Simulations pour Lola

simulation_RL_V2.R

@@ -43,6 +43,255 @@ options <- list(
   ) # Vulnerable
 )
 
+#' This function is the actual runner for the simulation with the params
+#' provided by other functions that will prepare the parameters to be run by
+#' this one
+simulation_runner_RL <- function(n_choices, options, params, model_name = "undefined") {
+  # Nombre d'options
+  n_arms <- length(options)
+
+  # Initialisation
+  Q_values <- rep(0, n_arms)
+  Q_values_history <- matrix(NA_real_, nrow = n_choices, ncol = n_arms)
+  colnames(Q_values_history) <- paste0("Q", seq_len(n_arms))
+
+  choices_history <- integer(n_choices)
+  rewards_history <- numeric(n_choices)
+  probs_history <- matrix(NA_real_, nrow = n_choices, ncol = n_arms)
+  colnames(probs_history) <- paste0("p", seq_len(n_arms))
+
+  # Récupération des paramètres depuis la liste params
+  alphas <- params$alphas
+  forgets <- params$forgets
+  lambdas <- params$lambdas
+  rhos <- params$rhos
+
+  # Normaliser les formats: si scalar, étendre à n_arms
+  expand_param <- function(x, default = 0) {
+    if (is.null(x)) {
+      return(rep(default, n_arms))
+    }
+    if (length(x) == 1) {
+      return(rep(unname(x), n_arms))
+    }
+    if (!is.null(names(x)) && all(grepl("^lambda_?", names(x)))) {
+      # ordered lambda_1..lambda_n
+      v <- as.numeric(x)
+      return(v[1:n_arms])
+    }
+    return(as.numeric(x)[1:n_arms])
+  }
+
+  lambda_vec <- expand_param(lambdas, default = 1)
+
+  # forgets may be named 'forget' or per-arm
+  forget_vec <- expand_param(forgets, default = 0)
+
+  # Alphas more complexe: can be a single 'alpha', two (alpha_loss, alpha_gain) or vectors per arm
+  # We store separate gain and loss vectors for easy lookup
+  if (!is.null(alphas)) {
+    if (!is.null(names(alphas)) && "alpha" %in% names(alphas) && length(alphas) == 1) {
+      alpha_gain_vec <- alpha_loss_vec <- rep(unname(alphas["alpha"]), n_arms)
+    } else if (!is.null(names(alphas)) && all(c("alpha_loss", "alpha_gain") %in% names(alphas)) && length(alphas) == 2) {
+      alpha_loss_vec <- rep(unname(alphas["alpha_loss"]), n_arms)
+      alpha_gain_vec <- rep(unname(alphas["alpha_gain"]), n_arms)
+    } else if (!is.null(names(alphas)) && any(grepl("^alpha_gain", names(alphas)))) {
+      # per-arm alpha_gain_1..4 and alpha_loss_1..4
+      # fallback to numeric
+      alpha_gain_vec <- expand_param(alphas[grepl("gain", names(alphas))], default = 0.1)
+      alpha_loss_vec <- expand_param(alphas[grepl("loss", names(alphas))], default = 0.1)
+    } else if (length(alphas) == n_arms) {
+      # assume same for gain and loss if vector provided
+      alpha_gain_vec <- alpha_loss_vec <- as.numeric(alphas)
+    } else {
+      alpha_gain_vec <- alpha_loss_vec <- rep(as.numeric(alphas[1]), n_arms)
+    }
+  } else {
+    alpha_gain_vec <- alpha_loss_vec <- rep(0.1, n_arms)
+  }
+
+  # rhos: named vector with rho_BS and rho_JP optionally
+  rho_JP_val <- 0
+  rho_BS_val <- 0
+  if (!is.null(rhos)) {
+    if (!is.null(names(rhos)) && "rho_JP" %in% names(rhos)) rho_JP_val <- as.numeric(rhos["rho_JP"])
+    if (!is.null(names(rhos)) && "rho_BS" %in% names(rhos)) rho_BS_val <- as.numeric(rhos["rho_BS"])
+  }
+
+  # Simulation loop
+  for (t in seq_len(n_choices)) {
+    # Compute subjective values
+    V_values <- lambda_vec * Q_values
+
+    # Add rhos according to the simulation file option mapping:
+    # option1 = Antifragile (JP possible)
+    # option2 = Robust
+    # option3 = Fragile (BS possible)
+    # option4 = Vulnerable (both)
+    if (!is.null(rhos)) {
+      V_values[1] <- V_values[1] + rho_JP_val
+      if (n_arms >= 3) V_values[3] <- V_values[3] + rho_BS_val
+      if (n_arms >= 4) V_values[4] <- V_values[4] + rho_BS_val + rho_JP_val
+    }
+
+    # Softmax (numerical stability)
+    V_max <- max(V_values)
+    exp_V <- exp(V_values - V_max)
+    probs <- exp_V / sum(exp_V)
+    probs <- pmax(probs, 1e-10)
+    probs <- probs / sum(probs)
+
+    # Draw choice
+    choice <- sample(seq_len(n_arms), size = 1, prob = probs)
+
+    # Draw reward according to option structure
+    opt <- options[[choice]]
+    u <- runif(1)
+    jp_p <- ifelse(is.null(opt$p_jp), 0, opt$p_jp)
+    bs_p <- ifelse(is.null(opt$p_bs), 0, opt$p_bs)
+
+    if (u < jp_p) {
+      reward <- ifelse(is.null(opt$jp), 0, opt$jp)
+    } else if (u < jp_p + bs_p) {
+      reward <- ifelse(is.null(opt$bs), 0, opt$bs)
+    } else {
+      # normal outcome: either gain or loss
+      if (runif(1) < 0.5) {
+        reward <- opt$gain[t]
+      } else {
+        reward <- opt$loss[t]
+      }
+    }
+
+    # Record probabilities, choice and reward
+    probs_history[t, ] <- probs
+    choices_history[t] <- choice
+    rewards_history[t] <- reward
+
+    # Select learning rate
+    if (reward >= 0) {
+      alpha_used <- alpha_gain_vec[choice]
+    } else {
+      alpha_used <- alpha_loss_vec[choice]
+    }
+
+    # Q update
+    prediction_error <- reward - Q_values[choice]
+    Q_values[choice] <- Q_values[choice] + alpha_used * prediction_error
+
+    # Forgetting for non-chosen arms
+    not_chosen <- setdiff(seq_len(n_arms), choice)
+    Q_values[not_chosen] <- Q_values[not_chosen] * (1 - forget_vec[not_chosen])
+
+    # Save Q history (after update)
+    Q_values_history[t, ] <- Q_values
+  }
+
+  # Convert histories to data.frame for output
+  choices_df <- tibble::tibble(
+    trial = seq_len(n_choices),
+    choice = choices_history,
+    reward = rewards_history
+  )
+
+  probs_df <- as.data.frame(probs_history)
+  probs_df$trial <- seq_len(n_choices)
+
+  Q_history_df <- as.data.frame(Q_values_history)
+  Q_history_df$trial <- seq_len(n_choices)
+
+  # Calcul de la proportion cumulée des choix pour chaque option au cours du temps
+  proportions_data <- data.frame(
+    Iteration = 1:n_choices,
+    Antifragile = cumsum(choices_history == 1) / 1:n_choices,
+    Robust = cumsum(choices_history == 2) / 1:n_choices,
+    Fragil = cumsum(choices_history == 3) / 1:n_choices,
+    Vulnerable = cumsum(choices_history == 4) / 1:n_choices
+  )
+
+  result <- list(
+    model = model_name,
+    params = params,
+    choices = choices_df,
+    probs = probs_df,
+    Q_history = Q_history_df,
+    proportions_data = proportions_data
+  )
+
+  return(result)
+}
+
+simulation_homogeneous_RL <- function(n_choices, options, alpha, forget, lambda) {
+  # Preparing the param list for the simulation runner
+  params <- list(
+    alphas = c("alpha" = alpha),
+    forgets = c("forget" = forget),
+    lambdas = c("lambda" = lambda)
+  )
+
+  results <- simulation_runner_RL(n_choices = n_choices, options = options, params = params, model_name = "HOMOGENEOUS")
+  return(results)
+}
+
+simulation_gain_loss_RL <- function(n_choices, options, alpha_loss, alpha_gain, forget, lambda) {
+  params <- list(
+    alphas = c("alpha_loss" = alpha_loss, "alpha_gain" = alpha_gain),
+    forgets = c("forget" = forget),
+    lambdas = c("lambda" = lambda)
+  )
+  results <- simulation_runner_RL(n_choices = n_choices, options = options, params = params, model_name = "GAIN_LOSS")
+  return(results)
+}
+
+simulation_biased_RL <- function(n_choices, options, alpha_loss, alpha_gain, forgets_vec, lambdas_vec) {
+  params <- list(
+    alphas = c("alpha_loss" = alpha_loss, "alpha_gain" = alpha_gain),
+    forgets = lambdas_vec, # here user may pass full vector as forgets_vec
+    lambdas = lambdas_vec
+  )
+  results <- simulation_runner_RL(n_choices = n_choices, options = options, params = params, model_name = "BIASED")
+  return(results)
+}
+
+simulation_ree_biased_simple_RL <- function(
+    n_choices,
+    options,
+    alpha_l, alpha_g,
+    rho_BS, rho_JP,
+    forget, lambda) {
+  # Preparing the param list for the simulation runner
+  params <- list(
+    alphas = c("alpha_loss" = alpha_l, "alpha_gain" = alpha_g),
+    forgets = c("forget" = forget),
+    lambdas = c("lambda" = lambda),
+    rhos = c("rho_BS" = rho_BS, "rho_JP" = rho_JP)
+  )
+
+  results <- simulation_runner_RL(n_choices = n_choices, options = options, params = params, model_name = "REE_BIASED_SIMPLE")
+  return(results)
+}
+
+simulation_ree_learning_simple_RL <- function(n_choices, options, alpha1, alpha2, alpha3, alpha4, forget, lambda) {
+  params <- list(
+    alphas = c(alpha1, alpha2, alpha3, alpha4),
+    forgets = c("forget" = forget),
+    lambdas = c("lambda" = lambda)
+  )
+  results <- simulation_runner_RL(n_choices = n_choices, options = options, params = params, model_name = "REE_LEARNING_SIMPLE")
+  return(results)
+}
+
+simulation_ree_learning_biased_simple_RL <- function(n_choices, options, alpha1, alpha2, alpha3, alpha4, forget, lambda, rho_BS, rho_JP) {
+  params <- list(
+    alphas = c(alpha1, alpha2, alpha3, alpha4),
+    forgets = c("forget" = forget),
+    lambdas = c("lambda" = lambda),
+    rhos = c("rho_BS" = rho_BS, "rho_JP" = rho_JP)
+  )
+  results <- simulation_runner_RL(n_choices = n_choices, options = options, params = params, model_name = "REE_LEARNING_BIASED_SIMPLE")
+  return(results)
+}
+
 simulation_agentRL <- function(alpha_g, alpha_l, lambda_g, lambda_l, fg, fl, n_choices, options) {
   # Initialisation des Q-values pour chaque option (gains et pertes séparés)
   Q1_gain <- 0
@@ -196,45 +445,83 @@ simulation_agentRL <- function(alpha_g, alpha_l, lambda_g, lambda_l, fg, fl, n_c
   return(result)
 }
 
+compute_TSREE <- function(proportions_data) {
+  TSREE <- 1 + proportions_data$Antifragile - proportions_data$Fragil
+  return(TSREE)
+}
+
+compute_OSSREE <- function(proportions_data) {
+  OSSREE <- proportions_data$Vulnerable - proportions_data$Robust
+  return(OSSREE)
+}
+
+plot_TSREE_OSSREE <- function(proportions_data) {
+  OSSREE <- compute_OSSREE(proportions_data)
+  TSREE <- compute_TSREE(proportions_data)
+  plot(OSSREE, TSREE,
+    col = "darkblue", cex = 2, xlim = c(-1, 1), ylim = c(0, 2), type = "l",
+    xlab = "OSSREE", ylab = "TSREE", main = "Evolution of TSREE and OSSREE over trials"
+  )
+  lines(c(0, 1, 0, -1, 0), c(0, 1, 2, 1, 0))
+  lines(c(0, 0), c(0, 2), lty = 2)
+  lines(c(-1, 1), c(1, 1), lty = 2)
+}
+
+plot_mean_TSREE_OSSREE_one_agent <- function(proportions_data) {
+  OSSREE <- compute_OSSREE(proportions_data)
+  TSREE <- compute_TSREE(proportions_data)
+  mean_OSSREE <- mean(OSSREE)
+  mean_TSREE <- mean(TSREE)
+  plot(mean_OSSREE, mean_TSREE,
+    col = "purple", cex = 2, pch = "+", xlim = c(-1, 1), ylim = c(0, 2), type = "p",
+    xlab = "OSSREE", ylab = "TSREE", main = "Mean TSREE and OSSREE over trials"
+  )
+  lines(c(0, 1, 0, -1, 0), c(0, 1, 2, 1, 0))
+  lines(c(0, 0), c(0, 2), lty = 2)
+  lines(c(-1, 1), c(1, 1), lty = 2)
+}
+
+plot_choices_proportions <- function(proportions_data) {
+  # Conversion des données pour ggplot
+  proportions_long <- reshape2::melt(proportions_data,
+    id.vars = "Iteration",
+    variable.name = "Option", value.name = "Proportion"
+  )
+
+  # Tracé du graphique
+  ggplot(proportions_long, aes(x = Iteration, y = Proportion, color = Option)) +
+    geom_line(size = 1.2) +
+    labs(
+      title = "Proportion of simulated choices through trials",
+      x = "trials",
+      y = "Proportion of choices"
+    ) +
+    scale_color_manual(values = c(
+      "Antifragile" = "blue", "Robust" = "red",
+      "Fragil" = "green", "Vulnerable" = "purple"
+    )) +
+    theme_minimal() +
+    theme(legend.title = element_blank())
+}
+
 #### pour un agent RL
-result <- simulation_agentRL(alpha_g, alpha_l, lambda_g, lambda_l, fg, fl, n_choices, options)
-proportions_data <- result$proportions_data
-# Conversion des données pour ggplot
-proportions_long <- reshape2::melt(proportions_data,
-  id.vars = "Iteration",
-  variable.name = "Option", value.name = "Proportion"
+result <- simulation_ree_learning_biased_simple_RL(
+  n_choices = n_choices,
+  options = options, alpha1 = 0.5, alpha2 = 0.5, alpha3 = 0.5, alpha4 = 0.5, forget = 0.1, lambda = 1, rho_BS = 0, rho_JP = 0
 )
 
-# Tracé du graphique
-ggplot(proportions_long, aes(x = Iteration, y = Proportion, color = Option)) +
-  geom_line(size = 1.2) +
-  labs(
-    title = "Proportion of simulated choices through trials",
-    x = "trials",
-    y = "Proportion of choices"
-  ) +
-  scale_color_manual(values = c(
-    "Antifragile" = "blue", "Robust" = "red",
-    "Fragil" = "green", "Vulnerable" = "purple"
-  )) +
-  theme_minimal() +
-  theme(legend.title = element_blank())
+proportions_data <- result$proportions_data
+plot_TSREE_OSSREE(proportions_data)
+plot_mean_TSREE_OSSREE_one_agent(proportions_data)
+plot_choices_proportions(proportions_data)
+
 
 ### pour plusieurs agents RL
 
-n_agent <- 100
+n_agent <- 1000
 
 result_multi_agent <- lapply(1:n_agent, function(i) {
-  # Paramètres d'apprentissage (indépendants pour chaque option)
-  alpha_g <- rep(0.9, 4) # Taux d'apprentissage pour les gains (pour chaque option)
-  alpha_l <- rep(0.9, 4) # Taux d'apprentissage pour les pertes (pour chaque option)
-  lambda_g <- rep(1, 4) # Poids pour les gains (individuel pour chaque option)
-  lambda_l <- rep(1, 4) # Poids pour les pertes (individuel pour chaque option)
-  fg <- rep(0.9, 4) # Facteurs d'oubli gains (spécifique pour chaque option) remplace les alpha pour les options non choisi
-  fl <- rep(0.9, 4) # Facteurs d'oubli pertes (spécifique pour chaque option) remplace les alpha pour les options non choisi
-
-  n_choices <- 1000 # Nombre total de choix
-
+  n_choices <- 400 # Nombre total de choix
   # Paramètres des options (récompenses)
   options <- list(
     option1 = list(
@@ -258,10 +545,12 @@ result_multi_agent <- lapply(1:n_agent, function(i) {
       jp = 3000, bs = -3000, p_jp = 0.05, p_bs = 0.05
     )
   )
-
-  result <- simulation_agentRL(alpha_g, alpha_l, lambda_g, lambda_l, fg, fl, n_choices, options)
-  result$parameters <- list(alpha_g = alpha_g, alpha_l = alpha_l, lambda_g = lambda_g, lambda_l = lambda_l, fg = fg, fl = fl)
-  result$option <- options
+  result <- simulation_ree_learning_biased_simple_RL(
+    n_choices = n_choices,
+    options = options,
+    alpha1 = 0.5, alpha2 = 0.5, alpha3 = 0.5, alpha4 = 0.5,
+    forget = 0.2, lambda = 2, rho_BS = -1, rho_JP = 1
+  )
 
   return(result)
 })