings in the monitor list can be assigned items and unsuspended. This method runs automatically twice a game day, so you only need to call it directly if you want buildingplan to do a check right now.
* ``void scheduleCycle()`` schedules a cycle to be run during the next non-paused game frame. Can be called multiple times while the game is paused and only one cycle will be scheduled.
burrows
=======
The `burrows` plugin implements extended burrow manipulations.
Events:
* ``onBurrowRename.foo = function(burrow)``
Emitted when a burrow might have been renamed either through
the game UI, or ``renameBurrow()``.
* ``onDigComplete.foo = function(job_type,pos,old_tiletype,new_tiletype,worker)``
Emitted when a tile might have been dug out. Only tracked if the
auto-growing burrows feature is enabled.
Native functions:
* ``renameBurrow(burrow,name)``
Renames the burrow, emitting ``onBurrowRename`` and updating auto-grow state properly.
* ``findByName(burrow,name)``
Finds a burrow by name, using the same rules as the plugin command line interface.
Namely, trailing ``'+'`` characters marking auto-grow burrows are ignored.
* ``copyUnits(target,source,enable)``
Applies units from ``source`` burrow to ``target``. The ``enable``
parameter specifies if they are to be added or removed.
* ``copyTiles(target,source,enable)``
Applies tiles from ``source`` burrow to ``target``. The ``enable``
parameter specifies if they are to be added or removed.
* ``setTilesByKeyword(target,keyword,enable)``
Adds or removes tiles matching a predefined keyword. The keyword
set is the same as used by the command line.
The lua module file also re-exports functions from ``dfhack.burrows``.
.. _cxxrandom:
cxxrandom
=========
Exposes some features of the C++11 random number library to Lua.
.. contents::
:local:
Native functions (exported to Lua)
----------------------------------
- ``GenerateEngine(seed)``
returns engine id
- ``DestroyEngine(rngID)``
destroys corresponding engine
- ``NewSeed(rngID, seed)``
re-seeds engine
- ``rollInt(rngID, min, max)``
generates random integer
- ``rollDouble(rngID, min, max)``
generates random double
- ``rollNormal(rngID, avg, stddev)``
generates random normal[gaus.]
- ``rollBool(rngID, chance)``
generates random boolean
- ``MakeNumSequence(start, end)``
returns sequence id
- ``AddToSequence(seqID, num)``
adds a number to the sequence
- ``ShuffleSequence(seqID, rngID)``
shuffles the number sequence
- ``NextInSequence(seqID)``
returns the next number in sequence
Lua plugin functions
--------------------
- ``MakeNewEngine(seed)``
returns engine id
Lua plugin classes
------------------
``crng``
~~~~~~~~
- ``init(id, df, dist)``: constructor
- ``id``: Reference ID of engine to use in RNGenerations
- ``df`` (optional): bool indicating whether to destroy the Engine when the crng object is garbage collected
- ``dist`` (optional): lua number distribution to use
- ``changeSeed(seed)``: alters engine's seed value
- ``setNumDistrib(distrib)``: sets the number distribution crng object should use
- ``distrib``: number distribution object to use in RNGenerations
- ``next()``: returns the next number in the distribution
- ``shuffle()``: effectively shuffles the number distribution
``normal_distribution``
~~~~~~~~~~~~~~~~~~~~~~~
- ``init(avg, stddev)``: constructor
- ``next(id)``: returns next number in the distribution
- ``id``: engine ID to pass to native function
``real_distribution``
~~~~~~~~~~~~~~~~~~~~~
- ``init(min, max)``: constructor
- ``next(id)``: returns next number in the distribution
- ``id``: engine ID to pass to native function
``int_distribution``
~~~~~~~~~~~~~~~~~~~~
- ``init(min, max)``: constructor
- ``next(id)``: returns next number in the distribution
- ``id``: engine ID to pass to native function
``bool_distribution``
~~~~~~~~~~~~~~~~~~~~~
- ``init(chance)``: constructor
- ``next(id)``: returns next boolean in the distribution
- ``id``: engine ID to pass to native function
``num_sequence``
~~~~~~~~~~~~~~~~
- ``init(a, b)``: constructor
- ``add(num)``: adds num to the end of the number sequence
- ``shuffle()``: shuffles the sequence of numbers
- ``next()``: returns next number in the sequence
Usage
-----
The basic idea is you create a number distribution which you generate random numbers along. The C++ relies
on engines keeping state information to determine the next number along the distribution.
You're welcome to try and (ab)use this knowledge for your RNG purposes.
Example::
local rng = require('plugins.cxxrandom')
local norm_dist = rng.normal_distribution(6820,116) // avg, stddev
local engID = rng.MakeNewEngine(0)
-- somewhat reminiscent of the C++ syntax
print(norm_dist:next(engID))
-- a bit more streamlined
local cleanup = true --delete engine on cleanup
local number_generator = rng.crng:new(engID, cleanup, norm_dist)
print(number_generator:next())
-- simplified
print(rng.rollNormal(engID,6820,116))
The number sequences are much simpler. They're intended for where you need to randomly generate an index, perhaps in a loop for an array. You technically don't need an engine to use it, if you don't mind never shuffling.
Example::
local rng = require('plugins.cxxrandom')
local g = rng.crng:new(rng.MakeNewEngine(0), true, rng.num_sequence:new(0,table_size))
g:shuffle()
for _ = 1, table_size do
func(array[g:next()])
end
dig-now
=======
The dig-now plugin exposes the following functions to Lua:
* ``dig_now_tile(pos)`` or ``dig_now_tile(x,y,z)``: Runs dig-now for the
specified tile coordinate. Default options apply, as if you were running the
command ``dig-now <pos> <pos>``. See the `dig-now` documentation for details
on default settings.
.. _eventful:
eventful
========
This plugin exports some events to lua thus allowing to run lua functions
on DF world events.
.. contents::
:local:
List of events
--------------
1. ``onReactionCompleting(reaction,reaction_product,unit,input_items,input_reagents,output_items,call_native)``
Is called once per reaction product, before reaction had a chance to call native code for item creation.
Setting ``call_native.value=false`` cancels further processing: no items are created and ``onReactionComplete`` is not called.
2. ``onReactionComplete(reaction,reaction_product,unit,input_items,input_reagents,output_items)``
Is called once per reaction product, when reaction finishes and has at least one product.
3. ``onItemContaminateWound(item,unit,wound,number1,number2)``
Is called when item tries to contaminate wound (e.g. stuck in).
4. ``onProjItemCheckMovement(projectile)``
Is called when projectile moves.
5. ``onProjItemCheckImpact(projectile,somebool)``
Is called when projectile hits something.
6. ``onProjUnitCheckMovement(projectile)``
Is called when projectile moves.
7. ``onProjUnitCheckImpact(projectile,somebool)``
Is called when projectile hits something.
8. ``onWorkshopFillSidebarMenu(workshop,callnative)``
Is called when viewing a workshop in 'q' mode, to populate reactions, useful for custom viewscreens for shops.
9. ``postWorkshopFillSidebarMenu(workshop)``
Is called after calling (or not) native fillSidebarMenu(). Useful for job button
tweaking (e.g. adding custom reactions)
.. _EventManager:
Events from EventManager
------------------------
These events are straight from EventManager module. Each of them first needs to be enabled. See functions for more info. If you register a listener before the game is loaded, be aware that no events will be triggered immediately after loading, so you might need to add another event listener for when the game first loads in some cases.
1. ``onBuildingCreatedDestroyed(building_id)``
Gets called when building is created or destroyed.
2. ``onConstructionCreatedDestroyed(building_id)``
Gets called when construction is created or destroyed.
3. ``onJobInitiated(job)``
Gets called when job is issued.
4. ``onJobCompleted(job)``
Gets called when job is finished. The job that is passed to this function is a copy. Requires a frequency of 0 in order to distinguish between workshop jobs that were cancelled by the user and workshop jobs that completed successfully.
5. ``onUnitDeath(unit_id)``
Gets called on unit death.
6. ``onItemCreated(item_id)``
Gets called when item is created (except due to traders, migrants, invaders and spider webs).
7. ``onSyndrome(unit_id,syndrome_index)``
Gets called when new syndrome appears on a unit.
8. ``onInvasion(invasion_id)``
Gets called when new invasion happens.
9. ``onInventoryChange(unit_id,item_id,old_equip,new_equip)``
Gets called when someone picks up an item, puts one down, or changes the way they are holding it. If an item is picked up, old_equip will be null. If an item is dropped, new_equip will be null. If an item is re-equipped in a new way, then neither will be null. You absolutely must NOT alter either old_equip or new_equip or you might break other plugins.
10. ``onReport(reportId)``
Gets called when a report happens. This happens more often than you probably think, even if it doesn't show up in the announcements.
11. ``onUnitAttack(attackerId, defenderId, woundId)``
Called when a unit wounds another with a weapon. Is NOT called if blocked, dodged, deflected, or parried.
12. ``onUnload()``
A convenience event in case you don't want to register for every onStateChange event.
13. ``onInteraction(attackVerb, defendVerb, attackerId, defenderId, attackReportId, defendReportId)``
Called when a unit uses an interaction on another.
Functions
---------
1. ``registerReaction(reaction_name,callback)``
Simplified way of using onReactionCompleting; the callback is function (same params as event).
2. ``removeNative(shop_name)``
Removes native choice list from the building.
3. ``addReactionToShop(reaction_name,shop_name)``
Add a custom reaction to the building.
4. ``enableEvent(evType,frequency)``
Enable event checking for EventManager events. For event types use ``eventType`` table. Note that different types of events require different frequencies to be effective. The frequency is how many ticks EventManager will wait before checking if that type of event has happened. If multiple scripts or plugins use the same event type, the smallest frequency is the one that is used, so you might get events triggered more often than the frequency you use here.
5. ``registerSidebar(shop_name,callback)``
Enable callback when sidebar for ``shop_name`` is drawn. Usefull for custom workshop views e.g. using gui.dwarfmode lib. Also accepts a ``class`` instead of function
as callback. Best used with ``gui.dwarfmode`` class ``WorkshopOverlay``.
Examples
--------
Spawn dragon breath on each item attempt to contaminate wound::
b=require "plugins.eventful"
b.onItemContaminateWound.one=function(item,unit,un_wound,x,y)
local flw=dfhack.maps.spawnFlow(unit.pos,6,0,0,50000)
end
Reaction complete example::
b=require "plugins.eventful"
b.registerReaction("LAY_BOMB",function(reaction,unit,in_items,in_reag,out_items,call_native)
local pos=copyall(unit.pos)
-- spawn dragonbreath after 100 ticks
dfhack.timeout(100,"ticks",function() dfhack.maps.spawnFlow(pos,6,0,0,50000) end)
--do not call real item creation code
call_native.value=false
end)
Grenade example::
b=require "plugins.eventful"
b.onProjItemCheckImpact.one=function(projectile)
-- you can check if projectile.item e.g. has correct material
dfhack.maps.spawnFlow(projectile.cur_pos,6,0,0,50000)
end
Integrated tannery::
b=require "plugins.eventful"
b.addReactionToShop("TAN_A_HIDE","LEATHERWORKS")
.. _luasocket:
luasocket
=========
A way to access csocket from lua. The usage is made similar to luasocket in vanilla lua distributions. Currently
only subset of functions exist and only tcp mode is implemented.
.. contents::
:local:
Socket class
------------
This is a base class for ``client`` and ``server`` sockets. You can not create it - it's like a virtual
base class in c++.
* ``socket:close()``
Closes the connection.
* ``socket:setTimeout(sec,msec)``
Sets the operation timeout for this socket. It's possible to set timeout to 0. Then it performs like
a non-blocking socket.
Client class
------------
Client is a connection socket to a server. You can get this object either from ``tcp:connect(address,port)`` or
from ``server:accept()``. It's a subclass of ``socket``.
* ``client:receive(pattern)``
Receives data. Pattern is one of:
:``*l``: read one line (default, if pattern is *nil*)
:<number>: read specified number of bytes
:``*a``: read all available data
* ``client:send(data)``
Sends data. Data is a string.
Server class
------------
Server is a socket that is waiting for clients.
You can get this object from ``tcp:bind(address,port)``.
* ``server:accept()``
Accepts an incoming connection if it exists.
Returns a ``client`` object representing that socket.
Tcp class
---------
A class with all the tcp functionality.
* ``tcp:bind(address,port)``
Starts listening on that port for incoming connections. Returns ``server`` object.
* ``tcp:connect(address,port)``
Tries connecting to that address and port. Returns ``client`` object.
.. _map-render:
map-render
==========
A way to ask DF to render a section of the fortress mode map. This uses a native
DF rendering function so it's highly dependent on DF settings (e.g. tileset,
colors, etc.)
Functions
---------
- ``render_map_rect(x,y,z,w,h)``
returns a table with w*h*4 entries of rendered tiles. The format is same as ``df.global.gps.screen`` (tile,foreground,bright,background).
.. _pathable:
pathable
========
This plugin implements the back end of the `gui/pathable` script. It exports a
single Lua function, in ``hack/lua/plugins/pathable.lua``:
* ``paintScreen(cursor[,skip_unrevealed])``: Paint each visible of the screen
green or red, depending on whether it can be pathed to from the tile at
``cursor``. If ``skip_unrevealed`` is specified and true, do not draw
unrevealed tiles.
reveal
======
Native functions provided by the `reveal` plugin:
* ``void unhideFlood(pos)``: Unhides map tiles according to visibility rules,
starting from the given coordinates. This algorithm only processes adjacent
hidden tiles, so it must start on a hidden tile in order to have any effect.
It will not reveal hidden sections separated by already-unhidden tiles.
Example of revealing a cavern that happens to have an open tile at the specified
coordinate::
unhideFlood({x=25, y=38, z=140})
sort
====
The `sort <sort>` plugin does not export any native functions as of now.
Instead, it calls Lua code to perform the actual ordering of list items.
.. _xlsxreader:
xlsxreader
==========
Utility functions to facilitate reading .xlsx spreadsheets. It provides the
following low-level API methods:
- ``open_xlsx_file(filename)`` returns a file_handle or nil on error
- ``close_xlsx_file(file_handle)`` closes the specified file_handle
- ``list_sheets(file_handle)`` returns a list of strings representing sheet
names
- ``open_sheet(file_handle, sheet_name)`` returns a sheet_handle. This call
always succeeds, even if the sheet doesn't exist. Non-existent sheets will
have no data, though.
- ``close_sheet(sheet_handle)`` closes the specified sheet_handle
- ``get_row(sheet_handle, max_tokens)`` returns a list of strings representing
the contents of the cells in the next row. The ``max_tokens`` parameter is
optional. If set to a number > 0, it limits the number of cells read and
returned for the row.
The plugin also provides Lua class wrappers for ease of use:
- ``XlsxioReader`` provides access to .xlsx files
- ``XlsxioSheetReader`` provides access to sheets within .xlsx files
- ``open(filepath)`` initializes and returns an ``XlsxioReader`` object
The ``XlsxioReader`` class has the following methods:
- ``XlsxioReader:close()`` closes the file. Be sure to close any open child
sheet handles first!
- ``XlsxioReader:list_sheets()`` returns a list of strings representing sheet
names
- ``XlsxioReader:open_sheet(sheet_name)`` returns an initialized
``XlsxioSheetReader`` object
The ``XlsxioSheetReader`` class has the following methods:
- ``XlsxioSheetReader:close()`` closes the sheet
- ``XlsxioSheetReader:get_row(max_tokens)`` reads the next row from the sheet.
If ``max_tokens`` is specified and is a positive integer, only the first
``max_tokens`` elements of the row are returned.
Here is an end-to-end example::
local xlsxreader = require('plugins.xlsxreader')
local function dump_sheet(reader, sheet_name)
print('reading sheet: ' .. sheet_name)
local sheet_reader = reader:open_sheet(sheet_name)
dfhack.with_finalize(
function() sheet_reader:close() end,
function()
local row_cells = sheet_reader:get_row()
while row_cells do
printall(row_cells)
row_cells = sheet_reader:get_row()
end
end
)
end
local filepath = 'path/to/some_file.xlsx'
local reader = xlsxreader.open(filepath)
dfhack.with_finalize(
function() reader:close() end,
function()
for _,sheet_name in ipairs(reader:list_sheets()) do
dump_sheet(reader, sheet_name)
end
end
)
=======
Scripts
=======
.. contents::
:local:
Any files with the ``.lua`` extension placed into the :file:`hack/scripts` folder
are automatically made avaiable as DFHack commands. The command corresponding to
a script is simply the script's filename, relative to the scripts folder, with
the extension omitted. For example:
* :file:`hack/scripts/add-thought.lua` is invoked as ``add-thought``
* :file:`hack/scripts/gui/teleport.lua` is invoked as ``gui/teleport``
.. note::
Scripts placed in subdirectories can be run as described above, but are not
listed by the `ls` command unless ``-a`` is specified. In general, scripts
should be placed in subfolders in the following situations:
* ``devel``: scripts that are intended exclusively for DFHack development,
including examples, or scripts that are experimental and unstable
* ``fix``: fixes for specific DF issues
* ``gui``: GUI front-ends for existing tools (for example, see the
relationship between `teleport` and `gui/teleport`)
* ``modtools``: scripts that are intended to be run exclusively as part of
mods, not directly by end-users (as a rule of thumb: if someone other than
a mod developer would want to run a script from the console, it should
not be placed in this folder)
Scripts can also be placed in other folders - by default, these include
:file:`raw/scripts` and :file:`data/save/{region}/raw/scripts`, but additional
folders can be added (for example, a copy of the
:source-scripts:`scripts repository <>` for local development). See
`script-paths` for more information on how to configure this behavior.
If the first line of the script is a one-line comment (starting with ``--``),
the content of the comment is used by the built-in ``ls`` and ``help`` commands.
Such a comment is required for every script in the official DFHack repository.
Scripts are read from disk when run for the first time, or if they have changed
since the last time they were run.
Each script has an isolated environment where global variables set by the script
are stored. Values of globals persist across script runs in the same DF session.
See `devel/lua-example` for an example of this behavior. Note that local
variables do *not* persist.
Arguments are passed in to the scripts via the ``...`` built-in quasi-variable;
when the script is called by the DFHack core, they are all guaranteed to be
non-nil strings.
Additional data about how a script is invoked is passed to the script as a
special ``dfhack_flags`` global, which is unique to each script. This table
is guaranteed to exist, but individual entries may be present or absent
depending on how the script was invoked. Flags that are present are described
in the subsections below.
DFHack invokes the scripts in the `core context <lua-core-context>`; however it
is possible to call them from any lua code (including from other scripts) in any
context with ``dfhack.run_script()`` below.
General script API
==================
* ``dfhack.run_script(name[,args...])``
Run a Lua script in hack/scripts/, as if it were started from the DFHack
command-line. The ``name`` argument should be the name of the script without
its extension, as it would be used on the command line.
Example:
In DFHack prompt::
repeat -time 14 -timeUnits days -command [ workorder ShearCreature ] -name autoShearCreature
In Lua script::
dfhack.run_script("repeat", "-time", "14", "-timeUnits", "days", "-command", "[", "workorder", "ShearCreature", "]", "-name", "autoShearCreature")
Note that the ``dfhack.run_script()`` function allows Lua errors to propagate to the caller.
To run other types of commands (such as built-in commands, plugin commands, or
Ruby scripts), see ``dfhack.run_command()``. Note that this is slightly slower
than ``dfhack.run_script()`` for Lua scripts.
* ``dfhack.script_help([name, [extension]])``
Returns the contents of the embedded documentation of the specified script.
``extension`` defaults to "lua", and ``name`` defaults to the name of the
script where this function was called. For example, the following can be used
to print the current script's help text::
local args = {...}
if args[1] == 'help' then
print(script_help())
return
end
Importing scripts
=================
* ``dfhack.reqscript(name)`` or ``reqscript(name)``
Loads a Lua script and returns its environment (i.e. a table of all global
functions and variables). This is similar to the built-in ``require()``, but
searches all script paths for the first matching ``name.lua`` file instead
of searching the Lua library paths (like ``hack/lua``).
Most scripts can be made to support ``reqscript()`` without significant
changes (in contrast, ``require()`` requires the use of ``mkmodule()`` and
some additional boilerplate). However, because scripts can have side effects
when they are loaded (such as printing messages or modifying the game state),
scripts that intend to support being imported must satisfy some criteria to
ensure that they can be imported safely:
1. Include the following line - ``reqscript()`` will fail if this line is
not present::
--@ module = true
2. Include a check for ``dfhack_flags.module``, and avoid running any code
that has side-effects if this flag is true. For instance::
-- (function definitions)
if dfhack_flags.module then
return
end
-- (main script code with side-effects)
or::
-- (function definitions)
function main()
-- (main script code with side-effects)
end
if not dfhack_flags.module then
main()
end
Example usage::
local addThought = reqscript('add-thought')
addThought.addEmotionToUnit(unit, ...)
Circular dependencies between scripts are supported, as long as the scripts
have no side-effects at load time (which should already be the case per
the above criteria).
.. warning::
Avoid caching the table returned by ``reqscript()`` beyond storing it in
a local or global variable as in the example above. ``reqscript()`` is fast
for scripts that have previously been loaded and haven't changed. If you
retain a reference to a table returned by an old ``reqscript()`` call, this
may lead to unintended behavior if the location of the script changes
(e.g. if a save is loaded or unloaded, or if a `script path <script-paths>`
is added in some other way).
.. admonition:: Tip
Mods that include custom Lua modules can write these modules to support
``reqscript()`` and distribute them as scripts in ``raw/scripts``. Since the
entire ``raw`` folder is copied into new saves, this will allow saves to be
successfully transferred to other users who do not have the mod installed
(as long as they have DFHack installed).
.. admonition:: Backwards compatibility notes
For backwards compatibility, ``moduleMode`` is also defined if
``dfhack_flags.module`` is defined, and is set to the same value.
Support for this may be removed in a future version.
* ``dfhack.script_environment(name)``
Similar to ``reqscript()`` but does not enforce the check for module support.
This can be used to import scripts that support being used as a module but do
not declare support as described above, although it is preferred to update
such scripts so that ``reqscript()`` can be used instead.
Enabling and disabling scripts
==============================
Scripts can choose to recognize the built-in ``enable`` and ``disable`` commands
by including the following line anywhere in their file::
--@ enable = true
When the ``enable`` and ``disable`` commands are invoked, the ``dfhack_flags``
table passed to the script will have the following fields set:
* ``enable``: Always ``true`` if the script is being enabled *or* disabled
* ``enable_state``: ``true`` if the script is being enabled, ``false`` otherwise
Example usage::
--@ enable = true
-- (function definitions...)
if dfhack_flags.enable then
if dfhack_flags.enable_state then
start()
else
stop()
end
end
Save init script
================
If a save directory contains a file called ``raw/init.lua``, it is
automatically loaded and executed every time the save is loaded.
The same applies to any files called ``raw/init.d/*.lua``. Every
such script can define the following functions to be called by dfhack:
* ``function onStateChange(op) ... end``
Automatically called from the regular onStateChange event as long
as the save is still loaded. This avoids the need to install a hook
into the global ``dfhack.onStateChange`` table, with associated
cleanup concerns.
* ``function onUnload() ... end``
Called when the save containing the script is unloaded. This function
should clean up any global hooks installed by the script. Note that
when this is called, the world is already completely unloaded.
Within the init script, the path to the save directory is available as ``SAVE_PATH``.