Nothing
inst/extdata/EmptyConfig/config_empty.R
In gen3sis: General Engine for Eco-Evolutionary Simulations
######################################
### METADATA ###
######################################
# Version: 1.0
#
# Author:
#
# Date: 01.07.2020
#
# Landscape:
#
# Publications:
#
# Description:
#
######################################
######################################
### General settings ###
######################################
# set the random seed for the simulation.
random_seed = NA
# set the starting time step or leave NA to use the earliest/highest time-step.
start_time = NA
# set the end time step or leave as NA to use the latest/lowest time-step (0).
end_time = NA
# maximum total number of species in the simulation before it is aborted.
max_number_of_species = 25000
# maximum number of species within one cell before the simulation is aborted.
max_number_of_coexisting_species = 2500
# a list of traits to include with each species
# a "dispersal" trait is implictly added in any case
trait_names = c("dispersal")
# ranges to scale the input environments with:
# not listed variable: no scaling takes place
# listed, set to NA: the environmental variable will be scaled from [min, max] to [0, 1]
# listed with a given range r: the environmental variable will be scaled from [r1, r2] to [0, 1]
environmental_ranges = list( )
######################################
### Observer ###
######################################
# a place to inspect the internal state of the simulation and collect additional information if desired.
end_of_timestep_observer = function(data, vars, config){
# the list of all species can be found in data$all_species
# the current landscape can be found in data$landscape
# saving functions example:
# save_landscape()
# save_species()
# plotting functions example:
# plot environmental conditions
# plot_landscape(data$landscape)
# plot richness
# plot_richness(data$all_species, data$landscape)
# plot a specific environmental condition
# plot_raster_single(data$landscape$environment[,"temp"], data$landscape, "temp", NA)
# plot species 1 range
# plot_species_presence(data$all_species[[1]], data$landscape)
# plot(0,type="n",axes=FALSE,ann=FALSE)
}
######################################
### Initialization ###
######################################
# the initial abundance of a newly colonized cell, both during setup and later when
# colonizing a cell during the dispersal.
initial_abundance = 1
# place species in the landscape:
create_ancestor_species <- function(landscape, config) {
stop("create the initial species here")
}
######################################
### Dispersal ###
######################################
# the maximum range to consider when calculating the distances from local distance inputs.
max_dispersal <- Inf
# returns n dispersal values.
get_dispersal_values <- function(n, species, landscape, config) {
stop("calculate dispersal values here")
}
######################################
### Speciation ###
######################################
# threshold for genetic distance after which a speciation event takes place.
divergence_threshold = NULL
# factor by which the divergence is increased between geographically isolated population.
# can also be a matrix between the different population clusters.
get_divergence_factor <- function(species, cluster_indices, landscape, config) {
stop("calculate divergence factor here")
}
######################################
### Evolution ###
######################################
# mutate the traits of a species and return the new traits matrix.
apply_evolution <- function(species, cluster_indices, landscape, config) {
stop("mutate species traits here")
}
######################################
### Ecology ###
######################################
# called for every cell with all occurring species, this function calculates abundances and/or
# who survives for each sites.
# returns a vector of abundances.
# set the abundance to 0 for every species supposed to die.
apply_ecology <- function(abundance, traits, environment, config) {
stop("calculate species abundances and deaths here")
}
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gen3sis documentation built on Nov. 22, 2023, 5:07 p.m.
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######################################
### METADATA ###
######################################
# Version: 1.0
#
# Author:
#
# Date: 01.07.2020
#
# Landscape:
#
# Publications:
#
# Description:
#
######################################
######################################
### General settings ###
######################################
# set the random seed for the simulation.
random_seed = NA
# set the starting time step or leave NA to use the earliest/highest time-step.
start_time = NA
# set the end time step or leave as NA to use the latest/lowest time-step (0).
end_time = NA
# maximum total number of species in the simulation before it is aborted.
max_number_of_species = 25000
# maximum number of species within one cell before the simulation is aborted.
max_number_of_coexisting_species = 2500
# a list of traits to include with each species
# a "dispersal" trait is implictly added in any case
trait_names = c("dispersal")
# ranges to scale the input environments with:
# not listed variable: no scaling takes place
# listed, set to NA: the environmental variable will be scaled from [min, max] to [0, 1]
# listed with a given range r: the environmental variable will be scaled from [r1, r2] to [0, 1]
environmental_ranges = list( )
######################################
### Observer ###
######################################
# a place to inspect the internal state of the simulation and collect additional information if desired.
end_of_timestep_observer = function(data, vars, config){
# the list of all species can be found in data$all_species
# the current landscape can be found in data$landscape
# saving functions example:
# save_landscape()
# save_species()
# plotting functions example:
# plot environmental conditions
# plot_landscape(data$landscape)
# plot richness
# plot_richness(data$all_species, data$landscape)
# plot a specific environmental condition
# plot_raster_single(data$landscape$environment[,"temp"], data$landscape, "temp", NA)
# plot species 1 range
# plot_species_presence(data$all_species[[1]], data$landscape)
# plot(0,type="n",axes=FALSE,ann=FALSE)
}
######################################
### Initialization ###
######################################
# the initial abundance of a newly colonized cell, both during setup and later when
# colonizing a cell during the dispersal.
initial_abundance = 1
# place species in the landscape:
create_ancestor_species <- function(landscape, config) {
stop("create the initial species here")
}
######################################
### Dispersal ###
######################################
# the maximum range to consider when calculating the distances from local distance inputs.
max_dispersal <- Inf
# returns n dispersal values.
get_dispersal_values <- function(n, species, landscape, config) {
stop("calculate dispersal values here")
}
######################################
### Speciation ###
######################################
# threshold for genetic distance after which a speciation event takes place.
divergence_threshold = NULL
# factor by which the divergence is increased between geographically isolated population.
# can also be a matrix between the different population clusters.
get_divergence_factor <- function(species, cluster_indices, landscape, config) {
stop("calculate divergence factor here")
}
######################################
### Evolution ###
######################################
# mutate the traits of a species and return the new traits matrix.
apply_evolution <- function(species, cluster_indices, landscape, config) {
stop("mutate species traits here")
}
######################################
### Ecology ###
######################################
# called for every cell with all occurring species, this function calculates abundances and/or
# who survives for each sites.
# returns a vector of abundances.
# set the abundance to 0 for every species supposed to die.
apply_ecology <- function(abundance, traits, environment, config) {
stop("calculate species abundances and deaths here")
}
Try the gen3sis package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
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We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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