inst/ubinc/templates/r_components.R
In john-harrold/ubiquity: PKPD, PBPK, and Systems Pharmacology Modeling Tools
<COMMENTS>
system_fetch_cfg_<MODEL_PREFIX> = function(){
#
# This function returns a list that stores all of the information about the
# system including parameter values, system indices used, initial condition
# assignments, etc.
#
#Creating the cfg variable
cfg = list();
c_libfile_base = "<MODEL_PREFIX>"
# Initializing the top level elements of cfg
cfg[["options"]] = list(mi = list(),
misc = list(),
time_scales = list(),
inputs = list(),
simulation_options = list(),
stochastic = list(),
logging = list())
cfg[["parameters"]] = list(sets = list(),
matrix = NULL,
current_set = NULL,
values = NULL)
cfg[["titration"]] = list(titrate = NULL,
times = c(),
rules = list())
cfg[["iiv"]] = list(sets = list(),
current_set = NULL,
iivs = list(),
parameters = list(),
values = NULL)
cfg[["estimation"]] = list(options = list(),
parameters = list(),
objective_type = list(),
mi = list())
cfg[["reporting"]] = list(meta_pptx = list(),
meta_docx = list(),
enabled = FALSE)
cfg[["reporting"]][["meta_pptx"]] =
list(title = list(),
section = list(),
content = list(),
two_col = list(),
md_def = list())
cfg[["reporting"]][["meta_docx"]] =
list(ph_content = list(),
styles = list(),
captions = list(),
md_def = list())
cfg[["ve"]] = list()
# JMH initialize the following:
# cfg[["data"]]
# cfg[["cohorts"]]
# storing the location of the temporary directory and the distribution type
cfg[["options"]][["misc"]][["temp_directory"]] = '<TEMP_DIRECTORY>'
cfg[["options"]][["misc"]][["distribution"]] = '<DISTRIBUTION>'
cfg[["options"]][["misc"]][["system_file"]] = '<SYSTEM_FILE>'
# storing the base file name of the compiled C file
cfg[["options"]][["misc"]][["c_libfile_base"]] = c_libfile_base
# Finding the location of the template directory
if(cfg[["options"]][["misc"]][["distribution"]] == "stand alone"){
cfg[["options"]][["misc"]][["templates"]] = file.path(getwd(), "library", "templates")
} else {
package_dir = system.file("", package="ubiquity")
cfg[["options"]][["misc"]][["templates"]] = file.path(package_dir, "ubinc", "templates")
}
# By default we will indicate that we're running at the
# scripting level. This will be altered at the Shiny App level
cfg[["options"]][["misc"]][["operating_environment"]] = "script"
# defaulting to integrating with r file
#cfg[["options"]][["simulation_options"]][["integrate_with"]] = "r-file"
# default simulation options
cfg[["options"]][["simulation_options"]] =
list(parallel = "No", # No parallelization
compute_cores = 1,
integrate_with = "r-file", # Integrating with R file
initial_conditions = NA, # No specified initial conditions
solver_opts = list())
# If the library has been loaded we switch to C
if(is.null(getLoadedDLLs()[[c_libfile_base]]) == FALSE){
if(getLoadedDLLs()[[c_libfile_base]][["dynamicLookup"]] == TRUE){
cfg[["options"]][["simulation_options"]][["integrate_with"]] = "c-file"
}
}
# defaulting to no specified initial condition
#cfg[["options"]][["simulation_options"]][["initial_conditions"]] = NA
# System parameter information
<FETCH_SYS_PARAMS>
# Static secondary parameters
<FETCH_SYS_SSP>
# Dynamic secondary parameters
<FETCH_SYS_DSP>
# Indices mapping state, parameter, etc. names
# to their index in the different vectors
<FETCH_SYS_INDICES>
<FETCH_SYS_INDICES_ODE_OUTPUT>
# Parameter Sets
<FETCH_SYS_PSETS>
# Interindiviudal Varability Information
<FETCH_SYS_IIV>
# Variance Equations
<FETCH_SYS_VE>
<FETCH_SYS_INFUSIONS>
<FETCH_SYS_COVARIATES>
# identifying that the current set is the default
cfg[["parameters"]][["current_set"]] = "default";
# Nonzero initial conditions
<FETCH_SYS_IC>
# timescale information
<FETCH_SYS_TS>
# data set
<FETCH_SYS_DATA>
# bolus inputs
<FETCH_SYS_BOLUS>
# misc options
<FETCH_SYS_MISC>
# Defaulting output times to gui output times
cfg[["options"]][["simulation_options"]][["output_times"]] =
eval(parse(text=cfg[["options"]][["misc"]][["output_times"]]))
<FETCH_SYS_OPTIONS>
# titration options
cfg[["titration"]][["titrate"]] = FALSE
cfg[["titration"]][["times"]] = c() # vector of times where titration can occur
cfg[["titration"]][["rules"]] = list() # titration rules
# default stochastic options
cfg[["options"]][["stochastic"]] =
list(nsub = 100,
seed = 8675309,
ci = 95,
ponly = FALSE,
sub_file = NULL,
sub_file_sample = "with replacement")
# default logging options
cfg[["options"]][["logging"]] =
list(enabled = TRUE,
file = file.path(cfg[["options"]][["misc"]][["temp_directory"]],"ubiquity_log.txt"),
timestamp = TRUE ,
ts_str = "%Y-%m-%d %H:%M:%S",
debug = FALSE,
verbose = TRUE)
# default estimation options
cfg[["estimation"]][["options"]] =
list(observation_function = "system_od_general",
optimizer = "optim",
method = "Nelder-Mead",
control = list(trace=TRUE, REPORT=10))
#--------------------------------------------------------------------
# default reporting options for powerpoint
#
# Set sub_title fields to NULL if they do not exist in the template
#
# this is the information the title slide
cfg[["reporting"]][["meta_pptx"]][["title"]][["layout"]]$general = "title_slide"
cfg[["reporting"]][["meta_pptx"]][["title"]][["master"]]$general = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["title"]][["type"]]$title = 'ctrTitle'
cfg[["reporting"]][["meta_pptx"]][["title"]][["type"]]$sub_title = 'subTitle'
cfg[["reporting"]][["meta_pptx"]][["title"]][["indices"]]$title = 3
cfg[["reporting"]][["meta_pptx"]][["title"]][["indices"]]$sub_title = 4
cfg[["reporting"]][["meta_pptx"]][["title"]][["ph_labels"]]$title = "Title 1"
cfg[["reporting"]][["meta_pptx"]][["title"]][["ph_labels"]]$sub_title = "Subtitle 2"
# this is the information the section title slide
cfg[["reporting"]][["meta_pptx"]][["section"]][["layout"]]$general = "section_slide"
cfg[["reporting"]][["meta_pptx"]][["section"]][["master"]]$general = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["section"]][["type"]]$title = 'ctrTitle'
cfg[["reporting"]][["meta_pptx"]][["section"]][["type"]]$sub_title = 'subTitle'
cfg[["reporting"]][["meta_pptx"]][["section"]][["indices"]]$title = 3
cfg[["reporting"]][["meta_pptx"]][["section"]][["indices"]]$sub_title = 4
cfg[["reporting"]][["meta_pptx"]][["section"]][["ph_labels"]]$title = "Title 1"
cfg[["reporting"]][["meta_pptx"]][["section"]][["ph_labels"]]$sub_title = "Subtitle 2"
# These contain the mapping information for content in the template
# The main dimensions are:
# units = inches, height = 5.0, width = 9.5
# Text content
cfg[["reporting"]][["meta_pptx"]][["content"]][["layout"]]$general = "content_text"
cfg[["reporting"]][["meta_pptx"]][["content"]][["master"]]$general = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$content_body = 3
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$content_sub_title = 2
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$content_body = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$content_sub_title = "Content Placeholder 10"
# List content
cfg[["reporting"]][["meta_pptx"]][["content"]][["layout"]]$list = "content_list"
cfg[["reporting"]][["meta_pptx"]][["content"]][["master"]]$list = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$list_body = 2
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$list_sub_title = 3
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$list_body = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$list_sub_title = "Content Placeholder 10"
# Two column slide options (with headers)
# Each of the larger placeholders have dimensions of:
# units = inches, height = 4.41, width = 4.65
# Two column list with headers
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$list_head = "two_content_header_list"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$list_head = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_sub_title = 1
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_left_title = 6
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_left = 5
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_right_title = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_right = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_left_title = "Text Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_right_title = "Text Placeholder 4"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_right = "Content Placeholder 3"
# Two column text with headers
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$text_head = "two_content_header_text"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$text_head = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_sub_title = 6
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_left_title = 2
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_left = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_right_title = 1
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_right = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_left_title = "Text Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_right_title = "Text Placeholder 4"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_right = "Content Placeholder 3"
# Each place holder has dimensions of:
# units = inches, height = 5.08, width = 4.65
# Two column lists (no headers)
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$list = "two_content_list"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$list = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_sub_title = 2
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_left = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_right = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_right = "Content Placeholder 3"
# Two column text (no headers)
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$text = "two_content_text"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$text = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_sub_title = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_left = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_right = 1
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_right = "Content Placeholder 3"
# MD format for tables
# Table_Labels is the footers and headers while Table is the defaults for the
# body of the table
cfg[["reporting"]][["meta_pptx"]][["md_def"]][["Table_Labels"]] = list(
color = "black",
font.size = 11,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_pptx"]][["md_def"]][["Table"]] = list(
color = "black",
font.size = 11,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
#--------------------------------------------------------------------
# default reporting options for Word
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERLEFT$location = "header"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERLEFT$content = ""
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERRIGHT$location = "header"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERRIGHT$content = ""
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERLEFT$location = "footer"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERLEFT$content = ""
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERRIGHT$location = "footer"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERRIGHT$content = ""
cfg[["reporting"]][["meta_docx"]][["styles"]]$Normal = "Normal"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Code = "Code"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Default = "Default"
cfg[["reporting"]][["meta_docx"]][["styles"]]$TOC = "TOC 1"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Heading_1 = "heading 1"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Heading_2 = "heading 2"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Heading_3 = "heading 3"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Table = "Table Grid"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Table_Caption = "table title"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Table_Caption_Location = "top"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Caption = "graphic title"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Caption_Location = "bottom"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Width = 6.0
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Height = 5.0
# Caption information:
cfg[["reporting"]][["meta_docx"]][["captions"]] =list(figure = list(pre_number ="Figure ",
post_number =": "),
table = list(pre_number ="Table ",
post_number =": "))
# Default formatting for markdown:
cfg[["reporting"]][["meta_docx"]][["md_def"]][["default"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
# Default formatting for markdown for each style:
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Normal"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Code"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Courier",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["TOC"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Courier",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Heading_1"]] = list(
color = "black",
font.size = 16,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Calibri (Headings)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Heading_2"]] = list(
color = "black",
font.size = 13,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Calibri (Headings)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Heading_3"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Calibri (Headings)",
vertical.align = "baseline",
shading.color = "transparent")
# MD format for tables
# Table_Labels is the footers and headers while Table is the defaults for the
# body of the table
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Table_Labels"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Table"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Table_Caption"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = TRUE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Figure"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Figure_Caption"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = TRUE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
#--------------------------------------------------------------------
# This last call is necessary to initialize analysis specific components to
# their default values. For example to populate covariates with the default
# values listed in the system file.
cfg = system_select_set(cfg, "default")
# Populating the NCA meta information with defaults
cfg[["options"]][["nca_meta"]] = system_nca_parameters_meta()
return(cfg);
}
system_prepare_inputs_<MODEL_PREFIX> = function(SIMINT_cfg, SIMINT_p, SIMINT_force_times){
# System parameters
<SYSTEM_PARAM>
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# This is an initialization function, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
SIMINT_cov_value = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]][["values"]][["values"]][1]
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# Static secondary parameters
<SS_PARAM>
# Making sure the SIMINT_force_times has some value
if(is.null(SIMINT_force_times)){
SIMINT_force_times = SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]][1]
}
# If the first compartment has dosing defined then we add the zeros to the
# vector where force_times are not already present in the bolus dosing times.
# If the first compartment does not have bolus defined then we created
# the data structure and add doses of 0 to at the force_times
if(is.null(SIMINT_cfg[["options"]][["inputs"]][["bolus"]])){
# if there is no bolus information specified we add a dummy bolus of zero
# into the first compartment at the first sample time
SIMINT_var = rep(x=names(SIMINT_cfg[["options"]][["mi"]][["states"]])[1], times=length(SIMINT_force_times))
SIMINT_time = SIMINT_force_times
SIMINT_value = rep(x=0, times=length(SIMINT_force_times))
SIMINT_method = rep(x='add', times=length(SIMINT_force_times))
}
else{
# If there are bolus values specified then we add all of
# those to the events list
SIMINT_var = c()
SIMINT_time = c()
SIMINT_value = c()
SIMINT_method = c()
# turning the time scale from a string
# into a numeric value:
SIMINT_time_scale = eval(parse(text=SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["scale"]]))
for(SIMINT_name in names(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["species"]])){
SIMINT_dose_scale = eval(parse(text=SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["species"]][[SIMINT_name]][["scale"]]))
SIMINT_var = c(SIMINT_var, rep(SIMINT_name,length(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["values"]])))
SIMINT_method = c(SIMINT_method, rep('add',length(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["values"]])))
SIMINT_time = c(SIMINT_time, SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["values"]]*SIMINT_time_scale)
SIMINT_value = c(SIMINT_value, SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["species"]][[SIMINT_name]][["values"]]*SIMINT_dose_scale)
}
# pulling out the times in force_times that were not in the bolus_times
# Then we add in empty boluses there to force them to update
SIMINT_force_times_add = setdiff(SIMINT_force_times, unique(SIMINT_time))
if(length(SIMINT_force_times_add) > 0){
SIMINT_var = c(SIMINT_var, rep(SIMINT_name,length(SIMINT_force_times_add)))
SIMINT_method = c(SIMINT_method, rep('add',length(SIMINT_force_times_add)))
SIMINT_time = c(SIMINT_time, SIMINT_force_times_add)
SIMINT_value = c(SIMINT_value, rep(0, length(SIMINT_force_times_add)))
}
}
# Making sure the time of the events is ordered
SIMINT_EO = order(SIMINT_time)
SIMINT_events = data.frame(
var = SIMINT_var[SIMINT_EO],
time = SIMINT_time[SIMINT_EO],
value = SIMINT_value[SIMINT_EO],
method = SIMINT_method[SIMINT_EO])
return(SIMINT_events)
}
system_IC_<MODEL_PREFIX> = function(SIMINT_cfg, SIMINT_p){
#
# Returns initial condition information based on information stored in the cfg
# variable and an parameter vector.
#
# Example usage:
# cfg = build_system()
# cfg = system_select_set(cfg, 'default')
# parameters = cfg$parameters$values
# IC = system_IC(cfg, parameters)
#
# System parameters
<SYSTEM_PARAM>
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# This is an initialization function, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
SIMINT_cov_value = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]][["values"]][["values"]][1]
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# Static secondary parameters
<SS_PARAM>
#
# Assigning initial conditions
#
# Looping through each state to see if there
# is an entry in cfg for the initial condition.
# If If there isnt well default to zero, if there
# is an entry we will evaluate that assignment:
for (SIMINT_sname in names(SIMINT_cfg[["options"]][["mi"]][["states"]])){
SIMINT_sname %in% names(SIMINT_cfg[["options"]][["initial_conditions"]])
if(!(SIMINT_sname %in% names(SIMINT_cfg[["options"]][["initial_conditions"]]))){
# Here there is no initial condition specified for this state
SIMINT_tmp_assignment = sprintf('SIMINT_%s_IC = 0.0', SIMINT_sname) }
else{
# Here the initial condition has been specified
SIMINT_tmp_assignment = sprintf('SIMINT_%s_IC = %s', SIMINT_sname, SIMINT_cfg[["options"]][["initial_conditions"]][[SIMINT_sname]]) }
eval(parse(text=SIMINT_tmp_assignment))
}
# Remapping state ICs into vector form
SIMINT_all_ICs = c(
<STATE_ICS_REMAP>)
return(SIMINT_all_ICs);
}
auto_run_simulation_titrate_<MODEL_PREFIX> <- function(SIMINT_p, SIMINT_cfg, SIMINT_dropfirst=TRUE){
#
# This runs titration or rule based simulations
#
# The following are defined locally within the environment
#
# Parameters and states
# SIMINT_p - vector of system parameters
# SIMINT_cfg - system configuration sent into the titration routine
# SIMINT_cfgtt - system configuration at the current titration event time
# SIMINT_ttimes - vector of titration times (in simulation units)
# SIMINT_tt_ts - list of time scales for the current titration
# SIMINT_history - data frame tracking the history of conditions that
# evaluated true with the following structure:
# tname - name of titration rule
# value - value of that rule
# simtime - simulation time when that rule/value were triggered
# timescale - time at the rule timescale when that rule/value were triggered
# Zeroing all of the inputs because these are expeted
# to be handled through titration below
SIMINT_cfg = system_zero_inputs(SIMINT_cfg)
SIMINT_som = list()
#
# Defining the system parameters locally
#
<SYSTEM_PARAM>
#
# Defining the covariates
#
# This is an initialization function, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
<COVARIATES_IC>
#
# Defining the secondary parameters locally
#
<SS_PARAM>
#
# Evaluating all of the input scales
#
SIMINT_scales = list()
# Bolus scales
if(!is.null(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["scale"]])){
eval(parse(text=paste(sprintf(' SIMINT_scales[["bolus"]] = %s', SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["scale"]]))))
}
# Infusion rate scales
for(SIMINT_rname in names(SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]])){
SIMINT_scales[["infusion_rates"]][[SIMINT_rname]] = eval(parse(text=paste(sprintf("%s", SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]][[SIMINT_rname]][["times"]][["scale"]]))))
}
#
# Identify all of the titration time points and creating an empty titration
# history vector. To do this we loop through all of the rules.
#
SIMINT_thist_blank = list()
SIMINT_ttimes = c()
for(SIMINT_tname in names(SIMINT_cfg[["titration"]][["rules"]])){
SIMINT_ttimes = c(SIMINT_ttimes, SIMINT_cfg[["titration"]][["rules"]][[SIMINT_tname]][["simtimes"]])
SIMINT_thist_blank[[SIMINT_tname]][["value"]] = -1
SIMINT_thist_blank[[SIMINT_tname]][["simtime"]] = -1
SIMINT_thist_blank[[SIMINT_tname]][["timescale"]] = -1
}
#
# This holds the entire titration history and is NULL until the first event
# is encountered
#
SIMINT_history = NULL
# Pulling out any duplicates that may occur
SIMINT_ttimes = sort(unique(SIMINT_ttimes))
# Trimming off titration times that are beyond the simulation output times
SIMINT_ttimes = SIMINT_ttimes[ SIMINT_ttimes < max(SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]])]
# now we have all of the titration times, next we calculate the initial
# conditions to start the first simulation
SIMINT_IC = system_IC_<MODEL_PREFIX>(SIMINT_cfg, SIMINT_p)
# Now we loop through each of the titration time points
for(SIMINT_ttidx in 1:length(SIMINT_ttimes)){
# Pulling out the current bolus time
SIMINT_ttime = SIMINT_ttimes[SIMINT_ttidx]
#
# Defining the time information for the current titration time. These are
# the current titration times for each of the defined timescales in the
# model
#
SIMINT_tt_ts = list()
for(SIMINT_tsname in names(SIMINT_cfg[["options"]][["time_scales"]])){
SIMINT_tt_ts[[SIMINT_tsname]] = SIMINT_cfg[["options"]][["time_scales"]][[SIMINT_tsname]]*SIMINT_ttime
}
# copying the cfg variable to use within the titration loop
SIMINT_cfgtt = SIMINT_cfg
# copying the titratino history variable to use within the titration loop
SIMINT_thist = SIMINT_thist_blank
#
# Defining the state values
#
for(SIMINT_sname in names(SIMINT_IC)){
eval(parse(text=paste(sprintf("%s = SIMINT_IC[[SIMINT_sname]]", SIMINT_sname))))
}
# JMH Apply titration rules twice
# (1) State assignments/resets
# (2) Other information
SIMINT_rule_types = c('state', 'other')
for(SIMINT_rule_type in SIMINT_rule_types){
# Looping through all of the rules
for(SIMINT_tname in names(SIMINT_cfgtt[["titration"]][["rules"]])){
# if any of the rules are active at the current titration time
# then we process those rules
SIMINT_tcond = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["simtimes"]] == SIMINT_ttime
if(any(SIMINT_tcond)){
# Collecting the information for the current titration rule being
# triggered
SIMINT_ti_times = list()
SIMINT_ti_times[["simtime"]] = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["simtimes"]][SIMINT_tcond]
SIMINT_ti_times[["tstime"]] = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["times"]][SIMINT_tcond]
SIMINT_ti_times[["timescale"]] = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["timescale"]]
# now looping through each condition for the current rule to see if
# there is a match
for(SIMINT_tcond_name in names(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]])){
#Evaluating the boolean expression
SIMINT_tcond_bool = eval(parse(text=paste(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["cond"]])))
if(SIMINT_tcond_bool){
# if the Boolean expression is true then we
# evaluate the action. To make sure that state actions occur
# first we look to see if the rule type is state and the state
# reassignment string is in the initial action.
if((SIMINT_rule_type == "state" &
grepl('SI_TT_STATE[', SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["action"]], fixed=TRUE)) |
(SIMINT_rule_type == "other" &
!grepl('SI_TT_STATE[', SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["action"]], fixed=TRUE))){
# Executing the action
eval(parse(text=paste(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["action_parsed"]])))
# Next we store the titration history
SIMINT_thist[[SIMINT_tname]][["value"]] = eval(parse(text=paste(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["value_parsed"]])))
SIMINT_thist[[SIMINT_tname]][["simtime"]] = SIMINT_ti_times[["simtime"]]
SIMINT_thist[[SIMINT_tname]][["timescale"]] = SIMINT_ti_times[["tstime"]]
#
# Collecting information for _all_ of the history
#
if(is.null(SIMINT_history)){
SIMINT_history = data.frame(tname = SIMINT_tname,
value = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["value"]],
simtime = SIMINT_ti_times[["simtime"]],
timescale = SIMINT_ti_times[["tstime"]], stringsAsFactors=FALSE)
}
else{
SIMINT_history =
rbind(SIMINT_history,
c(SIMINT_tname,
SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["value"]],
SIMINT_ti_times[["simtime"]],
SIMINT_ti_times[["tstime"]]))
}
}
}
}
}
}
}
#
# Setting the initial condition
#
SIMINT_cfgtt = system_set_option(cfg = SIMINT_cfgtt,
group = "simulation",
option = "initial_conditions",
value = SIMINT_IC)
# JMH defining the output times for this interval
# If we're before the last titration time we keep everything between that
# time and the current time
if(SIMINT_ttidx < length(SIMINT_ttimes)){
SIMINT_ottr_keep_idx = (SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]] >= SIMINT_ttimes[SIMINT_ttidx]) &
(SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]] <= SIMINT_ttimes[SIMINT_ttidx + 1])
}
else {
SIMINT_ottr_keep_idx = (SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]] >= SIMINT_ttimes[SIMINT_ttidx])
}
# Output times vector subset of the current titration times
SIMINT_ottr = SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]][SIMINT_ottr_keep_idx]
# Adding a point just before the last point so that when we add the results
# together before we will sample smoothly across titration points
SIMINT_pre = c()
if(SIMINT_ttidx < length(SIMINT_ttimes)){
SIMINT_pre = (max(SIMINT_ottr) - 1e-8*(max(SIMINT_ottr) - min(SIMINT_ottr))) }
# Making sure the titration time point is also included
SIMINT_ottr = c(SIMINT_ottr, SIMINT_ttimes[SIMINT_ttidx])
SIMINT_ottr = sort(unique(c(SIMINT_ottr, SIMINT_pre)))
# Setting the output times
SIMINT_cfgtt = system_set_option(SIMINT_cfgtt,
group = "simulation",
option = "output_times",
SIMINT_ottr)
# Simulating the system forward in time
SIMINT_somtt = run_simulation_ubiquity(SIMINT_parameters = SIMINT_p,
SIMINT_cfg = SIMINT_cfgtt,
SIMINT_dropfirst = SIMINT_dropfirst)
# adding the titration history information
# pulling out the number of observations
SIMINT_nobs = length(SIMINT_somtt[["simout"]][["time"]])
SIMINT_somtt[["titration"]] = data.frame(matrix(, nrow=SIMINT_nobs, ncol=0))
for(SIMINT_tname in names(SIMINT_thist)){
# Appending the value, simtime, and timescale to the som output
SIMINT_somtt[["titration"]][[sprintf('tt.%s.value', SIMINT_tname)]] = rep(times=SIMINT_nobs, SIMINT_thist[[SIMINT_tname]][["value"]])
SIMINT_somtt[["titration"]][[sprintf('tt.%s.simtime', SIMINT_tname)]] = rep(times=SIMINT_nobs, SIMINT_thist[[SIMINT_tname]][["simtime"]])
SIMINT_somtt[["titration"]][[sprintf('tt.%s.timescale',SIMINT_tname)]] = rep(times=SIMINT_nobs, SIMINT_thist[[SIMINT_tname]][["timescale"]])
}
# Updating the initial condition to the last observation of som
SIMINT_IC = as.numeric(SIMINT_somtt[["simout"]][length(SIMINT_somtt[["simout"]][,1]), names(SIMINT_cfg[["options"]][["mi"]][["states"]])])
names(SIMINT_IC) = names(SIMINT_cfg[["options"]][["mi"]][["states"]])
# Stripping the last observation off of som
if(SIMINT_ttidx < length(SIMINT_ttimes)){
SIMINT_somtt[["simout"]] = SIMINT_somtt[["simout"]][1:(SIMINT_nobs - 1),]
SIMINT_somtt[["titration"]] = SIMINT_somtt[["titration"]][1:(SIMINT_nobs - 1),]
}
#Appending the simulation results to the master set of results
if(SIMINT_ttidx == 1){
SIMINT_som = SIMINT_somtt }
else{
SIMINT_som[["simout"]] = rbind(SIMINT_som[["simout"]], SIMINT_somtt[["simout"]])
SIMINT_som[["titration"]] = rbind(SIMINT_som[["titration"]], SIMINT_somtt[["titration"]])
}
}
SIMINT_som[["titration_history"]] = SIMINT_history
# pulls out the last row of simout
# som$simout[length(som$simout[,1]),]
return(SIMINT_som)
}
system_DYDT_<MODEL_PREFIX> = function(SIMINT_TIME,SIMINT_x,SIMINT_cfg){
#
# Evalutates the derivatives of the ODEs at time SIMINT_TIME
#
SIMINT_p = SIMINT_cfg[["parameters"]][["values"]]
# System parameters
<SYSTEM_PARAM>
for(SIMINT_rate_name in names(SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]])){
# Looping through each infusion rate and creating a variable in the current
# function with the rate at the value for the current time
# plucking out the rate name
SIMINT_my_rate = SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]][[SIMINT_rate_name]]
# scaling the times
eval(parse(text=sprintf('SIMINT_my_rate[["times"]][["values"]] = SIMINT_my_rate[["times"]][["values"]]*%s',SIMINT_my_rate[["times"]][["scale"]])))
# getting the covariate value at the given time
SIMINT_rate_value =
system_evaluate_input_<MODEL_PREFIX>(SIMINT_my_rate[["times"]][["values"]],
SIMINT_my_rate[["levels"]][["values"]],
SIMINT_TIME,
'step')
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_rate_value*%s",SIMINT_rate_name, SIMINT_my_rate[["levels"]][["scale"]]))))
}
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name at the value for the current time
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# getting the covariate value at the given time
SIMINT_cov_value =
system_evaluate_input_<MODEL_PREFIX>(SIMINT_my_cov[["times"]][["values"]],
SIMINT_my_cov[["values"]][["values"]],
SIMINT_TIME,
SIMINT_my_cov[["cv_interp"]])
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# States
<STATES>
# Static secondary parameters
<SS_PARAM>
# Dynamic secondary parameters
<DS_PARAM>
# ODEs
<ODES>
# ODE
SIMINT_DYDT = c(
<ODES_REMAP>)
#return(SIMINT_DYDT)
list(dy=SIMINT_DYDT,global=c())
}
system_map_output_<MODEL_PREFIX> = function(SIMINT_cfg, SIMINT_simout, SIMINT_p, SIMINT_eventdata){
# Pulling out the time vector
SIMINT_tts = SIMINT_simout[,'time']
# Creating the matrix to store the simout
SIMINT_all_outputs = c(names(SIMINT_cfg[["options"]][["mi"]][["states"]]), names(SIMINT_cfg[["options"]][["mi"]][["odes"]]))
SIMINT_simoutmat = matrix(data=NA, nrow=length(SIMINT_tts), ncol=(length(SIMINT_all_outputs) +1) )
colnames(SIMINT_simoutmat) = eval(parse(text= sprintf("c('time', '%s')", paste(SIMINT_all_outputs, collapse="', '"))))
# System parameters
<SYSTEM_PARAM>
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name (evaluated at the first instance)
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# This is an initialization step, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
SIMINT_cov_value = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]][["values"]][["values"]][1]
# creating the named value for the covariate
# at the current time
# This is used when calculating secondary parameters:
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
# This will be stored in the output data frame
eval(parse(text=paste(sprintf("SIMINT_CVIC_%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# Static secondary parameters
<SS_PARAM>
for (SIMINT_tidx in seq(1,length(SIMINT_tts))){
SIMINT_TIME = SIMINT_tts[SIMINT_tidx]
<TIME_SCALES>
# Creating the states here at a given time
# (above a vector was created)
for (SIMINT_sname in names(SIMINT_cfg[["options"]][["mi"]][["states"]])){
SIMINT_tmp_assignment = sprintf('%s = SIMINT_simout[[SIMINT_tidx, SIMINT_sname]]', SIMINT_sname) #JMH modify
eval(parse(text=SIMINT_tmp_assignment))
}
for(SIMINT_rate_name in names(SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]])){
# Looping through each infusion rate and creating a variable in the current
# function with the rate at the value for the current time
# plucking out the rate name
SIMINT_my_rate = SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]][[SIMINT_rate_name]]
# scaling the times
eval(parse(text=sprintf('SIMINT_my_rate[["times"]][["values"]] = SIMINT_my_rate[["times"]][["values"]]*%s',SIMINT_my_rate[["times"]][["scale"]])))
# getting the covariate value at the given time
SIMINT_rate_value = system_evaluate_input_<MODEL_PREFIX>(
SIMINT_my_rate[["times"]][["values"]],
SIMINT_my_rate[["levels"]][["values"]],
SIMINT_TIME,
'step')
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_rate_value*%s",SIMINT_rate_name, SIMINT_my_rate[["levels"]][["scale"]]))))
}
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name at the value for the current time
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# getting the covariate value at the given time
SIMINT_cov_value = system_evaluate_input_<MODEL_PREFIX>(
SIMINT_my_cov[["times"]][["values"]],
SIMINT_my_cov[["values"]][["values"]],
SIMINT_TIME,
SIMINT_my_cov[["cv_interp"]])
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
<DS_PARAM>
# Outputs
<OUTPUTS>
# With all of the variables defined we add a row to the simout matrix
SIMINT_simoutmat[SIMINT_tidx,] = eval(parse(text=sprintf("c(SIMINT_TIME, %s)", paste(SIMINT_all_outputs , collapse=", "))))
}
return(SIMINT_simoutmat) }
system_evaluate_input_<MODEL_PREFIX> = function(tvals, lvals, etime, type){
#
# system_evaluate_input --- used to evaluate infusion rates and
# covariates at etime
#
# tvals - time values where time-series is defined
# lvals - corresponding values where the of the time series
# etime - time where the time-series is to be evaluated
# type - type of timeseries either: 'linear' or 'step'
#
# initializing the return value
value = -1
if(type == 'step'){
if(length(tvals) == 1){
# if there is only one element in tvals
# then we just take that value
value = tail(lvals, 1)
}
else if(etime > max(tvals)){
# the eval time is beyond the range of
# specified times then we carry the last
# one forward
value = tail(lvals, 1)
}
else if(etime < min(tvals)){
# the eval time is before the range of
# specified times then we assign it to
# the first value
value = lvals[1];
}
else{
# this should return the portion of the
# lvals vector that is less than
# the evaluation time (etime):
#
# lvals[tvals <= etime]
# and tail should pop off the last value
value = tail(lvals[tvals <= etime], 1)
}
}
else if(type == 'linear'){
if(length(tvals) == 1){
# if there is only 1 value then there is no linear interpolation :)
value = lvals
}
else{
#linearly interpolating, values beyond boundary
# will take on the values at the boundary
linear_interp = approx(tvals, lvals, etime, method="linear", rule=2, , , n=2)
value = linear_interp$y
}
}
return(value)
}
#-------------------------------------------------------------------------
# Looping through each output to add the error
add_observation_errors_<MODEL_PREFIX> = function(simout, parameters, cfg){
for(output in names(cfg[["ve"]])){
simout = output_add_error_<MODEL_PREFIX>(
SIMINT_simout = simout, # simulation output without error
SIMINT_output = output, # output
SIMINT_em = cfg[["ve"]][[output]],# error model
SIMINT_parameters = parameters, # current parameter values
SIMINT_cfg = cfg)
}
return(simout)}
#-------------------------------------------------------------------------
output_add_error_<MODEL_PREFIX> = function(SIMINT_simout, SIMINT_output, SIMINT_em, SIMINT_parameters, SIMINT_cfg){
# Defining the time
SIMINT_TIME = SIMINT_simout[,'time']
# Defining the pred values locally
PRED = SIMINT_simout[, SIMINT_output]
# Pulling the variance parameter names
SIMINT_VP_NAMES = as.vector(SIMINT_cfg[["parameters"]][["matrix"]][["name"]][SIMINT_cfg[["parameters"]][["matrix"]][["ptype"]] == 'variance'])
# Evaluating the variance parameters locally
for(SIMINT_VP_NAME in SIMINT_VP_NAMES){
eval(parse(text=sprintf('%s = as.numeric(SIMINT_parameters["%s"])', SIMINT_VP_NAME, SIMINT_VP_NAME)))
}
# calculating the error model value
eval(parse(text=sprintf("SIMINT_em_VARIANCE = %s", SIMINT_em)))
SIMINT_em_MEAN = rep(0,length(PRED));
SIMINT_ERR = rnorm(PRED, SIMINT_em_MEAN, sqrt(SIMINT_em_VARIANCE))
# adding the error to the prediction and storing it in SIMINT_simout
SIMINT_simout = eval(parse(text=sprintf('cbind(SIMINT_simout, SIOE_%s=c(PRED+SIMINT_ERR))', SIMINT_output)))
return(SIMINT_simout)}
john-harrold/ubiquity documentation built on March 13, 2024, 2:58 a.m.
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<COMMENTS>
system_fetch_cfg_<MODEL_PREFIX> = function(){
#
# This function returns a list that stores all of the information about the
# system including parameter values, system indices used, initial condition
# assignments, etc.
#
#Creating the cfg variable
cfg = list();
c_libfile_base = "<MODEL_PREFIX>"
# Initializing the top level elements of cfg
cfg[["options"]] = list(mi = list(),
misc = list(),
time_scales = list(),
inputs = list(),
simulation_options = list(),
stochastic = list(),
logging = list())
cfg[["parameters"]] = list(sets = list(),
matrix = NULL,
current_set = NULL,
values = NULL)
cfg[["titration"]] = list(titrate = NULL,
times = c(),
rules = list())
cfg[["iiv"]] = list(sets = list(),
current_set = NULL,
iivs = list(),
parameters = list(),
values = NULL)
cfg[["estimation"]] = list(options = list(),
parameters = list(),
objective_type = list(),
mi = list())
cfg[["reporting"]] = list(meta_pptx = list(),
meta_docx = list(),
enabled = FALSE)
cfg[["reporting"]][["meta_pptx"]] =
list(title = list(),
section = list(),
content = list(),
two_col = list(),
md_def = list())
cfg[["reporting"]][["meta_docx"]] =
list(ph_content = list(),
styles = list(),
captions = list(),
md_def = list())
cfg[["ve"]] = list()
# JMH initialize the following:
# cfg[["data"]]
# cfg[["cohorts"]]
# storing the location of the temporary directory and the distribution type
cfg[["options"]][["misc"]][["temp_directory"]] = '<TEMP_DIRECTORY>'
cfg[["options"]][["misc"]][["distribution"]] = '<DISTRIBUTION>'
cfg[["options"]][["misc"]][["system_file"]] = '<SYSTEM_FILE>'
# storing the base file name of the compiled C file
cfg[["options"]][["misc"]][["c_libfile_base"]] = c_libfile_base
# Finding the location of the template directory
if(cfg[["options"]][["misc"]][["distribution"]] == "stand alone"){
cfg[["options"]][["misc"]][["templates"]] = file.path(getwd(), "library", "templates")
} else {
package_dir = system.file("", package="ubiquity")
cfg[["options"]][["misc"]][["templates"]] = file.path(package_dir, "ubinc", "templates")
}
# By default we will indicate that we're running at the
# scripting level. This will be altered at the Shiny App level
cfg[["options"]][["misc"]][["operating_environment"]] = "script"
# defaulting to integrating with r file
#cfg[["options"]][["simulation_options"]][["integrate_with"]] = "r-file"
# default simulation options
cfg[["options"]][["simulation_options"]] =
list(parallel = "No", # No parallelization
compute_cores = 1,
integrate_with = "r-file", # Integrating with R file
initial_conditions = NA, # No specified initial conditions
solver_opts = list())
# If the library has been loaded we switch to C
if(is.null(getLoadedDLLs()[[c_libfile_base]]) == FALSE){
if(getLoadedDLLs()[[c_libfile_base]][["dynamicLookup"]] == TRUE){
cfg[["options"]][["simulation_options"]][["integrate_with"]] = "c-file"
}
}
# defaulting to no specified initial condition
#cfg[["options"]][["simulation_options"]][["initial_conditions"]] = NA
# System parameter information
<FETCH_SYS_PARAMS>
# Static secondary parameters
<FETCH_SYS_SSP>
# Dynamic secondary parameters
<FETCH_SYS_DSP>
# Indices mapping state, parameter, etc. names
# to their index in the different vectors
<FETCH_SYS_INDICES>
<FETCH_SYS_INDICES_ODE_OUTPUT>
# Parameter Sets
<FETCH_SYS_PSETS>
# Interindiviudal Varability Information
<FETCH_SYS_IIV>
# Variance Equations
<FETCH_SYS_VE>
<FETCH_SYS_INFUSIONS>
<FETCH_SYS_COVARIATES>
# identifying that the current set is the default
cfg[["parameters"]][["current_set"]] = "default";
# Nonzero initial conditions
<FETCH_SYS_IC>
# timescale information
<FETCH_SYS_TS>
# data set
<FETCH_SYS_DATA>
# bolus inputs
<FETCH_SYS_BOLUS>
# misc options
<FETCH_SYS_MISC>
# Defaulting output times to gui output times
cfg[["options"]][["simulation_options"]][["output_times"]] =
eval(parse(text=cfg[["options"]][["misc"]][["output_times"]]))
<FETCH_SYS_OPTIONS>
# titration options
cfg[["titration"]][["titrate"]] = FALSE
cfg[["titration"]][["times"]] = c() # vector of times where titration can occur
cfg[["titration"]][["rules"]] = list() # titration rules
# default stochastic options
cfg[["options"]][["stochastic"]] =
list(nsub = 100,
seed = 8675309,
ci = 95,
ponly = FALSE,
sub_file = NULL,
sub_file_sample = "with replacement")
# default logging options
cfg[["options"]][["logging"]] =
list(enabled = TRUE,
file = file.path(cfg[["options"]][["misc"]][["temp_directory"]],"ubiquity_log.txt"),
timestamp = TRUE ,
ts_str = "%Y-%m-%d %H:%M:%S",
debug = FALSE,
verbose = TRUE)
# default estimation options
cfg[["estimation"]][["options"]] =
list(observation_function = "system_od_general",
optimizer = "optim",
method = "Nelder-Mead",
control = list(trace=TRUE, REPORT=10))
#--------------------------------------------------------------------
# default reporting options for powerpoint
#
# Set sub_title fields to NULL if they do not exist in the template
#
# this is the information the title slide
cfg[["reporting"]][["meta_pptx"]][["title"]][["layout"]]$general = "title_slide"
cfg[["reporting"]][["meta_pptx"]][["title"]][["master"]]$general = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["title"]][["type"]]$title = 'ctrTitle'
cfg[["reporting"]][["meta_pptx"]][["title"]][["type"]]$sub_title = 'subTitle'
cfg[["reporting"]][["meta_pptx"]][["title"]][["indices"]]$title = 3
cfg[["reporting"]][["meta_pptx"]][["title"]][["indices"]]$sub_title = 4
cfg[["reporting"]][["meta_pptx"]][["title"]][["ph_labels"]]$title = "Title 1"
cfg[["reporting"]][["meta_pptx"]][["title"]][["ph_labels"]]$sub_title = "Subtitle 2"
# this is the information the section title slide
cfg[["reporting"]][["meta_pptx"]][["section"]][["layout"]]$general = "section_slide"
cfg[["reporting"]][["meta_pptx"]][["section"]][["master"]]$general = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["section"]][["type"]]$title = 'ctrTitle'
cfg[["reporting"]][["meta_pptx"]][["section"]][["type"]]$sub_title = 'subTitle'
cfg[["reporting"]][["meta_pptx"]][["section"]][["indices"]]$title = 3
cfg[["reporting"]][["meta_pptx"]][["section"]][["indices"]]$sub_title = 4
cfg[["reporting"]][["meta_pptx"]][["section"]][["ph_labels"]]$title = "Title 1"
cfg[["reporting"]][["meta_pptx"]][["section"]][["ph_labels"]]$sub_title = "Subtitle 2"
# These contain the mapping information for content in the template
# The main dimensions are:
# units = inches, height = 5.0, width = 9.5
# Text content
cfg[["reporting"]][["meta_pptx"]][["content"]][["layout"]]$general = "content_text"
cfg[["reporting"]][["meta_pptx"]][["content"]][["master"]]$general = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$content_body = 3
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$content_sub_title = 2
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$content_body = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$content_sub_title = "Content Placeholder 10"
# List content
cfg[["reporting"]][["meta_pptx"]][["content"]][["layout"]]$list = "content_list"
cfg[["reporting"]][["meta_pptx"]][["content"]][["master"]]$list = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$list_body = 2
cfg[["reporting"]][["meta_pptx"]][["content"]][["indices"]]$list_sub_title = 3
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$list_body = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["content"]][["ph_labels"]]$list_sub_title = "Content Placeholder 10"
# Two column slide options (with headers)
# Each of the larger placeholders have dimensions of:
# units = inches, height = 4.41, width = 4.65
# Two column list with headers
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$list_head = "two_content_header_list"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$list_head = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_sub_title = 1
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_left_title = 6
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_left = 5
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_right_title = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_head_right = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_left_title = "Text Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_right_title = "Text Placeholder 4"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_head_right = "Content Placeholder 3"
# Two column text with headers
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$text_head = "two_content_header_text"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$text_head = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_sub_title = 6
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_left_title = 2
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_left = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_right_title = 1
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_head_right = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_left_title = "Text Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_right_title = "Text Placeholder 4"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_head_right = "Content Placeholder 3"
# Each place holder has dimensions of:
# units = inches, height = 5.08, width = 4.65
# Two column lists (no headers)
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$list = "two_content_list"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$list = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_sub_title = 2
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_left = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$list_right = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$list_right = "Content Placeholder 3"
# Two column text (no headers)
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["layout"]]$text = "two_content_text"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["master"]]$text = "Office Theme"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_sub_title = 4
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_left = 3
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["indices"]]$text_right = 1
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_sub_title = "Content Placeholder 10"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_left = "Content Placeholder 2"
cfg[["reporting"]][["meta_pptx"]][["two_col"]][["ph_labels"]]$text_right = "Content Placeholder 3"
# MD format for tables
# Table_Labels is the footers and headers while Table is the defaults for the
# body of the table
cfg[["reporting"]][["meta_pptx"]][["md_def"]][["Table_Labels"]] = list(
color = "black",
font.size = 11,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_pptx"]][["md_def"]][["Table"]] = list(
color = "black",
font.size = 11,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
#--------------------------------------------------------------------
# default reporting options for Word
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERLEFT$location = "header"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERLEFT$content = ""
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERRIGHT$location = "header"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$HEADERRIGHT$content = ""
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERLEFT$location = "footer"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERLEFT$content = ""
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERRIGHT$location = "footer"
cfg[["reporting"]][["meta_docx"]][["ph_content"]]$FOOTERRIGHT$content = ""
cfg[["reporting"]][["meta_docx"]][["styles"]]$Normal = "Normal"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Code = "Code"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Default = "Default"
cfg[["reporting"]][["meta_docx"]][["styles"]]$TOC = "TOC 1"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Heading_1 = "heading 1"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Heading_2 = "heading 2"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Heading_3 = "heading 3"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Table = "Table Grid"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Table_Caption = "table title"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Table_Caption_Location = "top"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Caption = "graphic title"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Caption_Location = "bottom"
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Width = 6.0
cfg[["reporting"]][["meta_docx"]][["styles"]]$Figure_Height = 5.0
# Caption information:
cfg[["reporting"]][["meta_docx"]][["captions"]] =list(figure = list(pre_number ="Figure ",
post_number =": "),
table = list(pre_number ="Table ",
post_number =": "))
# Default formatting for markdown:
cfg[["reporting"]][["meta_docx"]][["md_def"]][["default"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
# Default formatting for markdown for each style:
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Normal"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Code"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Courier",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["TOC"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Courier",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Heading_1"]] = list(
color = "black",
font.size = 16,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Calibri (Headings)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Heading_2"]] = list(
color = "black",
font.size = 13,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Calibri (Headings)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Heading_3"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Calibri (Headings)",
vertical.align = "baseline",
shading.color = "transparent")
# MD format for tables
# Table_Labels is the footers and headers while Table is the defaults for the
# body of the table
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Table_Labels"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Table"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Helvetica",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Table_Caption"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = TRUE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Figure"]] = list(
color = "black",
font.size = 12,
bold = FALSE,
italic = FALSE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
cfg[["reporting"]][["meta_docx"]][["md_def"]][["Figure_Caption"]] = list(
color = "black",
font.size = 12,
bold = TRUE,
italic = TRUE,
underlined = FALSE,
font.family = "Cambria (Body)",
vertical.align = "baseline",
shading.color = "transparent")
#--------------------------------------------------------------------
# This last call is necessary to initialize analysis specific components to
# their default values. For example to populate covariates with the default
# values listed in the system file.
cfg = system_select_set(cfg, "default")
# Populating the NCA meta information with defaults
cfg[["options"]][["nca_meta"]] = system_nca_parameters_meta()
return(cfg);
}
system_prepare_inputs_<MODEL_PREFIX> = function(SIMINT_cfg, SIMINT_p, SIMINT_force_times){
# System parameters
<SYSTEM_PARAM>
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# This is an initialization function, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
SIMINT_cov_value = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]][["values"]][["values"]][1]
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# Static secondary parameters
<SS_PARAM>
# Making sure the SIMINT_force_times has some value
if(is.null(SIMINT_force_times)){
SIMINT_force_times = SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]][1]
}
# If the first compartment has dosing defined then we add the zeros to the
# vector where force_times are not already present in the bolus dosing times.
# If the first compartment does not have bolus defined then we created
# the data structure and add doses of 0 to at the force_times
if(is.null(SIMINT_cfg[["options"]][["inputs"]][["bolus"]])){
# if there is no bolus information specified we add a dummy bolus of zero
# into the first compartment at the first sample time
SIMINT_var = rep(x=names(SIMINT_cfg[["options"]][["mi"]][["states"]])[1], times=length(SIMINT_force_times))
SIMINT_time = SIMINT_force_times
SIMINT_value = rep(x=0, times=length(SIMINT_force_times))
SIMINT_method = rep(x='add', times=length(SIMINT_force_times))
}
else{
# If there are bolus values specified then we add all of
# those to the events list
SIMINT_var = c()
SIMINT_time = c()
SIMINT_value = c()
SIMINT_method = c()
# turning the time scale from a string
# into a numeric value:
SIMINT_time_scale = eval(parse(text=SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["scale"]]))
for(SIMINT_name in names(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["species"]])){
SIMINT_dose_scale = eval(parse(text=SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["species"]][[SIMINT_name]][["scale"]]))
SIMINT_var = c(SIMINT_var, rep(SIMINT_name,length(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["values"]])))
SIMINT_method = c(SIMINT_method, rep('add',length(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["values"]])))
SIMINT_time = c(SIMINT_time, SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["values"]]*SIMINT_time_scale)
SIMINT_value = c(SIMINT_value, SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["species"]][[SIMINT_name]][["values"]]*SIMINT_dose_scale)
}
# pulling out the times in force_times that were not in the bolus_times
# Then we add in empty boluses there to force them to update
SIMINT_force_times_add = setdiff(SIMINT_force_times, unique(SIMINT_time))
if(length(SIMINT_force_times_add) > 0){
SIMINT_var = c(SIMINT_var, rep(SIMINT_name,length(SIMINT_force_times_add)))
SIMINT_method = c(SIMINT_method, rep('add',length(SIMINT_force_times_add)))
SIMINT_time = c(SIMINT_time, SIMINT_force_times_add)
SIMINT_value = c(SIMINT_value, rep(0, length(SIMINT_force_times_add)))
}
}
# Making sure the time of the events is ordered
SIMINT_EO = order(SIMINT_time)
SIMINT_events = data.frame(
var = SIMINT_var[SIMINT_EO],
time = SIMINT_time[SIMINT_EO],
value = SIMINT_value[SIMINT_EO],
method = SIMINT_method[SIMINT_EO])
return(SIMINT_events)
}
system_IC_<MODEL_PREFIX> = function(SIMINT_cfg, SIMINT_p){
#
# Returns initial condition information based on information stored in the cfg
# variable and an parameter vector.
#
# Example usage:
# cfg = build_system()
# cfg = system_select_set(cfg, 'default')
# parameters = cfg$parameters$values
# IC = system_IC(cfg, parameters)
#
# System parameters
<SYSTEM_PARAM>
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# This is an initialization function, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
SIMINT_cov_value = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]][["values"]][["values"]][1]
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# Static secondary parameters
<SS_PARAM>
#
# Assigning initial conditions
#
# Looping through each state to see if there
# is an entry in cfg for the initial condition.
# If If there isnt well default to zero, if there
# is an entry we will evaluate that assignment:
for (SIMINT_sname in names(SIMINT_cfg[["options"]][["mi"]][["states"]])){
SIMINT_sname %in% names(SIMINT_cfg[["options"]][["initial_conditions"]])
if(!(SIMINT_sname %in% names(SIMINT_cfg[["options"]][["initial_conditions"]]))){
# Here there is no initial condition specified for this state
SIMINT_tmp_assignment = sprintf('SIMINT_%s_IC = 0.0', SIMINT_sname) }
else{
# Here the initial condition has been specified
SIMINT_tmp_assignment = sprintf('SIMINT_%s_IC = %s', SIMINT_sname, SIMINT_cfg[["options"]][["initial_conditions"]][[SIMINT_sname]]) }
eval(parse(text=SIMINT_tmp_assignment))
}
# Remapping state ICs into vector form
SIMINT_all_ICs = c(
<STATE_ICS_REMAP>)
return(SIMINT_all_ICs);
}
auto_run_simulation_titrate_<MODEL_PREFIX> <- function(SIMINT_p, SIMINT_cfg, SIMINT_dropfirst=TRUE){
#
# This runs titration or rule based simulations
#
# The following are defined locally within the environment
#
# Parameters and states
# SIMINT_p - vector of system parameters
# SIMINT_cfg - system configuration sent into the titration routine
# SIMINT_cfgtt - system configuration at the current titration event time
# SIMINT_ttimes - vector of titration times (in simulation units)
# SIMINT_tt_ts - list of time scales for the current titration
# SIMINT_history - data frame tracking the history of conditions that
# evaluated true with the following structure:
# tname - name of titration rule
# value - value of that rule
# simtime - simulation time when that rule/value were triggered
# timescale - time at the rule timescale when that rule/value were triggered
# Zeroing all of the inputs because these are expeted
# to be handled through titration below
SIMINT_cfg = system_zero_inputs(SIMINT_cfg)
SIMINT_som = list()
#
# Defining the system parameters locally
#
<SYSTEM_PARAM>
#
# Defining the covariates
#
# This is an initialization function, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
<COVARIATES_IC>
#
# Defining the secondary parameters locally
#
<SS_PARAM>
#
# Evaluating all of the input scales
#
SIMINT_scales = list()
# Bolus scales
if(!is.null(SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["scale"]])){
eval(parse(text=paste(sprintf(' SIMINT_scales[["bolus"]] = %s', SIMINT_cfg[["options"]][["inputs"]][["bolus"]][["times"]][["scale"]]))))
}
# Infusion rate scales
for(SIMINT_rname in names(SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]])){
SIMINT_scales[["infusion_rates"]][[SIMINT_rname]] = eval(parse(text=paste(sprintf("%s", SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]][[SIMINT_rname]][["times"]][["scale"]]))))
}
#
# Identify all of the titration time points and creating an empty titration
# history vector. To do this we loop through all of the rules.
#
SIMINT_thist_blank = list()
SIMINT_ttimes = c()
for(SIMINT_tname in names(SIMINT_cfg[["titration"]][["rules"]])){
SIMINT_ttimes = c(SIMINT_ttimes, SIMINT_cfg[["titration"]][["rules"]][[SIMINT_tname]][["simtimes"]])
SIMINT_thist_blank[[SIMINT_tname]][["value"]] = -1
SIMINT_thist_blank[[SIMINT_tname]][["simtime"]] = -1
SIMINT_thist_blank[[SIMINT_tname]][["timescale"]] = -1
}
#
# This holds the entire titration history and is NULL until the first event
# is encountered
#
SIMINT_history = NULL
# Pulling out any duplicates that may occur
SIMINT_ttimes = sort(unique(SIMINT_ttimes))
# Trimming off titration times that are beyond the simulation output times
SIMINT_ttimes = SIMINT_ttimes[ SIMINT_ttimes < max(SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]])]
# now we have all of the titration times, next we calculate the initial
# conditions to start the first simulation
SIMINT_IC = system_IC_<MODEL_PREFIX>(SIMINT_cfg, SIMINT_p)
# Now we loop through each of the titration time points
for(SIMINT_ttidx in 1:length(SIMINT_ttimes)){
# Pulling out the current bolus time
SIMINT_ttime = SIMINT_ttimes[SIMINT_ttidx]
#
# Defining the time information for the current titration time. These are
# the current titration times for each of the defined timescales in the
# model
#
SIMINT_tt_ts = list()
for(SIMINT_tsname in names(SIMINT_cfg[["options"]][["time_scales"]])){
SIMINT_tt_ts[[SIMINT_tsname]] = SIMINT_cfg[["options"]][["time_scales"]][[SIMINT_tsname]]*SIMINT_ttime
}
# copying the cfg variable to use within the titration loop
SIMINT_cfgtt = SIMINT_cfg
# copying the titratino history variable to use within the titration loop
SIMINT_thist = SIMINT_thist_blank
#
# Defining the state values
#
for(SIMINT_sname in names(SIMINT_IC)){
eval(parse(text=paste(sprintf("%s = SIMINT_IC[[SIMINT_sname]]", SIMINT_sname))))
}
# JMH Apply titration rules twice
# (1) State assignments/resets
# (2) Other information
SIMINT_rule_types = c('state', 'other')
for(SIMINT_rule_type in SIMINT_rule_types){
# Looping through all of the rules
for(SIMINT_tname in names(SIMINT_cfgtt[["titration"]][["rules"]])){
# if any of the rules are active at the current titration time
# then we process those rules
SIMINT_tcond = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["simtimes"]] == SIMINT_ttime
if(any(SIMINT_tcond)){
# Collecting the information for the current titration rule being
# triggered
SIMINT_ti_times = list()
SIMINT_ti_times[["simtime"]] = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["simtimes"]][SIMINT_tcond]
SIMINT_ti_times[["tstime"]] = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["times"]][SIMINT_tcond]
SIMINT_ti_times[["timescale"]] = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["timescale"]]
# now looping through each condition for the current rule to see if
# there is a match
for(SIMINT_tcond_name in names(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]])){
#Evaluating the boolean expression
SIMINT_tcond_bool = eval(parse(text=paste(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["cond"]])))
if(SIMINT_tcond_bool){
# if the Boolean expression is true then we
# evaluate the action. To make sure that state actions occur
# first we look to see if the rule type is state and the state
# reassignment string is in the initial action.
if((SIMINT_rule_type == "state" &
grepl('SI_TT_STATE[', SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["action"]], fixed=TRUE)) |
(SIMINT_rule_type == "other" &
!grepl('SI_TT_STATE[', SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["action"]], fixed=TRUE))){
# Executing the action
eval(parse(text=paste(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["action_parsed"]])))
# Next we store the titration history
SIMINT_thist[[SIMINT_tname]][["value"]] = eval(parse(text=paste(SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["value_parsed"]])))
SIMINT_thist[[SIMINT_tname]][["simtime"]] = SIMINT_ti_times[["simtime"]]
SIMINT_thist[[SIMINT_tname]][["timescale"]] = SIMINT_ti_times[["tstime"]]
#
# Collecting information for _all_ of the history
#
if(is.null(SIMINT_history)){
SIMINT_history = data.frame(tname = SIMINT_tname,
value = SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["value"]],
simtime = SIMINT_ti_times[["simtime"]],
timescale = SIMINT_ti_times[["tstime"]], stringsAsFactors=FALSE)
}
else{
SIMINT_history =
rbind(SIMINT_history,
c(SIMINT_tname,
SIMINT_cfgtt[["titration"]][["rules"]][[SIMINT_tname]][["conditions"]][[SIMINT_tcond_name]][["value"]],
SIMINT_ti_times[["simtime"]],
SIMINT_ti_times[["tstime"]]))
}
}
}
}
}
}
}
#
# Setting the initial condition
#
SIMINT_cfgtt = system_set_option(cfg = SIMINT_cfgtt,
group = "simulation",
option = "initial_conditions",
value = SIMINT_IC)
# JMH defining the output times for this interval
# If we're before the last titration time we keep everything between that
# time and the current time
if(SIMINT_ttidx < length(SIMINT_ttimes)){
SIMINT_ottr_keep_idx = (SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]] >= SIMINT_ttimes[SIMINT_ttidx]) &
(SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]] <= SIMINT_ttimes[SIMINT_ttidx + 1])
}
else {
SIMINT_ottr_keep_idx = (SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]] >= SIMINT_ttimes[SIMINT_ttidx])
}
# Output times vector subset of the current titration times
SIMINT_ottr = SIMINT_cfg[["options"]][["simulation_options"]][["output_times"]][SIMINT_ottr_keep_idx]
# Adding a point just before the last point so that when we add the results
# together before we will sample smoothly across titration points
SIMINT_pre = c()
if(SIMINT_ttidx < length(SIMINT_ttimes)){
SIMINT_pre = (max(SIMINT_ottr) - 1e-8*(max(SIMINT_ottr) - min(SIMINT_ottr))) }
# Making sure the titration time point is also included
SIMINT_ottr = c(SIMINT_ottr, SIMINT_ttimes[SIMINT_ttidx])
SIMINT_ottr = sort(unique(c(SIMINT_ottr, SIMINT_pre)))
# Setting the output times
SIMINT_cfgtt = system_set_option(SIMINT_cfgtt,
group = "simulation",
option = "output_times",
SIMINT_ottr)
# Simulating the system forward in time
SIMINT_somtt = run_simulation_ubiquity(SIMINT_parameters = SIMINT_p,
SIMINT_cfg = SIMINT_cfgtt,
SIMINT_dropfirst = SIMINT_dropfirst)
# adding the titration history information
# pulling out the number of observations
SIMINT_nobs = length(SIMINT_somtt[["simout"]][["time"]])
SIMINT_somtt[["titration"]] = data.frame(matrix(, nrow=SIMINT_nobs, ncol=0))
for(SIMINT_tname in names(SIMINT_thist)){
# Appending the value, simtime, and timescale to the som output
SIMINT_somtt[["titration"]][[sprintf('tt.%s.value', SIMINT_tname)]] = rep(times=SIMINT_nobs, SIMINT_thist[[SIMINT_tname]][["value"]])
SIMINT_somtt[["titration"]][[sprintf('tt.%s.simtime', SIMINT_tname)]] = rep(times=SIMINT_nobs, SIMINT_thist[[SIMINT_tname]][["simtime"]])
SIMINT_somtt[["titration"]][[sprintf('tt.%s.timescale',SIMINT_tname)]] = rep(times=SIMINT_nobs, SIMINT_thist[[SIMINT_tname]][["timescale"]])
}
# Updating the initial condition to the last observation of som
SIMINT_IC = as.numeric(SIMINT_somtt[["simout"]][length(SIMINT_somtt[["simout"]][,1]), names(SIMINT_cfg[["options"]][["mi"]][["states"]])])
names(SIMINT_IC) = names(SIMINT_cfg[["options"]][["mi"]][["states"]])
# Stripping the last observation off of som
if(SIMINT_ttidx < length(SIMINT_ttimes)){
SIMINT_somtt[["simout"]] = SIMINT_somtt[["simout"]][1:(SIMINT_nobs - 1),]
SIMINT_somtt[["titration"]] = SIMINT_somtt[["titration"]][1:(SIMINT_nobs - 1),]
}
#Appending the simulation results to the master set of results
if(SIMINT_ttidx == 1){
SIMINT_som = SIMINT_somtt }
else{
SIMINT_som[["simout"]] = rbind(SIMINT_som[["simout"]], SIMINT_somtt[["simout"]])
SIMINT_som[["titration"]] = rbind(SIMINT_som[["titration"]], SIMINT_somtt[["titration"]])
}
}
SIMINT_som[["titration_history"]] = SIMINT_history
# pulls out the last row of simout
# som$simout[length(som$simout[,1]),]
return(SIMINT_som)
}
system_DYDT_<MODEL_PREFIX> = function(SIMINT_TIME,SIMINT_x,SIMINT_cfg){
#
# Evalutates the derivatives of the ODEs at time SIMINT_TIME
#
SIMINT_p = SIMINT_cfg[["parameters"]][["values"]]
# System parameters
<SYSTEM_PARAM>
for(SIMINT_rate_name in names(SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]])){
# Looping through each infusion rate and creating a variable in the current
# function with the rate at the value for the current time
# plucking out the rate name
SIMINT_my_rate = SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]][[SIMINT_rate_name]]
# scaling the times
eval(parse(text=sprintf('SIMINT_my_rate[["times"]][["values"]] = SIMINT_my_rate[["times"]][["values"]]*%s',SIMINT_my_rate[["times"]][["scale"]])))
# getting the covariate value at the given time
SIMINT_rate_value =
system_evaluate_input_<MODEL_PREFIX>(SIMINT_my_rate[["times"]][["values"]],
SIMINT_my_rate[["levels"]][["values"]],
SIMINT_TIME,
'step')
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_rate_value*%s",SIMINT_rate_name, SIMINT_my_rate[["levels"]][["scale"]]))))
}
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name at the value for the current time
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# getting the covariate value at the given time
SIMINT_cov_value =
system_evaluate_input_<MODEL_PREFIX>(SIMINT_my_cov[["times"]][["values"]],
SIMINT_my_cov[["values"]][["values"]],
SIMINT_TIME,
SIMINT_my_cov[["cv_interp"]])
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# States
<STATES>
# Static secondary parameters
<SS_PARAM>
# Dynamic secondary parameters
<DS_PARAM>
# ODEs
<ODES>
# ODE
SIMINT_DYDT = c(
<ODES_REMAP>)
#return(SIMINT_DYDT)
list(dy=SIMINT_DYDT,global=c())
}
system_map_output_<MODEL_PREFIX> = function(SIMINT_cfg, SIMINT_simout, SIMINT_p, SIMINT_eventdata){
# Pulling out the time vector
SIMINT_tts = SIMINT_simout[,'time']
# Creating the matrix to store the simout
SIMINT_all_outputs = c(names(SIMINT_cfg[["options"]][["mi"]][["states"]]), names(SIMINT_cfg[["options"]][["mi"]][["odes"]]))
SIMINT_simoutmat = matrix(data=NA, nrow=length(SIMINT_tts), ncol=(length(SIMINT_all_outputs) +1) )
colnames(SIMINT_simoutmat) = eval(parse(text= sprintf("c('time', '%s')", paste(SIMINT_all_outputs, collapse="', '"))))
# System parameters
<SYSTEM_PARAM>
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name (evaluated at the first instance)
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# This is an initialization step, and these should only use covariates
# that are constant (like gender or race), so we just use the first value
SIMINT_cov_value = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]][["values"]][["values"]][1]
# creating the named value for the covariate
# at the current time
# This is used when calculating secondary parameters:
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
# This will be stored in the output data frame
eval(parse(text=paste(sprintf("SIMINT_CVIC_%s = SIMINT_cov_value",SIMINT_cov_name))))
}
# Static secondary parameters
<SS_PARAM>
for (SIMINT_tidx in seq(1,length(SIMINT_tts))){
SIMINT_TIME = SIMINT_tts[SIMINT_tidx]
<TIME_SCALES>
# Creating the states here at a given time
# (above a vector was created)
for (SIMINT_sname in names(SIMINT_cfg[["options"]][["mi"]][["states"]])){
SIMINT_tmp_assignment = sprintf('%s = SIMINT_simout[[SIMINT_tidx, SIMINT_sname]]', SIMINT_sname) #JMH modify
eval(parse(text=SIMINT_tmp_assignment))
}
for(SIMINT_rate_name in names(SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]])){
# Looping through each infusion rate and creating a variable in the current
# function with the rate at the value for the current time
# plucking out the rate name
SIMINT_my_rate = SIMINT_cfg[["options"]][["inputs"]][["infusion_rates"]][[SIMINT_rate_name]]
# scaling the times
eval(parse(text=sprintf('SIMINT_my_rate[["times"]][["values"]] = SIMINT_my_rate[["times"]][["values"]]*%s',SIMINT_my_rate[["times"]][["scale"]])))
# getting the covariate value at the given time
SIMINT_rate_value = system_evaluate_input_<MODEL_PREFIX>(
SIMINT_my_rate[["times"]][["values"]],
SIMINT_my_rate[["levels"]][["values"]],
SIMINT_TIME,
'step')
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_rate_value*%s",SIMINT_rate_name, SIMINT_my_rate[["levels"]][["scale"]]))))
}
for(SIMINT_cov_name in names(SIMINT_cfg[["options"]][["inputs"]][["covariates"]])){
# Looping through each covariate and creating a variable in the current
# function with the covariate name at the value for the current time
# plucking out the covariate
SIMINT_my_cov = SIMINT_cfg[["options"]][["inputs"]][["covariates"]][[SIMINT_cov_name]]
# getting the covariate value at the given time
SIMINT_cov_value = system_evaluate_input_<MODEL_PREFIX>(
SIMINT_my_cov[["times"]][["values"]],
SIMINT_my_cov[["values"]][["values"]],
SIMINT_TIME,
SIMINT_my_cov[["cv_interp"]])
# creating the named value for the covariate
# at the current time
eval(parse(text=paste(sprintf("%s = SIMINT_cov_value",SIMINT_cov_name))))
}
<DS_PARAM>
# Outputs
<OUTPUTS>
# With all of the variables defined we add a row to the simout matrix
SIMINT_simoutmat[SIMINT_tidx,] = eval(parse(text=sprintf("c(SIMINT_TIME, %s)", paste(SIMINT_all_outputs , collapse=", "))))
}
return(SIMINT_simoutmat) }
system_evaluate_input_<MODEL_PREFIX> = function(tvals, lvals, etime, type){
#
# system_evaluate_input --- used to evaluate infusion rates and
# covariates at etime
#
# tvals - time values where time-series is defined
# lvals - corresponding values where the of the time series
# etime - time where the time-series is to be evaluated
# type - type of timeseries either: 'linear' or 'step'
#
# initializing the return value
value = -1
if(type == 'step'){
if(length(tvals) == 1){
# if there is only one element in tvals
# then we just take that value
value = tail(lvals, 1)
}
else if(etime > max(tvals)){
# the eval time is beyond the range of
# specified times then we carry the last
# one forward
value = tail(lvals, 1)
}
else if(etime < min(tvals)){
# the eval time is before the range of
# specified times then we assign it to
# the first value
value = lvals[1];
}
else{
# this should return the portion of the
# lvals vector that is less than
# the evaluation time (etime):
#
# lvals[tvals <= etime]
# and tail should pop off the last value
value = tail(lvals[tvals <= etime], 1)
}
}
else if(type == 'linear'){
if(length(tvals) == 1){
# if there is only 1 value then there is no linear interpolation :)
value = lvals
}
else{
#linearly interpolating, values beyond boundary
# will take on the values at the boundary
linear_interp = approx(tvals, lvals, etime, method="linear", rule=2, , , n=2)
value = linear_interp$y
}
}
return(value)
}
#-------------------------------------------------------------------------
# Looping through each output to add the error
add_observation_errors_<MODEL_PREFIX> = function(simout, parameters, cfg){
for(output in names(cfg[["ve"]])){
simout = output_add_error_<MODEL_PREFIX>(
SIMINT_simout = simout, # simulation output without error
SIMINT_output = output, # output
SIMINT_em = cfg[["ve"]][[output]],# error model
SIMINT_parameters = parameters, # current parameter values
SIMINT_cfg = cfg)
}
return(simout)}
#-------------------------------------------------------------------------
output_add_error_<MODEL_PREFIX> = function(SIMINT_simout, SIMINT_output, SIMINT_em, SIMINT_parameters, SIMINT_cfg){
# Defining the time
SIMINT_TIME = SIMINT_simout[,'time']
# Defining the pred values locally
PRED = SIMINT_simout[, SIMINT_output]
# Pulling the variance parameter names
SIMINT_VP_NAMES = as.vector(SIMINT_cfg[["parameters"]][["matrix"]][["name"]][SIMINT_cfg[["parameters"]][["matrix"]][["ptype"]] == 'variance'])
# Evaluating the variance parameters locally
for(SIMINT_VP_NAME in SIMINT_VP_NAMES){
eval(parse(text=sprintf('%s = as.numeric(SIMINT_parameters["%s"])', SIMINT_VP_NAME, SIMINT_VP_NAME)))
}
# calculating the error model value
eval(parse(text=sprintf("SIMINT_em_VARIANCE = %s", SIMINT_em)))
SIMINT_em_MEAN = rep(0,length(PRED));
SIMINT_ERR = rnorm(PRED, SIMINT_em_MEAN, sqrt(SIMINT_em_VARIANCE))
# adding the error to the prediction and storing it in SIMINT_simout
SIMINT_simout = eval(parse(text=sprintf('cbind(SIMINT_simout, SIOE_%s=c(PRED+SIMINT_ERR))', SIMINT_output)))
return(SIMINT_simout)}
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