Types/NoiseExpression: Difference between revisions

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A fragment of a functional program used to generate coherent noise, probably for purposes related to terrain generation.
A fragment of a functional program used to generate coherent noise, probably for purposes related to terrain generation.


Noise expressions can be provided as object literals or built using functions in the built-in <code>noise</code> library.
Noise expressions can be provided as table literals or built using functions in the [https://github.com/wube/factorio-data/blob/master/core/lualib/noise.lua built-in <code>noise</code> library]. The built-in noise library allows writing much more concise code, so its usage will be shown in most examples on this page.<br>
<code>noise.define_noise_function</code> allows noise expressions to be defined using a shorthand
[https://github.com/wube/factorio-data/blob/master/core/lualib/noise.lua#L272 <code>noise.define_noise_function</code>] allows noise expressions to be defined using a shorthand
that's a subset of Lua (see [[#Example definition|example definition]] for an example and its literal equivalent).
that's a subset of Lua (see [[#Example definition|example definition]] for an example and its literal equivalent).
'''Types/NoiseExpression''' is used by [[Prototype/NamedNoiseExpression#expression|NamedNoiseExpressionPrototype::expression]], [[Types/AutoplaceSpecification#Properties_for_Expression-based_AutoplaceSpecifications|AutoplaceSpecification::probability_expression]] and [[Types/AutoplaceSpecification#Properties_for_Expression-based_AutoplaceSpecifications|AutoplaceSpecification::richness_expression]].


== Mandatory properties ==
== Mandatory properties ==
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=== variable ===
=== variable ===
Properties:
* '''variable_name''': a [[Types/string]]


Reference to a pre-defined variable, constant, or a named noise expression.
Reference to a pre-defined variable, constant, or a [[Prototype/NamedNoiseExpression|named noise expression]]. Variables referencing named noise expressions may have their reference overridden by other named noise expression if their intended_property is the variable name and it is selected by the user in the map generator GUI. See [[Prototype/NamedNoiseExpression#Custom intended_property]].


Predefined variables include "x", "y", and "distance".
Predefined variables:
* x - number - Current x position on the map
* y - number - Current y position on the map


Properties:
Predefined constants (note that map gen settings can also be provided by a [[Types/MapGenPreset]]):
* map_seed - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings]
* map_width - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings]
* map_height - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings]
* water_level - number - Don't use; use wlc_elevation_minimum instead
* finite_water_level - number - Don't use; use wlc_elevation_offset instead
* wlc_elevation_offset - number - When the result of 10 × log2("water") with "water" from [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings] is finite, <code>wlc_elevation_offset = -(10 * log2(water))</code>, else <code>wlc_elevation_offset = 0</code>
* wlc_elevation_minimum - number - When the result of 10 × log2("water") with "water" from [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings] is infinite, <code>wlc_elevation_minimum = -∞</code>, else <code>wlc_elevation_minimum = 4</code>
* cliff_elevation_offset - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings] ([https://lua-api.factorio.com/latest/Concepts.html#CliffPlacementSettings CliffPlacementSettings])
* cliff_elevation_interval - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings] ([https://lua-api.factorio.com/latest/Concepts.html#CliffPlacementSettings CliffPlacementSettings])
* control-setting:cliffs:richness:multiplier - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings] ([https://lua-api.factorio.com/latest/Concepts.html#CliffPlacementSettings CliffPlacementSettings])
* terrace_elevation_offset - number - Calculated from the cliff and water settings.
* terrace_elevation_interval - number - Same as "cliff_elevation_interval"
* starting_area_radius - number - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings]
* starting_positions - map position list - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings]
* starting_lake_positions - map position list - Calculated from starting positions and map seed
* peaceful_mode - boolean - Taken from the [http://lua-api.factorio.com/latest/Concepts.html#MapGenSettings MapGenSettings]
* control-setting:<prototype name>:frequency - number - Provided for all of the [[Prototype/Tile|tile]], [[Prototype/Entity|entity]], [[Prototype/Decorative|decorative]], [[Prototype/AutoplaceControl|autoplace-control]] prototypes.
* control-setting:<prototype name>:size - number - Provided for all of the [[Prototype/Tile|tile]], [[Prototype/Entity|entity]], [[Prototype/Decorative|decorative]], [[Prototype/AutoplaceControl|autoplace-control]] prototypes.
* control-setting:<prototype name>:richness - number - Provided for all of the [[Prototype/Tile|tile]], [[Prototype/Entity|entity]], [[Prototype/Decorative|decorative]], [[Prototype/AutoplaceControl|autoplace-control]] prototypes.
 
A list of all named noise expression defined in the base game can be found at [[Data.raw#noise-expression]]. Notable expressions defined by the base game are:
* distance - number - <code>noise.distance_from(noise.var("x"), noise.var("y"), noise.var("starting_positions"))</code>, so the distance from the closest starting position. distance is never < 0.
* tier_from_start - number - <code>noise.max(0.0, noise.var("distance") - noise.var("starting_area_radius")) /  noise.var("starting_area_radius)</code>
* tier - number - <code>noise.var("tier_from_start")</code>, so same as tier_from_start.
* starting_area_weight - number - <code>1 - noise.min(1.0, noise.var("tier_from_start") / 2.0)</code>
* moisture - number - A value between 0 and 1 that determines whether a tile becomes sandy (low moisture) or grassy (high moisture).
* aux - number - A value between 0 and 1 that determines whether low-moisture tiles become sand or red desert.
* temperature - number -  Provides a value (vaguely representing degrees Celsius, varying between -20 and 50) that is used (together with moisture and aux) as part of tree and decorative placement.
* elevation - number - Tiles values less than zero become water. Cliffs are placed along certain contours according to CliffPlacementSettings.
* cliffiness - number - Determines whether (when >0.5) or not (when <0.5) a cliff will be placed at an otherwise suitable (according to CliffPlacementSettings) location.
* enemy-base-intensity - number - Is referenced by both enemy-base-frequency and enemy-base-radius. i.e. if this is overridden, enemy base frequency and size will both be affected and do something reasonable. By default, this expression returns a value proportional to distance from any starting point, clamped at about 7.
* enemy-base-frequency - number - Represents average number of enemy bases per tile for a region, by default in terms of enemy-base-intensity.
* enemy-base-radius - number - Represents the radius of an enemy base, if one were to be placed on the given tile, by default proportional to a constant plus enemy-base-intensity.
 
Note that the named noise expressions are all defined in Lua, so mods may remove or change the notable expressions listed above or change how they are used in the map generation.
 
Examples:
<syntaxhighlight lang="lua">
local noise = require("noise")
 
local y =
{
  type = "variable",
  variable_name = "y" -- predefined variable
}
local x = noise.var("x") -- predefined variable, with the noise lib
 
local width =
{
  type = "variable",
  variable_name = "map_width" -- predefined constant
}
local height = noise.var("map_height") -- predefined constant, with the noise lib


* '''variable_name''': a [[Types/string]]
local aux =
{
  type = "variable",
  variable_name = "aux" -- named noise expression
}
local cliffiness = noise.var("cliffiness") -- named noise expression, with the noise lib
</syntaxhighlight>


=== function-application ===
=== function-application ===


Apply a function to a list or associative array of arguments.
Apply a function to a list or associative array of arguments. Some functions expect arguments to be named and some expect them not to be.
Some functions expect arguments to be named and some expect them not to be.


Function calls are their own class of expression
Function calls are their own class of expression (as opposed to every function just being its own expression type) because function calls all have similar properties -- arguments are themselves expressions, a function call with all-constant arguments can be constant-folded (due to [[Wikipedia:Referential_transparency|referential transparency]]), etc.
(as opposed to every function just being its own expression type)
because function calls all have similar properties --
arguments are themselves expressions,
a call to any pure function (i.e. most functions other than <code>random()</code>)
is [https://en.wikipedia.org/wiki/Referential_transparency referentially transparent]
and can be constant-folded if all of its arguments are constant, etc.


Properties:
Properties:


* '''function_name''' (a string; see functions, below)
* '''function_name''' (a string; see [[#Functions]], below)
* '''arguments''' (a list or associative array of argument expressions)
* '''arguments''' (a list or associative array of argument expressions)
=== literal-boolean ===
Evaluates to the same boolean value (true or false) every time, given by the '''literal_value''' property. May be used as a number value, evaluates to 1 for true and 0 for false.


=== literal-number ===
=== literal-number ===


Evaluates to the same number every time, given by the '''literal_value''' property.
Evaluates to the same number every time, given by the '''literal_value''' property. All numbers are treated as [[Types/float]]s internally unless otherwise specified. May be used as a boolean value, evaluates to true for numbers > 0, anything else evaluates to false.
 
Example:
<syntaxhighlight lang="lua">
local ten =
{
  type = "literal-number",
  literal_value = 10
}
 
-- or with the noise lib, see the "Basics" section above
local noise = require("noise")
local twenty_point_five = noise.to_noise_expression(20.5)
</syntaxhighlight>


=== literal-string ===
=== literal-string ===
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e.g.
e.g.


<pre>
<syntaxhighlight lang="lua">
{
{
   type = "literal-object",
   type = "literal-object",
Line 75: Line 150:
   }
   }
}
}
</pre>
</syntaxhighlight>


Since the noise generation runtime has no notion of objects or use for them,
Since the noise generation runtime has no notion of objects or use for them,
this is useful only in constant contexts, such as the '''points''' argument
this is useful only in constant contexts, such as the argument
of the '''distance-from-nearest-point''' function.
of the '''autoplace-probability''' function (where the 'literal object' is an [[Types/AutoplaceSpecification|AutoplaceSpecitication]])
 
=== literal-expression ===
 
Returns the expression represented by its '''literal-value''' property.
 
Useful mostly for passing expressions (to be evaluated later) to the [[#spot-noise|'''spot-noise''']] function.
 
=== array-construction ===
 
'''value_expressions''' property should be a list of expressions,
each of which will be evaluated to come up with the corresponding value
in the resulting array.
 
Used to construct map positions ({x, y}) and map position lists ({{x0,y0}, {y1,y1}, ...}) for [[#offset-points|offset-points]] and [[#distance-from-nearest-point|distance-from-nearest-point]].
 
Examples of constructing a map position and map position list:
<syntaxhighlight lang="lua">
local noise = require("noise")
local tne = noise.to_noise_expression
 
local map_pos_1 = -- the map position {x = 100, y = -200} specified directly
{
  type = "array-construction",
  value_expressions = {tne(100), tne(-200)}
}
-- or with make_array from the noise lib required above
local map_pos_2 = noise.make_array({100, 200})
 
local map_pos_list = -- a map position list: {{x = 100, y = -200}, {x = 100, y = 200}}
{
  type = "array-construction",
  value_expressions = {map_pos_1, map_pos_2}
}
-- or with the noise lib
local also_map_post_list = noise.make_point_list({{100, -200}, {100, 200}})
 
</syntaxhighlight>
 
=== procedure-delimiter ===
 
Evaluates and returns the value of its '''expression''' property, which is itself an expression.
 
This hints to the compiler that it should break the subexpression into its own procedure
so that the result can be re-used in multiple places.
For instance if you want to re-use the same multioctave noise for determining probability
of multiple tiles/entities, wrap the multioctave noise expression in a procedure-delimiter.
Alternatively, make the noise its own [[Prototype/NamedNoiseExpression|NamedNoiseExpression]] and reference it by name, using a variable.
 
=== if-else-chain ===
 
Has an '''arguments''' property that is a list of condition-result expression pairs followed by a default result expression, like so:
 
<syntaxhighlight lang="lua">
{
  type = "if-else-chain",
  arguments = {
    condition1, result1,
    condition2, result2,
    ...
    defaultResult
  }
}
</syntaxhighlight >
 
The result of the if-else-chain is the value of the first result expression whose condition expression evaluated to true,
or the value of the default result ('else') expression.


== Functions ==
== Functions ==
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=== add ===
=== add ===


'''Arguments (positional)''': term, other term
'''Arguments (positional)''': between 0 and 999 numbers


Takes 2 positional arguments and adds them.
Takes the positional arguments and adds them.


=== subtract ===
=== subtract ===
 
'''Arguments (positional)''':
'''Arguments (positional)''': minuend, subtrahend
* '''minuend''' - number
* '''subtrahend''' - number


Takes 2 positional arguments and subtracts the second from the first.
Takes 2 positional arguments and subtracts the second from the first.


=== multiply ===
=== multiply ===
'''Arguments (positional)''': between 0 and 999 numbers


'''Arguments (positional)''': factor, other factor
Takes the positional arguments and multiplies them.
 
Takes 2 positional arguments and multiplies them.


=== divide ===
=== divide ===
 
'''Arguments (positional)''':
'''Arguments (positional)''': dividend, divisor
* '''dividend''' - number
* '''divisor''' - number


Takes 2 positional arguments and divides the first by the second.
Takes 2 positional arguments and divides the first by the second.


=== exponentiate ===
=== exponentiate ===
 
'''Arguments (positional)''':
'''Arguments (positional)''': base, exponent
* '''base''' - number
* '''exponent''' - number


Takes 2 positional arguments, and raises the first to the second power.
Takes 2 positional arguments, and raises the first to the second power.


=== absolute-value ===
=== absolute-value ===
'''Arguments (positional)''': value to be absoluted
'''Arguments (positional)''': value to be absoluted


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=== clamp ===
=== clamp ===
'''Arguments (positional)''':
* '''value''' - number to be clamped
* '''floor''' - lower limit
* '''ceiling''' - upper limit
First argument is clamped between the second and third.  The second is treated as a lower limit and the third the upper limit.
=== compile-time-log ===
'''Arguments''': Between 1 and 999 values of any type
Prints all of its arguments to the [[log file]] when the expression is compiled. For that it needs to part of another expression that is compiled. The last argument of the compile-time-log is returned as the "result" of the compile-time-log.
Example of usage inside a [[Prototype/NamedNoiseExpression|NamedNoiseExpression]]:
<syntaxhighlight lang="lua">
local noise = require("noise")
local tne = noise.to_noise_expression
-- see the named noise expression docs linked above the code for how this works
data:extend{{
  type = "noise-expression",
  name = "compile-log-test",
  intended_property = "elevation",
  expression = noise.compile_time_log(2000, noise.var("y"), tne(100) - noise.var("distance"))
}}
-- When "compile-log-test" is selected as the map type and a map preview or map is generated, this logs:
--  Info data-updates.lua:24: 2000.000000 reference to variable 'y' subtract
-- Furthermore, the elevation noise expression is set to 'tne(100) - noise.var("distance")', producing a circular island with a 100 tile radius
</syntaxhighlight>
=== distance-from-nearest-point ===
'''Arguments (named)''':
* '''x''' - number
* '''y''' - number
* '''points''' - list of map positions
* '''maximum_distance''' (constant, default: max double) - number
Computes the [[Wikipedia:Euclidean_distance|euclidean distance]] of the position {x, y} to all position listed in '''points''' and returns the shortest distance. The returned distance can be '''maximum_distance''' at most.
See [[#array-construction|array-construction]] for how to specify a map position list.
Example:
<syntaxhighlight lang="lua">
-- Shortest distance at the current {x, y} from the two given points, but at most 1000


'''Arguments (positional)''': value to be clamped, lower limit, upper limit
local noise = require("noise")
local tne = noise.to_noise_expression
local positions = noise.make_point_list({{-100, -40}, {-50, -200}})


First argument is clamped between the second and third. The second is treated as a lower limit and the third the upper limit.
local shortest_distance =
{
  type = "function-application",
  function_name = "distance-from-nearest-point",
  arguments = {x = noise.var("x"), y = noise.var("y"), points = positions, maximum_distance = tne(1000)}
}
-- or with the noise lib
local also_shortest_distance = noise.function_application("distance-from-nearest-point", {x = noise.var("x"), y = noise.var("y"), points = positions, maximum_distance = 1000})
</syntaxhighlight>


=== ridge ===
=== ridge ===
 
'''Arguments (positional)''':
'''Arguments (positional)''': value to be ridged, lower limit, upper limit
* '''value''' - number to be ridged
* '''floor''' - lower limit
* '''ceiling''' - upper limit


Similar to clamp but the input value is folded back across the upper and lower limits
Similar to clamp but the input value is folded back across the upper and lower limits
until it lies between them.
until it lies between them.
Example:
<syntaxhighlight lang="lua">
local noise = require("noise")
local ridge_1 = noise.ridge(6, 1, 5) -- this returns 4
local ridge_2 = noise.ridge(-1, 1, 5) -- this returns 3
</syntaxhighlight>
=== terrace ===
'''Arguments (positional)''':
* '''value''' - number
* '''offset''' (constant) - number
* '''width''' (constant) - number
* '''strength''' - number
=== modulo ===
'''Arguments (positional)''':
* '''dividend''' - number
* '''divisor''' - number
Takes 2 positional arguments and divides the first by the second and returns the remainder. This is implemented using [https://en.cppreference.com/w/cpp/numeric/math/fmod fmod(double, double)].
=== floor ===
'''Arguments (positional)''':
* '''value''' - number
Takes one 1 numeric value and returns its floor.
=== ceil ===
'''Arguments (positional)''':
* '''value''' - number
Takes one 1 numeric value and returns its ceiling.
=== bitwise-and ===
'''Arguments (positional)''': between 0 and 999 numbers
Casts the positional arguments to signed 32-bit integers and performs bitwise AND on them.
=== bitwise-or ===
'''Arguments (positional)''': between 0 and 999 numbers
Casts the positional arguments to signed 32-bit integers and performs bitwise OR on them.
=== bitwise-xor ===
'''Arguments (positional)''': between 0 and 999 numbers
Casts the positional arguments to signed 32-bit integers and performs bitwise EXCLUSIVE OR on them.
=== bitwise-not ===
'''Arguments (positional)''':
* '''value''' - number to be negated
Casts the positional argument to a signed 32-bit integer and bitwise negates it.
=== sin ===
'''Arguments (positional)''':
* '''value''' - number
Takes one 1 value and returns its sine.
=== cos ===
'''Arguments (positional)''':
* '''value''' - number
Takes one 1 value and returns its cosine.
=== atan2 ===
'''Arguments (positional)''':
* '''y''' - number
* '''x''' - number
Returns the arc tangent of y/x using the signs of arguments to determine the correct quadrant.
=== less-than ===
'''Arguments (positional)''':
* '''lhs''' - number
* '''rhs''' - number
Returns the result of lhs < rhs as literal number that is 0 for false and 1 for true.
=== less-or-equal ===
'''Arguments (positional)''':
* '''lhs''' - number
* '''rhs''' - number
Returns the result of lhs <= rhs as literal number that is 0 for false and 1 for true.
=== equals ===
'''Arguments (positional)''':
* '''lhs''' - number
* '''rhs''' - number
Returns the result of lhs == rhs as literal number that is 0 for false and 1 for true.


=== factorio-basis-noise ===
=== factorio-basis-noise ===
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* '''x'''
* '''x'''
* '''y'''
* '''y'''
* '''seed0''' - integer between 0 and 4294967295 (inclusive) used to populate the backing random noise
* '''seed0''' (constant) - integer between 0 and 4294967295 (inclusive) used to populate the backing random noise
* '''seed1''' - integer between 0 and 255 (inclusive) used to provide extra randomness when sampling
* '''seed1''' (constant) - integer between 0 and 255 (inclusive) used to provide extra randomness when sampling
* '''input_scale''' (default: 1) - x and y will be multiplied by this before sampling
* '''input_scale''' (constant, default: 1) - x and y will be multiplied by this before sampling
* '''output_scale''' (default: 1) - output will be multiplied by this before being returned
* '''output_scale''' (constant, default: 1) - output will be multiplied by this before being returned


Scaling input and output can be accomplished other ways, but are done so commonly
Scaling input and output can be accomplished other ways, but are done so commonly
as to be built into this function for performance reasons.
as to be built into this function for performance reasons.
=== factorio-quick-multioctave-noise ===
'''Arguments (named)''':
* '''x''' - number
* '''y''' - number
* '''seed0''' (constant) - number
* '''seed1''' (constant) - number
* '''input_scale''' (constant, default: 1) - number
* '''output_scale''' (constant, default: 1) - number
* '''octaves''' (constant) - number
* '''octave_input_scale_multiplier''' (constant, default: 0.5) - number
* '''octave_output_scale_multiplier''' (constant, default: 2) - number
* '''octave_seed0_shift''' (constant, default: 1) - number
=== random-penalty ===
'''Arguments (named)''':
* '''x''' - number
* '''y''' - number
* '''source''' - number
* '''seed''' (constant, default: 1) - number
* '''amplitude''' (constant, default: 1) - number
=== log2 ===
'''Argument (positional)''': value (number)
=== noise-layer-name-to-id ===
'''Argument (positional)''': value (string)
=== autoplace-probability ===
'''Argument (positional)''': value (object)
=== autoplace-richness ===
'''Argument (positional)''': value (object)
=== offset-points ===
'''Arguments (positional)''':
* '''offset''' - map position - Vector of how the positions should be shifted
* '''positions''' - list of map positions - The positions that should be shifted
See [[#array-construction|array-construction]] for how to specify map positions.
Example:
<syntaxhighlight lang="lua">
-- Shifts "positions" by {100, 90}
local noise = require("noise")
local positions = noise.make_point_list({{-10, -40}, {-50, -20}})
local offset = noise.make_array({100, 90})
local offset_positions =
{
  type = "function-application",
  function_name = "offset-points",
  arguments = {offset, positions}
}
-- or with the noise lib
local also_offset_positions = noise.function_application("offset-points", {offset, positions})
</syntaxhighlight>


=== factorio-multioctave-noise ===
=== factorio-multioctave-noise ===
Line 152: Line 512:
* '''x'''
* '''x'''
* '''y'''
* '''y'''
* '''seed0''' - integer between 0 and 4294967295 (inclusive) used to populate the backing random noise
* '''seed1''' - integer between 0 and 255 (inclusive) used to provide extra randomness when sampling
* '''octaves''' - how many layers of noise at different scales to sum
* '''persistence''' (constant) - how strong is each layer compared to the next larger one
* '''persistence''' (constant) - how strong is each layer compared to the next larger one
* '''input_scale''' (default: 1) - x and y will be multiplied by this before sampling
* '''seed0''' (constant) - integer between 0 and 4294967295 (inclusive) used to populate the backing random noise
* '''output_scale''' (default: 1) - output will be multiplied by this before being returned
* '''seed1''' (constant) - integer between 0 and 255 (inclusive) used to provide extra randomness when sampling
* '''input_scale''' (constant, default: 1) - x and y will be multiplied by this before sampling
* '''output_scale''' (constant, default: 1) - output will be multiplied by this before being returned
* '''octaves''' (constant) - how many layers of noise at different scales to sum
 
=== spot-noise ===
 
Generates random conical spots.  The map is divided into square regions, and within each region, candidate points are chosen at random and target density, spot quantity, and radius are calculated for each point (or one of every '''skip_span''' candidate points) by configured expressions.  Each spot contributes a quantity to a regional target total (which is the average of sampled target densities times the area of the region) until the total has been reached or a maximum spot count is hit.  The output value of the function is the maximum height of any spot at a given point.
 
The parameters that provide expressions to be evaluated for each point (all named '''something_expression''') need to actually return expression objects. 
 
The quantity of the spot is assumed to be the same as its volume.  Since the volume of a cone is '''pi * radius^2 * height / 3''',
the height ('peak value') of any given spot is calculated as '''3 * quantity / (pi * radius^2)'''
 
'''Arguments (named)''':
 
* '''x''' (number)
* '''y''' (number)
* '''seed0''' (constant integer) - random seed, part 1 - usually the map seed is used
* '''seed1''' (constant integer) - random seed, part 2 - usually chosen to identify the noise layer
* '''region_size''' (constant integer, default: 512) - width/height of each region
* '''skip_offset''' (constant integer, default: 0) - offset of the first candidate point to use
* '''skip_span''' (constant integer, default: 1) - number of candidate points to skip over after each one used as a spot, including the used one
* '''candidate_point_count''' (constant integer, default:256) - how many candidate points to generate
* '''candidate_spot_count''' (constant integer, default depends on skip_span) - an alternative to candidate_point_count - number of spots to generate: '''candidate_spot_count = X''' is equivalent to '''candidate_point_count / skip_span = X'''
* '''suggested_minimum_candidate_point_spacing''' (constant number, default depends on region size and candidate_point_count) - minimum spacing to *try* to achieve while randomly picking points; spot noise may end up placing spots closer than this in crowded regions
* '''hard_region_target_quantity''' (constant boolean, default: true) - whether to place a hard limit on the total quantity in each region by reducing the size of any spot (which will be the last spot chosen) that would put it over the limit.
* '''density_expression''' (number-returningexpression) - an expression that will be evaluated for each candidate spot to calculate density at that point
* '''spot_quantity_expression''' (number-returningexpression) - an expression that will be evaluated for each candidate spot to calculate the spot's quantity
* '''spot_radius_expression''' (number-returning expression) - an expression that will be evaluated for each candidate spot to calculate the spot's radius (this, together with quantity, will determine the spots peak value)
* '''spot_favorability_expression''' (number-returning expression) - an expression that will be evaluated for each candidate spot to calculate the spot's favorability; spots with higher favorability will be considered first when building the final list of spots for a region
* '''basement_value''' (constant) - number
* '''maximum_spot_basement_radius''' (constant) - number
* '''comment''' (constant) - comment string
 
The infinite series of candidate points (of which '''candidate_point_count''' are actually considered) generated by '''spot-noise''' expressions with the same '''seed0''', '''seed1''', '''region_size''', and '''suggested_minimum_candidate_point_spacing''' will be identical.  This allows multiple spot-noise expressions (e.g. for different ore patches) to avoid overlap by using different points from the same list, determined by '''skip_span''' and '''skip_offset'''.


== Example definition ==
== Example definition ==
Line 163: Line 555:
To override the 'temperature' named noise expression with one that linearly increases to the southeast:
To override the 'temperature' named noise expression with one that linearly increases to the southeast:


<pre>
<syntaxhighlight lang="lua">
local noise = require("noise");
local noise = require("noise");


Line 169: Line 561:
   {
   {
     type = "noise-expression",
     type = "noise-expression",
     name = "temperature", -- for 0.17; for 0.16 override "default-temperature" instead.
     name = "new-temperature-function",
    intended_property = "temperature", -- Makes this available in the 'temperature generator' drop-down
     expression = noise.define_noise_function( function(x,y,tile,map)
     expression = noise.define_noise_function( function(x,y,tile,map)
       return (x + y) / 1000
       return (x + y) / 1000
Line 175: Line 568:
   }
   }
}
}
</pre>
</syntaxhighlight>


Which is equivalent to:
Which is equivalent to:


<pre>
<syntaxhighlight lang="lua">
local noise = require("noise");
 
data:extend{
data:extend{
   {
   {
     type = "noise-expression",
     type = "noise-expression",
     name = "temperature",
     name = "new-temperature-function",
    intended_property = "temperature",
     expression = {
     expression = {
       type = "function-application",
       type = "function-application",
Line 212: Line 604:
   }
   }
}
}
</pre>
</syntaxhighlight>
 
== See also ==
 
* [https://togos.github.io/togos-example-noise-programs/ A tutorial on authoring noise functions]

Latest revision as of 15:28, 25 November 2020

Basics

A fragment of a functional program used to generate coherent noise, probably for purposes related to terrain generation.

Noise expressions can be provided as table literals or built using functions in the built-in noise library. The built-in noise library allows writing much more concise code, so its usage will be shown in most examples on this page.
noise.define_noise_function allows noise expressions to be defined using a shorthand that's a subset of Lua (see example definition for an example and its literal equivalent).

Types/NoiseExpression is used by NamedNoiseExpressionPrototype::expression, AutoplaceSpecification::probability_expression and AutoplaceSpecification::richness_expression.

Mandatory properties

type

Type: Types/string

Name of the type of this expression. Which other properties apply depend on the expression type.

Expression types

variable

Properties:

Reference to a pre-defined variable, constant, or a named noise expression. Variables referencing named noise expressions may have their reference overridden by other named noise expression if their intended_property is the variable name and it is selected by the user in the map generator GUI. See Prototype/NamedNoiseExpression#Custom intended_property.

Predefined variables:

  • x - number - Current x position on the map
  • y - number - Current y position on the map

Predefined constants (note that map gen settings can also be provided by a Types/MapGenPreset):

  • map_seed - number - Taken from the MapGenSettings
  • map_width - number - Taken from the MapGenSettings
  • map_height - number - Taken from the MapGenSettings
  • water_level - number - Don't use; use wlc_elevation_minimum instead
  • finite_water_level - number - Don't use; use wlc_elevation_offset instead
  • wlc_elevation_offset - number - When the result of 10 × log2("water") with "water" from MapGenSettings is finite, wlc_elevation_offset = -(10 * log2(water)), else wlc_elevation_offset = 0
  • wlc_elevation_minimum - number - When the result of 10 × log2("water") with "water" from MapGenSettings is infinite, wlc_elevation_minimum = -∞, else wlc_elevation_minimum = 4
  • cliff_elevation_offset - number - Taken from the MapGenSettings (CliffPlacementSettings)
  • cliff_elevation_interval - number - Taken from the MapGenSettings (CliffPlacementSettings)
  • control-setting:cliffs:richness:multiplier - number - Taken from the MapGenSettings (CliffPlacementSettings)
  • terrace_elevation_offset - number - Calculated from the cliff and water settings.
  • terrace_elevation_interval - number - Same as "cliff_elevation_interval"
  • starting_area_radius - number - Taken from the MapGenSettings
  • starting_positions - map position list - Taken from the MapGenSettings
  • starting_lake_positions - map position list - Calculated from starting positions and map seed
  • peaceful_mode - boolean - Taken from the MapGenSettings
  • control-setting:<prototype name>:frequency - number - Provided for all of the tile, entity, decorative, autoplace-control prototypes.
  • control-setting:<prototype name>:size - number - Provided for all of the tile, entity, decorative, autoplace-control prototypes.
  • control-setting:<prototype name>:richness - number - Provided for all of the tile, entity, decorative, autoplace-control prototypes.

A list of all named noise expression defined in the base game can be found at Data.raw#noise-expression. Notable expressions defined by the base game are:

  • distance - number - noise.distance_from(noise.var("x"), noise.var("y"), noise.var("starting_positions")), so the distance from the closest starting position. distance is never < 0.
  • tier_from_start - number - noise.max(0.0, noise.var("distance") - noise.var("starting_area_radius")) / noise.var("starting_area_radius)
  • tier - number - noise.var("tier_from_start"), so same as tier_from_start.
  • starting_area_weight - number - 1 - noise.min(1.0, noise.var("tier_from_start") / 2.0)
  • moisture - number - A value between 0 and 1 that determines whether a tile becomes sandy (low moisture) or grassy (high moisture).
  • aux - number - A value between 0 and 1 that determines whether low-moisture tiles become sand or red desert.
  • temperature - number - Provides a value (vaguely representing degrees Celsius, varying between -20 and 50) that is used (together with moisture and aux) as part of tree and decorative placement.
  • elevation - number - Tiles values less than zero become water. Cliffs are placed along certain contours according to CliffPlacementSettings.
  • cliffiness - number - Determines whether (when >0.5) or not (when <0.5) a cliff will be placed at an otherwise suitable (according to CliffPlacementSettings) location.
  • enemy-base-intensity - number - Is referenced by both enemy-base-frequency and enemy-base-radius. i.e. if this is overridden, enemy base frequency and size will both be affected and do something reasonable. By default, this expression returns a value proportional to distance from any starting point, clamped at about 7.
  • enemy-base-frequency - number - Represents average number of enemy bases per tile for a region, by default in terms of enemy-base-intensity.
  • enemy-base-radius - number - Represents the radius of an enemy base, if one were to be placed on the given tile, by default proportional to a constant plus enemy-base-intensity.

Note that the named noise expressions are all defined in Lua, so mods may remove or change the notable expressions listed above or change how they are used in the map generation.

Examples:

local noise = require("noise")

local y = 
{
  type = "variable",
  variable_name = "y" -- predefined variable
}
local x = noise.var("x") -- predefined variable, with the noise lib

local width = 
{
  type = "variable",
  variable_name = "map_width" -- predefined constant
}
local height = noise.var("map_height") -- predefined constant, with the noise lib

local aux = 
{
  type = "variable",
  variable_name = "aux" -- named noise expression
}
local cliffiness = noise.var("cliffiness") -- named noise expression, with the noise lib

function-application

Apply a function to a list or associative array of arguments. Some functions expect arguments to be named and some expect them not to be.

Function calls are their own class of expression (as opposed to every function just being its own expression type) because function calls all have similar properties -- arguments are themselves expressions, a function call with all-constant arguments can be constant-folded (due to referential transparency), etc.

Properties:

  • function_name (a string; see #Functions, below)
  • arguments (a list or associative array of argument expressions)

literal-boolean

Evaluates to the same boolean value (true or false) every time, given by the literal_value property. May be used as a number value, evaluates to 1 for true and 0 for false.

literal-number

Evaluates to the same number every time, given by the literal_value property. All numbers are treated as Types/floats internally unless otherwise specified. May be used as a boolean value, evaluates to true for numbers > 0, anything else evaluates to false.

Example:

local ten = 
{
  type = "literal-number",
  literal_value = 10
}

-- or with the noise lib, see the "Basics" section above
local noise = require("noise")
local twenty_point_five = noise.to_noise_expression(20.5)

literal-string

Evaluates to the same string every time, given by the literal_value property.

Since the noise generation runtime has no notion of strings or use for them, this is useful only in constant contexts.

literal-object

Evaluates to the same object every time, given by the literal_value property.

e.g.

{
  type = "literal-object",
  literal_value = {
    name = "Bob Hope",
    birth_date = {
      year = 1903,
      month = 5,
      day_of_month = 29
    }
  }
}

Since the noise generation runtime has no notion of objects or use for them, this is useful only in constant contexts, such as the argument of the autoplace-probability function (where the 'literal object' is an AutoplaceSpecitication)

literal-expression

Returns the expression represented by its literal-value property.

Useful mostly for passing expressions (to be evaluated later) to the spot-noise function.

array-construction

value_expressions property should be a list of expressions, each of which will be evaluated to come up with the corresponding value in the resulting array.

Used to construct map positions ({x, y}) and map position lists ({{x0,y0}, {y1,y1}, ...}) for offset-points and distance-from-nearest-point.

Examples of constructing a map position and map position list:

local noise = require("noise")
local tne = noise.to_noise_expression

local map_pos_1 = -- the map position {x = 100, y = -200} specified directly
{
  type = "array-construction",
  value_expressions = {tne(100), tne(-200)}
}
-- or with make_array from the noise lib required above
local map_pos_2 = noise.make_array({100, 200})

local map_pos_list = -- a map position list: {{x = 100, y = -200}, {x = 100, y = 200}}
{
  type = "array-construction",
  value_expressions = {map_pos_1, map_pos_2}
}
-- or with the noise lib
local also_map_post_list = noise.make_point_list({{100, -200}, {100, 200}})

procedure-delimiter

Evaluates and returns the value of its expression property, which is itself an expression.

This hints to the compiler that it should break the subexpression into its own procedure so that the result can be re-used in multiple places. For instance if you want to re-use the same multioctave noise for determining probability of multiple tiles/entities, wrap the multioctave noise expression in a procedure-delimiter. Alternatively, make the noise its own NamedNoiseExpression and reference it by name, using a variable.

if-else-chain

Has an arguments property that is a list of condition-result expression pairs followed by a default result expression, like so:

{
  type = "if-else-chain",
  arguments = {
    condition1, result1,
    condition2, result2,
    ...
    defaultResult
  }
}

The result of the if-else-chain is the value of the first result expression whose condition expression evaluated to true, or the value of the default result ('else') expression.

Functions

add

Arguments (positional): between 0 and 999 numbers

Takes the positional arguments and adds them.

subtract

Arguments (positional):

  • minuend - number
  • subtrahend - number

Takes 2 positional arguments and subtracts the second from the first.

multiply

Arguments (positional): between 0 and 999 numbers

Takes the positional arguments and multiplies them.

divide

Arguments (positional):

  • dividend - number
  • divisor - number

Takes 2 positional arguments and divides the first by the second.

exponentiate

Arguments (positional):

  • base - number
  • exponent - number

Takes 2 positional arguments, and raises the first to the second power.

absolute-value

Arguments (positional): value to be absoluted

Takes a single positional argument and returns its absolute value. i.e. If the argument is negative, it is inverted.

clamp

Arguments (positional):

  • value - number to be clamped
  • floor - lower limit
  • ceiling - upper limit

First argument is clamped between the second and third. The second is treated as a lower limit and the third the upper limit.

compile-time-log

Arguments: Between 1 and 999 values of any type

Prints all of its arguments to the log file when the expression is compiled. For that it needs to part of another expression that is compiled. The last argument of the compile-time-log is returned as the "result" of the compile-time-log.

Example of usage inside a NamedNoiseExpression:

local noise = require("noise")
local tne = noise.to_noise_expression

-- see the named noise expression docs linked above the code for how this works
data:extend{{
  type = "noise-expression",
  name = "compile-log-test",
  intended_property = "elevation",
  expression = noise.compile_time_log(2000, noise.var("y"), tne(100) - noise.var("distance"))
}}

-- When "compile-log-test" is selected as the map type and a map preview or map is generated, this logs:
--  Info data-updates.lua:24: 2000.000000 reference to variable 'y' subtract
-- Furthermore, the elevation noise expression is set to 'tne(100) - noise.var("distance")', producing a circular island with a 100 tile radius

distance-from-nearest-point

Arguments (named):

  • x - number
  • y - number
  • points - list of map positions
  • maximum_distance (constant, default: max double) - number

Computes the euclidean distance of the position {x, y} to all position listed in points and returns the shortest distance. The returned distance can be maximum_distance at most.

See array-construction for how to specify a map position list.

Example:

-- Shortest distance at the current {x, y} from the two given points, but at most 1000

local noise = require("noise")
local tne = noise.to_noise_expression
local positions = noise.make_point_list({{-100, -40}, {-50, -200}})

local shortest_distance = 
{
  type = "function-application",
  function_name = "distance-from-nearest-point",
  arguments = {x = noise.var("x"), y = noise.var("y"), points = positions, maximum_distance = tne(1000)}
}
-- or with the noise lib
local also_shortest_distance = noise.function_application("distance-from-nearest-point", {x = noise.var("x"), y = noise.var("y"), points = positions, maximum_distance = 1000})

ridge

Arguments (positional):

  • value - number to be ridged
  • floor - lower limit
  • ceiling - upper limit

Similar to clamp but the input value is folded back across the upper and lower limits until it lies between them.

Example:

local noise = require("noise")

local ridge_1 = noise.ridge(6, 1, 5) -- this returns 4

local ridge_2 = noise.ridge(-1, 1, 5) -- this returns 3

terrace

Arguments (positional):

  • value - number
  • offset (constant) - number
  • width (constant) - number
  • strength - number

modulo

Arguments (positional):

  • dividend - number
  • divisor - number

Takes 2 positional arguments and divides the first by the second and returns the remainder. This is implemented using fmod(double, double).

floor

Arguments (positional):

  • value - number

Takes one 1 numeric value and returns its floor.

ceil

Arguments (positional):

  • value - number

Takes one 1 numeric value and returns its ceiling.

bitwise-and

Arguments (positional): between 0 and 999 numbers

Casts the positional arguments to signed 32-bit integers and performs bitwise AND on them.

bitwise-or

Arguments (positional): between 0 and 999 numbers

Casts the positional arguments to signed 32-bit integers and performs bitwise OR on them.

bitwise-xor

Arguments (positional): between 0 and 999 numbers

Casts the positional arguments to signed 32-bit integers and performs bitwise EXCLUSIVE OR on them.

bitwise-not

Arguments (positional):

  • value - number to be negated

Casts the positional argument to a signed 32-bit integer and bitwise negates it.

sin

Arguments (positional):

  • value - number

Takes one 1 value and returns its sine.

cos

Arguments (positional):

  • value - number

Takes one 1 value and returns its cosine.

atan2

Arguments (positional):

  • y - number
  • x - number

Returns the arc tangent of y/x using the signs of arguments to determine the correct quadrant.

less-than

Arguments (positional):

  • lhs - number
  • rhs - number

Returns the result of lhs < rhs as literal number that is 0 for false and 1 for true.

less-or-equal

Arguments (positional):

  • lhs - number
  • rhs - number

Returns the result of lhs <= rhs as literal number that is 0 for false and 1 for true.

equals

Arguments (positional):

  • lhs - number
  • rhs - number

Returns the result of lhs == rhs as literal number that is 0 for false and 1 for true.

factorio-basis-noise

Arguments (named):

  • x
  • y
  • seed0 (constant) - integer between 0 and 4294967295 (inclusive) used to populate the backing random noise
  • seed1 (constant) - integer between 0 and 255 (inclusive) used to provide extra randomness when sampling
  • input_scale (constant, default: 1) - x and y will be multiplied by this before sampling
  • output_scale (constant, default: 1) - output will be multiplied by this before being returned

Scaling input and output can be accomplished other ways, but are done so commonly as to be built into this function for performance reasons.

factorio-quick-multioctave-noise

Arguments (named):

  • x - number
  • y - number
  • seed0 (constant) - number
  • seed1 (constant) - number
  • input_scale (constant, default: 1) - number
  • output_scale (constant, default: 1) - number
  • octaves (constant) - number
  • octave_input_scale_multiplier (constant, default: 0.5) - number
  • octave_output_scale_multiplier (constant, default: 2) - number
  • octave_seed0_shift (constant, default: 1) - number

random-penalty

Arguments (named):

  • x - number
  • y - number
  • source - number
  • seed (constant, default: 1) - number
  • amplitude (constant, default: 1) - number

log2

Argument (positional): value (number)

noise-layer-name-to-id

Argument (positional): value (string)

autoplace-probability

Argument (positional): value (object)

autoplace-richness

Argument (positional): value (object)

offset-points

Arguments (positional):

  • offset - map position - Vector of how the positions should be shifted
  • positions - list of map positions - The positions that should be shifted

See array-construction for how to specify map positions.

Example:

-- Shifts "positions" by {100, 90}

local noise = require("noise")
local positions = noise.make_point_list({{-10, -40}, {-50, -20}})
local offset = noise.make_array({100, 90})
local offset_positions = 
{
  type = "function-application",
  function_name = "offset-points",
  arguments = {offset, positions}
}
-- or with the noise lib
local also_offset_positions = noise.function_application("offset-points", {offset, positions})

factorio-multioctave-noise

Arguments (named):

  • x
  • y
  • persistence (constant) - how strong is each layer compared to the next larger one
  • seed0 (constant) - integer between 0 and 4294967295 (inclusive) used to populate the backing random noise
  • seed1 (constant) - integer between 0 and 255 (inclusive) used to provide extra randomness when sampling
  • input_scale (constant, default: 1) - x and y will be multiplied by this before sampling
  • output_scale (constant, default: 1) - output will be multiplied by this before being returned
  • octaves (constant) - how many layers of noise at different scales to sum

spot-noise

Generates random conical spots. The map is divided into square regions, and within each region, candidate points are chosen at random and target density, spot quantity, and radius are calculated for each point (or one of every skip_span candidate points) by configured expressions. Each spot contributes a quantity to a regional target total (which is the average of sampled target densities times the area of the region) until the total has been reached or a maximum spot count is hit. The output value of the function is the maximum height of any spot at a given point.

The parameters that provide expressions to be evaluated for each point (all named something_expression) need to actually return expression objects.

The quantity of the spot is assumed to be the same as its volume. Since the volume of a cone is pi * radius^2 * height / 3, the height ('peak value') of any given spot is calculated as 3 * quantity / (pi * radius^2)

Arguments (named):

  • x (number)
  • y (number)
  • seed0 (constant integer) - random seed, part 1 - usually the map seed is used
  • seed1 (constant integer) - random seed, part 2 - usually chosen to identify the noise layer
  • region_size (constant integer, default: 512) - width/height of each region
  • skip_offset (constant integer, default: 0) - offset of the first candidate point to use
  • skip_span (constant integer, default: 1) - number of candidate points to skip over after each one used as a spot, including the used one
  • candidate_point_count (constant integer, default:256) - how many candidate points to generate
  • candidate_spot_count (constant integer, default depends on skip_span) - an alternative to candidate_point_count - number of spots to generate: candidate_spot_count = X is equivalent to candidate_point_count / skip_span = X
  • suggested_minimum_candidate_point_spacing (constant number, default depends on region size and candidate_point_count) - minimum spacing to *try* to achieve while randomly picking points; spot noise may end up placing spots closer than this in crowded regions
  • hard_region_target_quantity (constant boolean, default: true) - whether to place a hard limit on the total quantity in each region by reducing the size of any spot (which will be the last spot chosen) that would put it over the limit.
  • density_expression (number-returningexpression) - an expression that will be evaluated for each candidate spot to calculate density at that point
  • spot_quantity_expression (number-returningexpression) - an expression that will be evaluated for each candidate spot to calculate the spot's quantity
  • spot_radius_expression (number-returning expression) - an expression that will be evaluated for each candidate spot to calculate the spot's radius (this, together with quantity, will determine the spots peak value)
  • spot_favorability_expression (number-returning expression) - an expression that will be evaluated for each candidate spot to calculate the spot's favorability; spots with higher favorability will be considered first when building the final list of spots for a region
  • basement_value (constant) - number
  • maximum_spot_basement_radius (constant) - number
  • comment (constant) - comment string

The infinite series of candidate points (of which candidate_point_count are actually considered) generated by spot-noise expressions with the same seed0, seed1, region_size, and suggested_minimum_candidate_point_spacing will be identical. This allows multiple spot-noise expressions (e.g. for different ore patches) to avoid overlap by using different points from the same list, determined by skip_span and skip_offset.

Example definition

To override the 'temperature' named noise expression with one that linearly increases to the southeast:

local noise = require("noise");

data:extend{
  {
    type = "noise-expression",
    name = "new-temperature-function",
    intended_property = "temperature", -- Makes this available in the 'temperature generator' drop-down
    expression = noise.define_noise_function( function(x,y,tile,map)
      return (x + y) / 1000
    end)
  }
}

Which is equivalent to:

data:extend{
  {
    type = "noise-expression",
    name = "new-temperature-function",
    intended_property = "temperature",
    expression = {
      type = "function-application",
      function_name = "divide",
      arguments = {
        {
          type = "function-application",
          function_name = "add",
          arguments = {
            {
              type = "variable",
              variable_name = "x"
            },
            {
              type = "variable",
              variable_name = "y"
            }
          }
        },
        {
          type = "literal-number",
          literal_value = 1000
        }
      }
    }
  }
}

See also