## ----include = FALSE---------------------------------------------------------- knitr::opts_chunk$set( collapse = TRUE, comment = "#>", out.width = "300px", fig.width = 1.5625, # 150px / 96dpi fig.height = 1.5625, # makes 300 px plots dpi = 96, fig.align = "center" ) ## ----eval = TRUE, echo = FALSE------------------------------------------------ show_plot <- function(svg){ old_mar <- par()["mar"] on.exit(par(old_mar)) par(mar=rep(0,4)) charToRaw(svg) |> rsvg::rsvg_png(width = 300) |> magick::image_read() |> plot() } ## ----echo = TRUE, eval=FALSE-------------------------------------------------- # library(metainsight) # run_metainsight() ## ----write_plot, echo = TRUE, eval = FALSE------------------------------------ # summary_study(configured_data) |> write_plot("summary_study_plot.pdf") ## ----setup_load--------------------------------------------------------------- library(metainsight) loaded_data <- setup_load(outcome = "continuous") loaded_data$data[1:6, 1:7] |> knitr::kable() ## ----setup_configure---------------------------------------------------------- configured_data <- setup_configure(loaded_data = loaded_data, reference_treatment = "Placebo", effects = "random", outcome_measure = "MD", ranking_option = "good", seed = 123) ## ----setup_exclude------------------------------------------------------------ subsetted_data <- setup_exclude(configured_data = configured_data, exclusions = c("Study01", "Study02")) ## ----summary_char------------------------------------------------------------- characteristics <- summary_char(configured_data) characteristics$network |> knitr::kable() ## ----summary_study------------------------------------------------------------ summary_study(configured_data) |> show_plot() ## ----summary_network---------------------------------------------------------- summary_network(configured_data, style = "netplot") |> show_plot() ## ----freq_forest-------------------------------------------------------------- freq_forest(configured_data) |> show_plot() ## ----freq_compare------------------------------------------------------------- freq_compare(configured_data) |> knitr::kable() ## ----freq_inconsistency------------------------------------------------------- freq_inconsistency(configured_data) |> knitr::kable() ## ----freq_summary------------------------------------------------------------- freq_summary(configured_data) |> show_plot() ## ----bayes_model-------------------------------------------------------------- fitted_bayes_model <- bayes_model(configured_data, n_adapt = 100, n_iter = 100) ## ----bayes_ranking------------------------------------------------------------ ranking_data <- bayes_ranking(fitted_bayes_model, configured_data) ranking_plot(ranking_data, "rankogram") |> show_plot() ## ----bayes_mcmc, eval = FALSE------------------------------------------------- # mcmc_plots <- bayes_mcmc(fitted_bayes_model) # # mcmc_plots$gelman_plots # mcmc_plots$trace_plots # mcmc_plots$density_plots ## ----bayes_deviance, eval = FALSE--------------------------------------------- # deviance_plots <- bayes_deviance(fitted_bayes_model) # # deviance_plots$scat_plot # deviance_plots$stem_plot # deviance_plots$lev_plot ## ----bayes_nodesplit---------------------------------------------------------- nodesplit_path <- system.file("extdata", "continuous_nodesplit.csv", package = "metainsight") nodesplit_loaded_data <- setup_load(data_path = nodesplit_path, outcome = "continuous") nodesplit_configured_data <- setup_configure(loaded_data = nodesplit_loaded_data, reference_treatment = "Placebo", effects = "random", outcome_measure = "MD", ranking_option = "good", seed = 123) nodesplit_model <- bayes_nodesplit(nodesplit_configured_data, n_adapt = 100, n_iter = 100) bayes_nodesplit_plot(nodesplit_model) |> show_plot() ## ----covariate_model---------------------------------------------------------- fitted_covariate_model <- covariate_model(configured_data, covariate_value = 50, regressor_type = "shared", n_adapt = 100, n_iter = 100) ## ----covariate_regression----------------------------------------------------- regression_data <- covariate_regression(fitted_covariate_model, configured_data) metaregression_plot(fitted_covariate_model, configured_data, regression_data, comparators = c("Glucocorticoids", "Ketamine", "Gabapentinoids")) |> show_plot() ## ----baseline_summary--------------------------------------------------------- baseline_summary(configured_data) |> show_plot() ## ----baseline_model----------------------------------------------------------- fitted_baseline_model <- baseline_model(configured_data, regressor_type = "shared", n_iter = 120, max_iter = 120, check_iter = 12) ## ----export_cinema------------------------------------------------------------ cinema_project <- export_cinema(configured_data) writeLines(cinema_project, tempfile(fileext = ".json")) ## ----eval = FALSE------------------------------------------------------------- # common <- readRDS("")