server-scripts/qhtcp-workflow/apps/r/calculate_interaction_zscores.R

suppressMessages({
  library(ggplot2)
  library(plotly)
  library(htmlwidgets)
  library(dplyr)
  library(ggthemes)
  library(data.table)
  library(unix)
})

options(warn = 2, max.print = 1000)
options(width = 10000)

# Set the memory limit to 30GB (30 * 1024 * 1024 * 1024 bytes)
soft_limit <- 30 * 1024 * 1024 * 1024
hard_limit <- 30 * 1024 * 1024 * 1024
rlimit_as(soft_limit, hard_limit)

# Constants for configuration
plot_width <- 14
plot_height <- 9
base_size <- 14

parse_arguments <- function() {
  args <- if (interactive()) {
    c(
      "/home/bryan/documents/develop/hartmanlab/qhtcp-workflow/out/20240116_jhartman2_DoxoHLD/20240116_jhartman2_DoxoHLD",
      "/home/bryan/documents/develop/hartmanlab/qhtcp-workflow/apps/r/SGD_features.tab",
      "/home/bryan/documents/develop/hartmanlab/qhtcp-workflow/out/20240116_jhartman2_DoxoHLD/easy/20240116_jhartman2_DoxoHLD/results_std.txt",
      "/home/bryan/documents/develop/hartmanlab/qhtcp-workflow/out/20240116_jhartman2_DoxoHLD/20240822_jhartman2_DoxoHLD/exp1",
      "Experiment 1: Doxo versus HLD",
      3,
      "/home/bryan/documents/develop/hartmanlab/workflow/out/20240116_jhartman2_DoxoHLD/20240822_jhartman2_DoxoHLD/exp2",
      "Experiment 2: HLD versus Doxo",
      3
    )
  } else {
    commandArgs(trailingOnly = TRUE)
  }
  
  # Extract paths, names, and standard deviations
  paths <- args[seq(4, length(args), by = 3)]
  names <- args[seq(5, length(args), by = 3)]
  sds <- as.numeric(args[seq(6, length(args), by = 3)])
  
  # Normalize paths
  normalized_paths <- normalizePath(paths, mustWork = FALSE)
  
  # Create named list of experiments
  experiments <- list()
  for (i in seq_along(paths)) {
    experiments[[names[i]]] <- list(
      path = normalized_paths[i],
      sd = sds[i]
    )
  }
  
  list(
    out_dir = normalizePath(args[1], mustWork = FALSE),
    sgd_gene_list = normalizePath(args[2], mustWork = FALSE),
    easy_results_file = normalizePath(args[3], mustWork = FALSE),
    experiments = experiments
  )
}

args <- parse_arguments()

# Should we keep output in exp dirs or combine in the study output dir?
# dir.create(file.path(args$out_dir, "zscores"), showWarnings = FALSE)
# dir.create(file.path(args$out_dir, "zscores", "qc"), showWarnings = FALSE)

# Define themes and scales
theme_publication <- function(base_size = 14, base_family = "sans", legend_position = "bottom") {
  theme_foundation <- ggplot2::theme_grey(base_size = base_size, base_family = base_family)
  
  theme_foundation %+replace%
    theme(
      plot.title = element_text(face = "bold", size = rel(1.2), hjust = 0.5),
      text = element_text(),
      panel.background = element_rect(colour = NA),
      plot.background = element_rect(colour = NA),
      panel.border = element_rect(colour = NA),
      axis.title = element_text(face = "bold", size = rel(1)),
      axis.title.y = element_text(angle = 90, vjust = 2),
      axis.title.x = element_text(vjust = -0.2),
      axis.line = element_line(colour = "black"),
      panel.grid.major = element_line(colour = "#f0f0f0"),
      panel.grid.minor = element_blank(),
      legend.key = element_rect(colour = NA),
      legend.position = legend_position,
      legend.direction = ifelse(legend_position == "right", "vertical", "horizontal"),
      plot.margin = unit(c(10, 5, 5, 5), "mm"),
      strip.background = element_rect(colour = "#f0f0f0", fill = "#f0f0f0"),
      strip.text = element_text(face = "bold")
    )
}

scale_fill_publication <- function(...) {
  discrete_scale("fill", "Publication", manual_pal(values = c(
    "#386cb0", "#fdb462", "#7fc97f", "#ef3b2c", "#662506",
    "#a6cee3", "#fb9a99", "#984ea3", "#ffff33"
  )), ...)
}

scale_colour_publication <- function(...) {
  discrete_scale("colour", "Publication", manual_pal(values = c(
    "#386cb0", "#fdb462", "#7fc97f", "#ef3b2c", "#662506",
    "#a6cee3", "#fb9a99", "#984ea3", "#ffff33"
  )), ...)
}

# Load the initial dataframe from the easy_results_file
load_and_process_data <- function(easy_results_file, sd = 3) {
  df <- read.delim(easy_results_file, skip = 2, as.is = TRUE, row.names = 1, strip.white = TRUE)
  
  df <- df %>%
    filter(!(.[[1]] %in% c("", "Scan"))) %>%
    filter(!is.na(ORF) & ORF != "" & !Gene %in% c("BLANK", "Blank", "blank") & Drug != "BMH21") %>%
    # Rename columns
    rename(L = l, num = Num., AUC = AUC96, scan = Scan, last_bg = LstBackgrd, first_bg = X1stBackgrd) %>%
    mutate(
      across(c(Col, Row, num, L, K, r, scan, AUC, last_bg, first_bg), as.numeric),
      delta_bg = last_bg - first_bg,
      delta_bg_tolerance = mean(delta_bg, na.rm = TRUE) + (sd * sd(delta_bg, na.rm = TRUE)),
      NG = if_else(L == 0 & !is.na(L), 1, 0),
      DB = if_else(delta_bg >= delta_bg_tolerance, 1, 0),
      SM = 0,
      OrfRep = if_else(ORF == "YDL227C", "YDL227C", OrfRep), # should these be hardcoded?
      conc_num = as.numeric(gsub("[^0-9\\.]", "", Conc)),
      conc_num_factor = as.numeric(as.factor(conc_num)) - 1
    )
  
  return(df)
}

# Update Gene names using the SGD gene list
update_gene_names <- function(df, sgd_gene_list) {
  # Load SGD gene list
  genes <- read.delim(file = sgd_gene_list,
    quote = "", header = FALSE,
    colClasses = c(rep("NULL", 3), rep("character", 2), rep("NULL", 11)))
  
  # Create a named vector for mapping ORF to GeneName
  gene_map <- setNames(genes$V5, genes$V4)
  # Vectorized match to find the GeneName from gene_map
  mapped_genes <- gene_map[df$ORF]
  # Replace NAs in mapped_genes with original Gene names (preserves existing Gene names if ORF is not found)
  updated_genes <- ifelse(is.na(mapped_genes) | df$OrfRep == "YDL227C", df$Gene, mapped_genes)
  # Ensure Gene is not left blank or incorrectly updated to "OCT1"
  df <- df %>%
    mutate(Gene = ifelse(updated_genes == "" | updated_genes == "OCT1", OrfRep, updated_genes))
  
  return(df)
}

# Calculate summary statistics for all variables
calculate_summary_stats <- function(df, variables, group_vars = c("conc_num", "conc_num_factor")) {
  df <- df %>%
    mutate(across(all_of(variables), ~ ifelse(. == 0, NA, .)))

  summary_stats <- df %>%
    group_by(across(all_of(group_vars))) %>%
    summarise(
      N = sum(!is.na(L)),
      across(all_of(variables), list(
        mean = ~mean(., na.rm = TRUE),
        median = ~median(., na.rm = TRUE),
        max = ~max(., na.rm = TRUE),
        min = ~min(., na.rm = TRUE),
        sd = ~sd(., na.rm = TRUE),
        se = ~sd(., na.rm = TRUE) / sqrt(sum(!is.na(.)) - 1)
      ), .names = "{.fn}_{.col}")
    )

  df_cleaned <- df %>%
    select(-any_of(names(summary_stats)))

  df_with_stats <- left_join(df_cleaned, summary_stats, by = group_vars)

  return(list(summary_stats = summary_stats, df_with_stats = df_with_stats))
}

calculate_interaction_scores <- function(df, max_conc, variables, group_vars = c("OrfRep", "Gene", "num")) {

  # Calculate total concentration variables
  total_conc_num <- length(unique(df$conc_num))
  num_non_removed_concs <- total_conc_num - sum(df$DB, na.rm = TRUE) - 1

  # Pull the background means and standard deviations from zero concentration
  bg_means <- list(
    L = df %>% filter(conc_num_factor == 0) %>% pull(mean_L) %>% first(),
    K = df %>% filter(conc_num_factor == 0) %>% pull(mean_K) %>% first(),
    r = df %>% filter(conc_num_factor == 0) %>% pull(mean_r) %>% first(),
    AUC = df %>% filter(conc_num_factor == 0) %>% pull(mean_AUC) %>% first()
  )

  bg_sd <- list(
    L = df %>% filter(conc_num_factor == 0) %>% pull(sd_L) %>% first(),
    K = df %>% filter(conc_num_factor == 0) %>% pull(sd_K) %>% first(),
    r = df %>% filter(conc_num_factor == 0) %>% pull(sd_r) %>% first(),
    AUC = df %>% filter(conc_num_factor == 0) %>% pull(sd_AUC) %>% first()
  )

  calculations <- df %>%
    mutate(
      WT_L = df$mean_L,
      WT_K = df$mean_K,
      WT_r = df$mean_r,
      WT_AUC = df$mean_AUC,
      WT_sd_L = df$sd_L,
      WT_sd_K = df$sd_K,
      WT_sd_r = df$sd_r,
      WT_sd_AUC = df$sd_AUC
    ) %>%
    group_by(across(all_of(group_vars)), conc_num, conc_num_factor) %>%
      mutate(
        N = sum(!is.na(L)),
        NG = sum(NG, na.rm = TRUE),
        DB = sum(DB, na.rm = TRUE),
        SM = sum(SM, na.rm = TRUE),
        across(all_of(variables), list(
          mean = ~mean(., na.rm = TRUE),
          median = ~median(., na.rm = TRUE),
          max = ~max(., na.rm = TRUE),
          min = ~min(., na.rm = TRUE),
          sd = ~sd(., na.rm = TRUE),
          se = ~sd(., na.rm = TRUE) / sqrt(sum(!is.na(.)) - 1)
        ), .names = "{.fn}_{.col}")
      ) %>%
    ungroup()

  calculations <- calculations %>%
    group_by(across(all_of(group_vars))) %>%
      mutate(
        Raw_Shift_L = mean_L[[1]] - bg_means$L,
        Raw_Shift_K = mean_K[[1]] - bg_means$K,
        Raw_Shift_r = mean_r[[1]] - bg_means$r,
        Raw_Shift_AUC = mean_AUC[[1]] - bg_means$AUC,
        Z_Shift_L = Raw_Shift_L[[1]] / bg_sd$L,
        Z_Shift_K = Raw_Shift_K[[1]] / bg_sd$K,
        Z_Shift_r = Raw_Shift_r[[1]] / bg_sd$r,
        Z_Shift_AUC = Raw_Shift_AUC[[1]] / bg_sd$AUC
      )

  calculations <- calculations %>%
    mutate(
      Exp_L = WT_L + Raw_Shift_L,
      Delta_L = mean_L - Exp_L,
      Exp_K = WT_K + Raw_Shift_K,
      Delta_K = mean_K - Exp_K,
      Exp_r = WT_r + Raw_Shift_r,
      Delta_r = mean_r - Exp_r,
      Exp_AUC = WT_AUC + Raw_Shift_AUC,
      Delta_AUC = mean_AUC - Exp_AUC
    )

  calculations <- calculations %>%
    mutate(
      Delta_L = if_else(NG == 1, mean_L - WT_L, Delta_L),
      Delta_K = if_else(NG == 1, mean_K - WT_K, Delta_K),
      Delta_r = if_else(NG == 1, mean_r - WT_r, Delta_r),
      Delta_AUC = if_else(NG == 1, mean_AUC - WT_AUC, Delta_AUC),
      Delta_L = if_else(SM == 1, mean_L - WT_L, Delta_L)
    )

  interactions <- calculations %>%
    mutate(
      lm_L = lm(Delta_L ~ conc_num_factor),
      lm_K = lm(Delta_K ~ conc_num_factor),
      lm_r = lm(Delta_r ~ conc_num_factor),
      lm_AUC = lm(Delta_AUC ~ conc_num_factor),
      Zscore_L = Delta_L / WT_sd_L,
      Zscore_K = Delta_K / WT_sd_K,
      Zscore_r = Delta_r / WT_sd_r,
      Zscore_AUC = Delta_AUC / WT_sd_AUC
    )

  interactions <- interactions %>%
    mutate(
      lm_Score_L = max_conc * coef(lm_L)[2] + coef(lm_L)[1],
      lm_Score_K = max_conc * coef(lm_K)[2] + coef(lm_K)[1],
      lm_Score_r = max_conc * coef(lm_r)[2] + coef(lm_r)[1],
      lm_Score_AUC = max_conc * coef(lm_AUC)[2] + coef(lm_AUC)[1],
      r_squared_L = summary(lm_L)$r.squared,
      r_squared_K = summary(lm_K)$r.squared,
      r_squared_r = summary(lm_r)$r.squared,
      r_squared_AUC = summary(lm_AUC)$r.squared,
      Sum_Zscore_L = sum(Zscore_L, na.rm = TRUE),
      Sum_Zscore_K = sum(Zscore_K, na.rm = TRUE),
      Sum_Zscore_r = sum(Zscore_r, na.rm = TRUE),
      Sum_Zscore_AUC = sum(Zscore_AUC, na.rm = TRUE)
    )

  interactions <- interactions %>%
    mutate(
      Avg_Zscore_L = Sum_Zscore_L / num_non_removed_concs,
      Avg_Zscore_K = Sum_Zscore_K / num_non_removed_concs,
      Avg_Zscore_r = Sum_Zscore_r / (total_conc_num - 1),
      Avg_Zscore_AUC = Sum_Zscore_AUC / (total_conc_num - 1),
      Z_lm_L = (lm_Score_L - mean(lm_Score_L, na.rm = TRUE)) / sd(lm_Score_L, na.rm = TRUE),
      Z_lm_K = (lm_Score_K - mean(lm_Score_K, na.rm = TRUE)) / sd(lm_Score_K, na.rm = TRUE),
      Z_lm_r = (lm_Score_r - mean(lm_Score_r, na.rm = TRUE)) / sd(lm_Score_r, na.rm = TRUE),
      Z_lm_AUC = (lm_Score_AUC - mean(lm_Score_AUC, na.rm = TRUE)) / sd(lm_Score_AUC, na.rm = TRUE)
    )

  calculations <- calculations %>%
    select("OrfRep", "Gene", "num", "conc_num", "conc_num_factor",
      "mean_L", "mean_K", "mean_r", "mean_AUC",
      "median_L", "median_K", "median_r", "median_AUC",
      "sd_L", "sd_K", "sd_r", "sd_AUC",
      "se_L", "se_K", "se_r", "se_AUC",
      "Raw_Shift_L", "Raw_Shift_K", "Raw_Shift_r", "Raw_Shift_AUC",
      "Z_Shift_L", "Z_Shift_K", "Z_Shift_r", "Z_Shift_AUC",
      "WT_L", "WT_K", "WT_r", "WT_AUC", "WT_sd_L", "WT_sd_K", "WT_sd_r", "WT_sd_AUC",
      "Exp_L", "Exp_K", "Exp_r", "Exp_AUC", "Delta_L", "Delta_K", "Delta_r", "Delta_AUC",
      "Zscore_L", "Zscore_K", "Zscore_r", "Zscore_AUC",
      "NG", "SM", "DB") %>%
    ungroup()

  # Arrange results by Z_lm_L and NG
  interactions <- interactions %>%
    select("OrfRep", "Gene", "num", "Raw_Shift_L", "Raw_Shift_K",  "Raw_Shift_AUC", "Raw_Shift_r",
      "Z_Shift_L", "Z_Shift_K", "Z_Shift_r", "Z_Shift_AUC",
      "lm_Score_L", "lm_Score_K", "lm_Score_AUC", "lm_Score_r",
      "R_Squared_L", "R_Squared_K", "R_Squared_r", "R_Squared_AUC",
      "Sum_Z_Score_L", "Sum_Z_Score_K", "Sum_Z_Score_r", "Sum_Z_Score_AUC",
      "Avg_Zscore_L", "Avg_Zscore_K", "Avg_Zscore_r", "Avg_Zscore_AUC",
      "Z_lm_L", "Z_lm_K", "Z_lm_r", "Z_lm_AUC",
      "NG", "SM", "DB") %>%
    arrange(desc(lm_Score_L)) %>%
    arrange(desc(NG)) %>%
    ungroup()

  return(list(calculations = calculations, interactions = interaction))
}

generate_and_save_plots <- function(output_dir, file_name, plot_configs, grid_layout = NULL) {
  
  `%||%` <- function(a, b) if (!is.null(a)) a else b
  
  # Generalized plot generation
  plots <- lapply(plot_configs, function(config) {
    
    df <- config$df
    plot <- ggplot(df, aes(x = !!sym(config$x_var), y = !!sym(config$y_var), color = as.factor(!!sym(config$color_var))))
    
    # Rank plots with SD annotations
    if (config$plot_type == "rank") {
      plot <- plot + geom_point(size = 0.1, shape = 3)
      
      # Adding SD bands
      if (!is.null(config$sd_band)) {
        for (i in seq_len(config$sd_band)) {
          plot <- plot +
            annotate("rect", xmin = -Inf, xmax = Inf, ymin = i, ymax = Inf, fill = "#542788", alpha = 0.3) +
            annotate("rect", xmin = -Inf, xmax = Inf, ymin = -i, ymax = -Inf, fill = "orange", alpha = 0.3) +
            geom_hline(yintercept = c(-i, i), color = "gray")
        }
      }

      # Optionally add enhancer/suppressor count annotations
      if (!is.null(config$enhancer_label)) {
        plot <- plot + annotate("text", x = config$enhancer_label$x,
          y = config$enhancer_label$y, label = config$enhancer_label$label) +
          annotate("text", x = config$suppressor_label$x,
            y = config$suppressor_label$y, label = config$suppressor_label$label)
      }
    }
    
    # Correlation plots
    if (config$plot_type == "correlation") {
      plot <- plot + geom_point(shape = 3, color = "gray70") +
        geom_smooth(method = "lm", color = "tomato3") +
        annotate("text", x = 0, y = 0, label = config$correlation_text)
    }

    # General scatter/boxplot/density handling
    if (!is.null(config$y_var)) {
      plot <- plot + aes(y = !!sym(config$y_var))
      
      y_mean_col <- paste0("mean_", config$y_var)
      y_sd_col <- paste0("sd_", config$y_var)
      
      if (config$y_var == "delta_bg" && config$plot_type == "scatter") {
        plot <- plot + geom_point(shape = 3, size = 0.2, position = "jitter") +
          geom_errorbar(aes(ymin = !!sym(y_mean_col) - !!sym(y_sd_col),
            ymax = !!sym(y_mean_col) + !!sym(y_sd_col)), width = 0.1) +
          geom_point(aes(y = !!sym(y_mean_col)), size = 0.6)
      } else if (config$error_bar %||% FALSE) {
        plot <- plot +
          geom_point(shape = 3, size = 0.2) +
          geom_errorbar(aes(ymin = !!sym(y_mean_col) - !!sym(y_sd_col),
            ymax = !!sym(y_mean_col) + !!sym(y_sd_col)), width = 0.1) +
          geom_point(aes(y = !!sym(y_mean_col)), size = 0.6)
      }
    }

    # Plot type selection
    plot <- switch(config$plot_type,
      "box" = plot + geom_boxplot(),
      "density" = plot + geom_density(),
      "bar" = plot + geom_bar(stat = "identity"),
      plot + geom_point() + geom_smooth(method = "lm", se = FALSE))
    
    # Adding y-limits if provided
    if (!is.null(config$ylim_vals)) {
      plot <- plot + coord_cartesian(ylim = config$ylim_vals)
    }

    # Setting legend position, titles, and labels
    legend_position <- config$legend_position %||% "bottom"
    plot <- plot + ggtitle(config$title) + theme_Publication(legend_position = legend_position)
    
    if (!is.null(config$x_label)) plot <- plot + xlab(config$x_label)
    if (!is.null(config$y_label)) plot <- plot + ylab(config$y_label)
    
    # Adding text annotations if provided
    if (!is.null(config$annotations)) {
      for (annotation in config$annotations) {
        plot <- plot + annotate("text", x = annotation$x, y = annotation$y, label = annotation$label)
      }
    }
    
    return(plot)
  })
  
  # If grid_layout is provided, arrange plots in a grid and save in a single PDF
  if (!is.null(grid_layout)) {
    pdf(file.path(output_dir, paste0(file_name, ".pdf")), width = 14, height = 9)
    
    # Loop through plots in chunks defined by ncol and nrow
    for (start_idx in seq(1, length(plots), by = grid_layout$ncol * grid_layout$nrow)) {
      end_idx <- min(start_idx + grid_layout$ncol * grid_layout$nrow - 1, length(plots))
      plot_subset <- plots[start_idx:end_idx]
      
      # Arrange plots in a grid
      do.call(grid.arrange, c(plot_subset, ncol = grid_layout$ncol, nrow = grid_layout$nrow))
    }
    
    dev.off()
    
    # Save as HTML (optional)
    plotly_plots <- lapply(plots, function(plot) {
      suppressWarnings(ggplotly(plot) %>% layout(legend = list(orientation = "h")))
    })
    combined_plot <- subplot(plotly_plots, nrows = grid_layout$nrow, margin = 0.05)
    saveWidget(combined_plot, file = file.path(output_dir, paste0(file_name, "_grid.html")), selfcontained = TRUE)
    
  } else {
    # Save individual plots to PDF
    pdf(file.path(output_dir, paste0(file_name, ".pdf")), width = 14, height = 9)
    lapply(plots, print)
    dev.off()
    
    # Convert plots to plotly and save as HTML
    plotly_plots <- lapply(plots, function(plot) {
      suppressWarnings(ggplotly(plot) %>% layout(legend = list(orientation = "h")))
    })
    combined_plot <- subplot(plotly_plots, nrows = length(plotly_plots), margin = 0.05)
    saveWidget(combined_plot, file = file.path(output_dir, paste0(file_name, ".html")), selfcontained = TRUE)
  }
}

generate_interaction_plot_configs <- function(df, variables) {
  plot_configs <- list()

  for (variable in variables) {
    # Define the y-limits based on the variable being plotted
    ylim_vals <- switch(variable,
      "L" = c(-65, 65),
      "K" = c(-65, 65),
      "r" = c(-0.65, 0.65),
      "AUC" = c(-6500, 6500)
    )

    # Dynamically generate the column names for standard deviation and delta
    wt_sd_col <- paste0("WT_sd_", variable)
    delta_var <- paste0("Delta_", variable)
    z_shift <- paste0("Z_Shift_", variable)
    z_lm <- paste0("Z_lm_", variable)

    # Set annotations for ZShift, Z lm Score, NG, DB, SM
    annotations <- list(
      list(x = 1, y = ifelse(variable == "L", 45, ifelse(variable == "K", 45,
        ifelse(variable == "r", 0.45, 4500))), label = paste("ZShift =", round(df[[z_shift]], 2))),
      list(x = 1, y = ifelse(variable == "L", 25, ifelse(variable == "K", 25,
        ifelse(variable == "r", 0.25, 2500))), label = paste("lm ZScore =", round(df[[z_lm]], 2))),
      list(x = 1, y = ifelse(variable == "L", -25, ifelse(variable == "K", -25,
        ifelse(variable == "r", -0.25, -2500))), label = paste("NG =", df$NG)),
      list(x = 1, y = ifelse(variable == "L", -35, ifelse(variable == "K", -35,
        ifelse(variable == "r", -0.35, -3500))), label = paste("DB =", df$DB)),
      list(x = 1, y = ifelse(variable == "L", -45, ifelse(variable == "K", -45,
        ifelse(variable == "r", -0.45, -4500))), label = paste("SM =", df$SM))
    )

    # Add scatter plot configuration for this variable
    plot_configs[[length(plot_configs) + 1]] <- list(
      df = df,
      x_var = "conc_num_factor",
      y_var = delta_var,
      plot_type = "scatter",
      title = sprintf("%s      %s", df$OrfRep[1], df$Gene[1]),
      ylim_vals = ylim_vals,
      annotations = annotations,
      error_bar = list(
        ymin = 0 - (2 * df[[wt_sd_col]][1]),
        ymax = 0 + (2 * df[[wt_sd_col]][1])
      ),
      x_breaks = unique(df$conc_num_factor),
      x_labels = unique(as.character(df$conc_num)),
      x_label = unique(df$Drug[1])
    )

    # Add box plot configuration for this variable
    plot_configs[[length(plot_configs) + 1]] <- list(
      df = df,
      x_var = "conc_num_factor",
      y_var = variable,
      plot_type = "box",
      title = sprintf("%s      %s (Boxplot)", df$OrfRep[1], df$Gene[1]),
      ylim_vals = ylim_vals,
      annotations = annotations,
      error_bar = FALSE,  # Boxplots typically don't need error bars
      x_breaks = unique(df$conc_num_factor),
      x_labels = unique(as.character(df$conc_num)),
      x_label = unique(df$Drug[1])
    )
  }

  return(plot_configs)
}

generate_rank_plot_configs <- function(df, rank_var, zscore_var, label_prefix, is_lm = FALSE) {
  configs <- list()
  
  # Adjust titles for _lm plots if is_lm is TRUE
  plot_title_prefix <- if (is_lm) "Interaction Z score vs. Rank for" else "Average Z score vs. Rank for"
  
  for (sd_band in c(1, 2, 3)) {
    # Annotated version (with text)
    configs[[length(configs) + 1]] <- list(
      df = df,
      x_var = rank_var,
      y_var = zscore_var,
      plot_type = "rank",
      title = paste(plot_title_prefix, label_prefix, "above", sd_band, "SD"),
      sd_band = sd_band,
      enhancer_label = list(
        x = nrow(df) / 2, y = 10,
        label = paste("Deletion Enhancers =", nrow(df[df[[zscore_var]] >= sd_band, ]))
      ),
      suppressor_label = list(
        x = nrow(df) / 2, y = -10,
        label = paste("Deletion Suppressors =", nrow(df[df[[zscore_var]] <= -sd_band, ]))
      )
    )
    
    # Non-annotated version (_notext)
    configs[[length(configs) + 1]] <- list(
      df = df,
      x_var = rank_var,
      y_var = zscore_var,
      plot_type = "rank",
      title = paste(plot_title_prefix, label_prefix, "above", sd_band, "SD"),
      sd_band = sd_band,
      enhancer_label = NULL,  # No annotations for _notext
      suppressor_label = NULL  # No annotations for _notext
    )
  }
  
  return(configs)
}

generate_correlation_plot_configs <- function(df, lm_list, lm_summaries) {
  lapply(seq_along(lm_list), function(i) {
    r_squared <- round(lm_summaries[[i]]$r.squared, 3)
    list(
      x_var = names(lm_list)[i][1],
      y_var = names(lm_list)[i][2],
      plot_type = "scatter",
      title = paste("Correlation between", names(lm_list)[i][1], "and", names(lm_list)[i][2]),
      annotations = list(list(x = 0, y = 0, label = paste("R-squared =", r_squared)))
    )
  })
}

# Adjust missing values and calculate ranks
adjust_missing_and_rank <- function(df, variables) {

  # Adjust missing values in Avg_Zscore and Z_lm columns, and apply rank to the specified variables
  df <- df %>%
    mutate(across(all_of(variables), list(
      Avg_Zscore = ~ if_else(is.na(get(paste0("Avg_Zscore_", cur_column()))), 0.001, get(paste0("Avg_Zscore_", cur_column()))),
      Z_lm = ~ if_else(is.na(get(paste0("Z_lm_", cur_column()))), 0.001, get(paste0("Z_lm_", cur_column()))),
      Rank = ~ rank(get(paste0("Avg_Zscore_", cur_column()))),
      Rank_lm = ~ rank(get(paste0("Z_lm_", cur_column())))
    ), .names = "{fn}_{col}"))

  return(df)
}

main <- function() {
  lapply(names(args$experiments), function(exp_name) {
    exp <- args$experiments[[exp_name]]
    exp_path <- exp$path
    exp_sd <- exp$sd
    out_dir <- file.path(exp_path, "zscores")
    out_dir_qc <- file.path(exp_path, "zscores", "qc")
    dir.create(out_dir, recursive = TRUE, showWarnings = FALSE)
    dir.create(out_dir_qc, recursive = TRUE, showWarnings = FALSE)
    
    # Load and process data
    df <- load_and_process_data(args$easy_results_file, sd = exp_sd)
    df <- update_gene_names(df, args$sgd_gene_list)
    
    max_conc <- max(df$conc_num_factor)
    
    # QC steps and filtering
    df_above_tolerance <- df %>% filter(DB == 1)

    # Calculate the half-medians for `L` and `K` for rows above tolerance
    L_half_median <- (median(df_above_tolerance$L, na.rm = TRUE)) / 2
    K_half_median <- (median(df_above_tolerance$K, na.rm = TRUE)) / 2

    # Get the number of rows that are above tolerance
    rows_to_remove <- nrow(df_above_tolerance)

    # Set L, r, K, and AUC to NA for rows that are above tolerance
    df_na <- df %>% mutate(across(c(L, r, AUC, K), ~ ifelse(DB == 1, NA, .)))

    # Calculate summary statistics for all strains, including both background and the deletions
    message("Calculating summary statistics for all strains")
    variables <- c("L", "K", "r", "AUC")
    ss <- calculate_summary_stats(df_na, variables, group_vars = c("OrfRep", "conc_num", "conc_num_factor"))
    summary_stats <- ss$summary_stats
    df_na_stats <- ss$df_with_stats
    write.csv(summary_stats, file = file.path(out_dir, "SummaryStats_ALLSTRAINS.csv"), row.names = FALSE)

    print("Summary stats:")
    print(head(summary_stats), width = 200)

    # Remove rows with 0 values in L
    df_no_zeros <- df_na %>% filter(L > 0)

    # Additional filtering for non-finite values
    df_na_filtered <- df_na %>%
      filter(if_any(c(L), ~ !is.finite(.))) %>%
      {
        if (nrow(.) > 0) {
          message("Removing non-finite rows:\n")
          print(head(., n = 10))
        }
        df_na %>% filter(if_all(c(L), is.finite))
      }

    # Filter data within and outside 2SD
    message("Filtering by 2SD of K")
    df_na_within_2sd_k <- df_na_stats %>%
      filter(K >= (mean_K - 2 * sd_K) & K <= (mean_K + 2 * sd_K))
    df_na_outside_2sd_k <- df_na_stats %>%
      filter(K < (mean_K - 2 * sd_K) | K > (mean_K + 2 * sd_K))

    # Summary statistics for within and outside 2SD of K
    message("Calculating summary statistics for L within 2SD of K")
    # TODO We're omitting the original z_max calculation, not sure if needed?
    ss <- calculate_summary_stats(df_na_within_2sd_k, "L", group_vars = c("conc_num", "conc_num_factor"))
    l_within_2sd_k_stats <- ss$summary_stats
    df_na_l_within_2sd_k_stats <- ss$df_with_stats
    message("Calculating summary statistics for L outside 2SD of K")
    ss <- calculate_summary_stats(df_na_outside_2sd_k, "L", group_vars = c("conc_num", "conc_num_factor"))
    l_outside_2sd_k_stats <- ss$summary_stats
    df_na_l_outside_2sd_k_stats <- ss$df_with_stats
    # Write CSV files
    write.csv(l_within_2sd_k_stats, file = file.path(out_dir_qc, "Max_Observed_L_Vals_for_spots_within_2sd_k.csv"), row.names = FALSE)
    write.csv(l_outside_2sd_k_stats, file = file.path(out_dir, "Max_Observed_L_Vals_for_spots_outside_2sd_k.csv"), row.names = FALSE)

    # Plots

    # Print quality control graphs before removing data due to contamination and
    # adjusting missing data to max theoretical values
    message("Generating QC plot configurations")
    l_vs_k_plots <- list(
      list(df = df, x_var = "L", y_var = "K", plot_type = "scatter",
        title = "Raw L vs K before QC",
        color_var = "conc_num",
        legend_position = "right"
      )
    )

    above_threshold_plots <- list(
      list(df = df_above_tolerance, x_var = "L", y_var = "K", plot_type = "scatter",
        title = paste("Raw L vs K for strains above delta background threshold of", df_above_tolerance$delta_bg_tolerance[[1]], "or above"),
        color_var = "conc_num",
        annotations = list(
          list(
            x = L_half_median,
            y = K_half_median,
            label = paste("Strains above delta background tolerance =", nrow(df_above_tolerance))
          )
        ),
        error_bar = FALSE,
        legend_position = "right"
      )
    )

    frequency_delta_bg_plots <- list(
      list(df = df, x_var = "delta_bg", y_var = NULL, plot_type = "density",
        title = "Density plot for Delta Background by Conc All Data",
        color_var = "conc_num",
        x_label = "Delta Background",
        y_label = "Density",
        error_bar = FALSE,
        legend_position = "right"
      ),
      list(df = df, x_var = "delta_bg", y_var = NULL, plot_type = "bar",
        title = "Bar plot for Delta Background by Conc All Data",
        color_var = "conc_num",
        x_label = "Delta Background",
        y_label = "Count",
        error_bar = FALSE,
        legend_position = "right"
      )
    )

    plate_analysis_plots <- list()
    for (plot_type in c("scatter", "box")) {
      variables <- c("L", "K", "r", "AUC", "delta_bg")
      for (var in variables) {
        for (stage in c("before", "after")) {
          if (stage == "before") {
            df_plot <- df
          } else {
            df_plot <- df_na # TODO use df_na_filtered if necessary
          }
          
          # Set error_bar = TRUE only for scatter plots
          error_bar <- ifelse(plot_type == "scatter", TRUE, FALSE)
          
          # Create the plot configuration
          plot_config <- list(df = df_plot, x_var = "scan", y_var = var, plot_type = plot_type,
            title = paste("Plate analysis by Drug Conc for", var, stage, "quality control"),
            error_bar = error_bar, color_var = "conc_num")

          plate_analysis_plots <- append(plate_analysis_plots, list(plot_config))
        }
      }
    }

    plate_analysis_no_zero_plots <- list()
      for (plot_type in c("scatter", "box")) {
        variables <- c("L", "K", "r", "AUC", "delta_bg")
        for (var in variables) {
            
          # Set error_bar = TRUE only for scatter plots
          error_bar <- ifelse(plot_type == "scatter", TRUE, FALSE)
          
          # Create the plot configuration
          plot_config <- list(
            df = df_no_zeros,
            x_var = "scan",
            y_var = var,
            plot_type = plot_type,
            title = paste("Plate analysis by Drug Conc for", var, "after quality control"),
            error_bar = error_bar,
            color_var = "conc_num"
          )
          plate_analysis_plots <- append(plate_analysis_plots, list(plot_config))
        }
      }

    l_outside_2sd_k_plots <- list(
      list(df = X_outside_2SD_K, x_var = "l", y_var = "K", plot_type = "scatter",
        title = "Raw L vs K for strains falling outside 2SD of the K mean at each Conc",
        color_var = "conc_num",
        legend_position = "right"
      )
    )

    delta_bg_outside_2sd_k_plots <- list(
      list(df = X_outside_2SD_K, x_var = "delta_bg", y_var = "K", plot_type = "scatter",
        title = "Delta Background vs K for strains falling outside 2SD of the K mean at each Conc",
        color_var = "conc_num",
        legend_position = "right"
      )
    )

    # Generate and save plots for each QC step
    message("Generating QC plots")
    generate_and_save_plots(out_dir_qc, "L_vs_K_before_quality_control", l_vs_k_plots)
    generate_and_save_plots(out_dir_qc, "L_vs_K_above_threshold", above_threshold_plots)
    generate_and_save_plots(out_dir_qc, "frequency_delta_background", frequency_delta_bg_plots)
    generate_and_save_plots(out_dir_qc, "plate_analysis", plate_analysis_plots)
    generate_and_save_plots(out_dir_qc, "plate_analysis_no_zeros", plate_analysis_no_zeros_plots)
    generate_and_save_plots(out_dir_qc, "L_vs_K_for_strains_2SD_outside_mean_K", l_outside_2sd_k_plots)
    generate_and_save_plots(out_dir_qc, "delta_background_vs_K_for_strains_2sd_outside_mean_K", delta_bg_outside_2sd_k_plots)

    # Clean up
    rm(df, df_above_tolerance, df_no_zeros)

    # TODO: Originally this filtered L NA's
    # Let's try to avoid for now since stats have already been calculated

    # Process background strains
    bg_strains <- c("YDL227C")
    lapply(bg_strains, function(strain) {
      
      message("Processing background strain: ", strain)
      
      # Handle missing data by setting zero values to NA
      # and then removing any rows with NA in L col
      df_bg <- df_na %>%
        filter(OrfRep == strain) %>%
        mutate(
          L = if_else(L == 0, NA, L),
          K = if_else(K == 0, NA, K),
          r = if_else(r == 0, NA, r),
          AUC = if_else(AUC == 0, NA, AUC)
        ) %>%
        filter(!is.na(L))
      
      # Recalculate summary statistics for the background strain
      message("Calculating summary statistics for background strain")
      ss <- calculate_summary_stats(df_bg, variables, group_vars = c("OrfRep", "conc_num", "conc_num_factor"))
      summary_stats_bg <- ss$summary_stats
      df_bg_stats <- ss$df_with_stats
      write.csv(summary_stats_bg,
        file = file.path(out_dir, paste0("SummaryStats_BackgroundStrains_", strain, ".csv")),
        row.names = FALSE)
      
      # Filter reference and deletion strains
      # Formerly X2_RF (reference strains)
      df_reference <- df_na_stats %>%
        filter(OrfRep == strain) %>%
        mutate(SM = 0)
      
      # Formerly X2 (deletion strains)
      df_deletion <- df_na_stats %>%
        filter(OrfRep != strain) %>%
        mutate(SM = 0)

      # Set the missing values to the highest theoretical value at each drug conc for L
      # Leave other values as 0 for the max/min
      reference_strain <- df_reference %>%
        group_by(conc_num) %>%
        mutate(
          max_l_theoretical = max(max_L, na.rm = TRUE),
          L = ifelse(L == 0 & !is.na(L) & conc_num > 0, max_l_theoretical, L),
          SM = ifelse(L >= max_l_theoretical & !is.na(L) & conc_num > 0, 1, SM),
          L = ifelse(L >= max_l_theoretical & !is.na(L) & conc_num > 0, max_l_theoretical, L)) %>%
        ungroup()

      # Ditto for deletion strains
      deletion_strains <- df_deletion %>%
        group_by(conc_num) %>%
        mutate(
          max_l_theoretical = max(max_L, na.rm = TRUE),
          L = ifelse(L == 0 & !is.na(L) & conc_num > 0, max_l_theoretical, L),
          SM = ifelse(L >= max_l_theoretical & !is.na(L) & conc_num > 0, 1, SM),
          L = ifelse(L >= max_l_theoretical & !is.na(L) & conc_num > 0, max_l_theoretical, L)) %>%
        ungroup()

      # Calculate interactions
      variables <- c("L", "K", "r", "AUC")
      message("Calculating interaction scores")
      print("Reference strain:")
      print(head(reference_strain))
      reference_results <- calculate_interaction_scores(reference_strain, max_conc, variables)
      print("Deletion strains:")
      print(head(deletion_strains))
      deletion_results <- calculate_interaction_scores(deletion_strains, max_conc, variables)
      
      zscores_calculations_reference <- reference_results$calculations
      zscores_interactions_reference <- reference_results$interactions
      zscores_calculations <- deletion_results$calculations
      zscores_interactions <- deletion_results$interactions
      
      # Writing Z-Scores to file
      write.csv(zscores_calculations_reference, file = file.path(out_dir, "RF_ZScores_Calculations.csv"), row.names = FALSE)
      write.csv(zscores_calculations, file = file.path(out_dir, "ZScores_Calculations.csv"), row.names = FALSE)
      write.csv(zscores_interactions_reference, file = file.path(out_dir, "RF_ZScores_Interaction.csv"), row.names = FALSE)
      write.csv(zscores_interactions, file = file.path(out_dir, "ZScores_Interaction.csv"), row.names = FALSE)

      # Create interaction plots
      reference_plot_configs <- generate_interaction_plot_configs(df_reference, variables)
      deletion_plot_configs <- generate_interaction_plot_configs(df_deletion, variables)
      generate_and_save_plots(out_dir, "RF_interactionPlots", reference_plot_configs, grid_layout = list(ncol = 4, nrow = 3))
      generate_and_save_plots(out_dir, "InteractionPlots", deletion_plot_configs, grid_layout = list(ncol = 4, nrow = 3))

      # Define conditions for enhancers and suppressors
      # TODO Add to study config file?
      threshold <- 2
      enhancer_condition_L <- zscores_interactions$Avg_Zscore_L >= threshold
      suppressor_condition_L <- zscores_interactions$Avg_Zscore_L <= -threshold
      enhancer_condition_K <- zscores_interactions$Avg_Zscore_K >= threshold
      suppressor_condition_K <- zscores_interactions$Avg_Zscore_K <= -threshold
      
      # Subset data
      enhancers_L <- zscores_interactions[enhancer_condition_L, ]
      suppressors_L <- zscores_interactions[suppressor_condition_L, ]
      enhancers_K <- zscores_interactions[enhancer_condition_K, ]
      suppressors_K <- zscores_interactions[suppressor_condition_K, ]
      
      # Save enhancers and suppressors
      message("Writing enhancer/suppressor csv files")
      write.csv(enhancers_L, file = file.path(out_dir, "ZScores_Interaction_Deletion_Enhancers_L.csv"), row.names = FALSE)
      write.csv(suppressors_L, file = file.path(out_dir, "ZScores_Interaction_Deletion_Suppressors_L.csv"), row.names = FALSE)
      write.csv(enhancers_K, file = file.path(out_dir, "ZScores_Interaction_Deletion_Enhancers_K.csv"), row.names = FALSE)
      write.csv(suppressors_K, file = file.path(out_dir, "ZScores_Interaction_Deletion_Suppressors_K.csv"), row.names = FALSE)
      
      # Combine conditions for enhancers and suppressors
      enhancers_and_suppressors_L <- zscores_interactions[enhancer_condition_L | suppressor_condition_L, ]
      enhancers_and_suppressors_K <- zscores_interactions[enhancer_condition_K | suppressor_condition_K, ]
      
      # Save combined enhancers and suppressors
      write.csv(enhancers_and_suppressors_L,
        file = file.path(out_dir, "ZScores_Interaction_Deletion_Enhancers_and_Suppressors_L.csv"), row.names = FALSE)
      write.csv(enhancers_and_suppressors_K,
        file = file.path(out_dir, "ZScores_Interaction_Deletion_Enhancers_and_Suppressors_K.csv"), row.names = FALSE)
      
      # Handle linear model based enhancers and suppressors
      lm_threshold <- 2
      enhancers_lm_L <- zscores_interactions[zscores_interactions$Z_lm_L >= lm_threshold, ]
      suppressors_lm_L <- zscores_interactions[zscores_interactions$Z_lm_L <= -lm_threshold, ]
      enhancers_lm_K <- zscores_interactions[zscores_interactions$Z_lm_K >= lm_threshold, ]
      suppressors_lm_K <- zscores_interactions[zscores_interactions$Z_lm_K <= -lm_threshold, ]
      
      # Save linear model based enhancers and suppressors
      message("Writing linear model enhancer/suppressor csv files")
      write.csv(enhancers_lm_L,
        file = file.path(out_dir, "ZScores_Interaction_Deletion_Enhancers_L_lm.csv"), row.names = FALSE)
      write.csv(suppressors_lm_L,
        file = file.path(out_dir, "ZScores_Interaction_Deletion_Suppressors_L_lm.csv"), row.names = FALSE)
      write.csv(enhancers_lm_K,
        file = file.path(out_dir, "ZScores_Interaction_Deletion_Enhancers_K_lm.csv"), row.names = FALSE)
      write.csv(suppressors_lm_K,
        file = file.path(out_dir, "ZScores_Interaction_Deletion_Suppressors_K_lm.csv"), row.names = FALSE)

      zscores_interactions_adjusted <- adjust_missing_and_rank(zscores_interactions)
      
      rank_plot_configs <- c(
        generate_rank_plot_configs(zscores_interactions_adjusted, "Rank_L", "Avg_Zscore_L", "L"),
        generate_rank_plot_configs(zscores_interactions_adjusted, "Rank_K", "Avg_Zscore_K", "K")
      )
      generate_and_save_plots(output_dir = out_dir, file_name = "RankPlots",
        plot_configs = rank_plot_config, grid_layout = list(ncol = 3, nrow = 2))

      rank_lm_plot_config <- c(
        generate_rank_lm_plot_configs(zscores_interactions_adjusted, "Rank_lm_L", "Z_lm_L", "L"),
        generate_rank_lm_plot_configs(zscores_interactions_adjusted, "Rank_lm_K", "Z_lm_K", "K")
      )
      generate_and_save_plots(output_dir = out_dir, file_name = "RankPlots_lm",
        plot_configs = rank_lm_plot_config, grid_layout = list(ncol = 3, nrow = 2))
      
      # interaction_scores_filtered


      # lm_summaries <- lapply(lm_list, summary)
      # correlation_plot_configs <- generate_correlation_plot_configs(zscores_interactions_filtered, lm_list, lm_summaries)
      # generate_and_save_plots(zscores_interactions_filtered, output_dir, correlation_plot_configs)
    })
  })
}
main()


      # # Correlation plots
      # lm_list <- list(
      #   lm(Z_lm_K ~ Z_lm_L, data = zscores_interactions_filtered),
      #   lm(Z_lm_r ~ Z_lm_L, data = zscores_interactions_filtered),
      #   lm(Z_lm_AUC ~ Z_lm_L, data = zscores_interactions_filtered),
      #   lm(Z_lm_r ~ Z_lm_K, data = zscores_interactions_filtered),
      #   lm(Z_lm_AUC ~ Z_lm_K, data = zscores_interactions_filtered),
      #   lm(Z_lm_AUC ~ Z_lm_r, data = zscores_interactions_filtered)
      # )