+ return ones;
+}
+
+/* Find the category to which an item belongs. */
+static category_t *
+mnemon_item_category (mnemon_t *mnemon,
+ item_t *item)
+{
+ category_t *category;
+ int i, item_index;
+
+ for (i = 0; i < mnemon->num_categories; i++) {
+ category = &mnemon->categories[i];
+ item_index = item - category->items;
+ if (item_index >= 0 && item_index < category->num_items)
+ return category;
+ }
+
+ assert (0);
+}
+
+typedef struct _item_in_category_closure
+{
+ mnemon_t *mnemon;
+ category_t *category;
+} item_in_category_closure_t;
+
+static int
+mnemon_item_in_category (void *closure, item_t *item)
+{
+ item_in_category_closure_t *iicc = closure;
+ mnemon_t *mnemon = iicc->mnemon;
+ category_t *category = iicc->category;
+
+ return (mnemon_item_category (mnemon, item) == category);
+}
+
+typedef struct _item_in_category_of_length_closure
+{
+ mnemon_t *mnemon;
+ category_t *category;
+ int length;
+} item_in_category_of_length_closure_t;
+
+static int
+mnemon_item_in_category_of_length (void *closure, item_t *item)
+{
+ item_in_category_of_length_closure_t *iicolc = closure;
+ mnemon_t *mnemon = iicolc->mnemon;
+ category_t *category = iicolc->category;
+ int length = iicolc->length;
+
+ if (mnemon_item_category (mnemon, item) != category)
+ return 0;
+
+ return strlen (item->challenge) == length;
+}
+
+static void
+mnemon_select_item (mnemon_t *mnemon,
+ bin_t **bin_ret,
+ int *item_index_ret,
+ category_t **category_ret)
+{
+ int bin_index, item_index;
+ bin_t *bin;
+ item_t *item;
+ category_t *category;
+
+ bin_index = rand_within_exponential (mnemon->num_bins);
+ bin = &mnemon->bins[bin_index];
+
+ /* The most intuitive understanding of the to_introduce counter is
+ * that it's tracking never-before-learned items as they are
+ * pulled from the bin with score 0. But that bin can become
+ * empty. So the refined rule is that we decrement to_introduce
+ * whenever we pull from the lowest-indexed bin with a
+ * non-negative score. */
+ if (mnemon->to_introduce && bin->score >=0 &&
+ (bin_index == 0 || mnemon->bins[bin_index-1].score < 0))
+ {
+ mnemon->to_introduce--;
+ }
+
+ item_index = rand_within (bin->num_items);
+
+ item = bin->items[item_index];
+ category = mnemon_item_category (mnemon, item);
+
+ if (bin->score == 0) {
+ if (category->order == CATEGORY_ORDER_SEQUENTIAL) {
+ item = category_next_bin_zero_item (category);
+ if (item)
+ item_index = bin_item_index (bin, item);
+ }
+ }
+
+ *bin_ret = bin;
+ *item_index_ret = item_index;
+ *category_ret = category;
+}
+
+
+#define HISTOGRAM_ROW_FORMAT "%3d: %3d"
+#define HISTOGRAM_BAR_WIDTH 63
+
+static void
+print_histogram_bar (double size,
+ double max)
+{
+ int units_per_cell = (int) ceil (max / HISTOGRAM_BAR_WIDTH);
+ static char const *boxes[8] = {
+ "█", "▉", "▊", "▋",
+ "▌", "▍", "▎", "▏"
+ };
+
+ while (size > units_per_cell) {
+ printf(boxes[0]);
+ size -= units_per_cell;
+ }
+
+ size /= units_per_cell;
+
+ if (size > 7.5/8.0)
+ printf(boxes[0]);
+ else if (size > 6.5/8.0)
+ printf(boxes[1]);
+ else if (size > 5.5/8.0)
+ printf(boxes[2]);
+ else if (size > 4.5/8.0)
+ printf(boxes[3]);
+ else if (size > 3.5/8.0)
+ printf(boxes[4]);
+ else if (size > 2.5/8.0)
+ printf(boxes[5]);
+ else if (size > 1.5/8.0)
+ printf(boxes[6]);
+ else if (size > 0.5/8.0)
+ printf(boxes[7]);
+
+ printf ("\n");
+}
+
+static void
+mnemon_print_histogram (mnemon_t *mnemon,
+ const char *category_name,
+ int length)
+{
+ int i, last_score, max;
+ category_t *category = NULL;
+ bin_t *bin;
+ int num_items;
+ item_match_predicate_t *predicate = NULL;
+ void *closure = NULL;
+ item_in_category_closure_t item_in_category;
+ item_in_category_of_length_closure_t item_in_category_of_length;
+
+ if (mnemon->num_bins == 0)
+ return;
+
+ if (category_name) {
+ category = mnemon_get_category_if_exists (mnemon, category_name);
+ if (category) {
+ if (length) {
+ predicate = mnemon_item_in_category_of_length;
+ item_in_category_of_length.mnemon = mnemon;
+ item_in_category_of_length.category = category;
+ item_in_category_of_length.length = length;
+ closure = &item_in_category_of_length;
+ } else {
+ predicate = mnemon_item_in_category;
+ item_in_category.mnemon = mnemon;
+ item_in_category.category = category;
+ closure = &item_in_category;
+ }
+ }
+ }
+
+ for (i = 0; i < mnemon->num_bins; i++) {
+ num_items = bin_num_items_matching (&mnemon->bins[i],
+ predicate, closure);
+ if (i == 0 || num_items > max)
+ max = num_items;
+ }
+
+ for (i = 0; i < mnemon->num_bins; i++) {
+ bin = &mnemon->bins[i];
+ if (i != 0)
+ while (bin->score - last_score > 1)
+ printf (HISTOGRAM_ROW_FORMAT "\n", ++last_score, 0);
+ num_items = bin_num_items_matching (bin,
+ predicate, closure);
+ printf (HISTOGRAM_ROW_FORMAT " ", bin->score, num_items);
+ print_histogram_bar (num_items, max);
+ last_score = bin->score;
+ }
+}
+
+static void
+mnemon_handle_command (mnemon_t *mnemon,
+ const char *command)
+{
+ const char *arg;
+ int len;
+ switch (command[0]) {
+ case 'h':
+ {
+ char *category = NULL;
+ int length = 0;
+
+ arg = command + 1;
+ arg += strspn (arg, " \t");
+ len = strcspn (arg, " \t");
+ if (len) {
+ category = xstrndup (arg, len);
+ arg += len;
+ arg += strspn (arg, " \t");
+ if (*arg)
+ length = atoi (arg);
+ }
+ mnemon_print_histogram (mnemon, category, length);
+ }
+ break;
+ default:
+ printf ("Unknown command: %s\n", command);
+ break;
+ }
+}
+
+static void
+mnemon_handle_response (mnemon_t *mnemon,
+ bin_t *bin,
+ int item_index,
+ item_t *item,
+ const char *response,
+ double response_time,
+ double time_limit)
+{
+ bool_t correct;
+
+ correct = (strcmp (response, item->response) == 0);
+
+ bin_remove_item (bin, item_index);
+
+ /* If the bin is now empty, we must remove it. Also if we just
+ * picked the last word we'll ever pick from the bin with
+ * score 0, then we can remove that as well. */
+ if (bin->num_items == 0 ||
+ (bin->score == 0 && mnemon->to_introduce == 0))
+ {
+ mnemon_remove_bin (mnemon, bin);
+ }
+
+ if (correct &&
+ (time_limit == 0.0 || response_time < time_limit))
+ {
+ item->score++;
+ mnemon->to_master--;
+ /* We reserve an item score of 0 for an item that has
+ * never been asked. */
+ if (item->score == 0) {
+ item->score = 1;
+ mnemon->unlearned--;
+ mnemon->to_master--;
+ printf ("You got it!");
+ } else if (item->score < 0) {
+ printf ("Yes---just give me %d more.",
+ - item->score);
+ } else if (item->score == 1) {
+ printf ("On your first try, no less!");
+ } else {
+ printf ("Masterful (%dx).", item->score);
+ }
+ } else {
+ if (! correct)
+ printf (" %s is the correct answer.",
+ item->response);
+ else
+ printf ("Correct, but not quite quick enough (%0.2f seconds---needed %0.2f seconds)\n",
+ response_time, time_limit);
+ /* Penalize an incorrect response by forcing the score
+ * negative. */
+ if (item->score >= 0) {
+ if (item->score > 0)
+ printf (" Oops, you knew that, right? (%dx)\n ",
+ item->score);
+ mnemon->unlearned++;
+ /* We add three here, (rather than just 2 to track the
+ * change in the item's score below), as an extra
+ * penalty. If the user is forgetting stuff learned
+ * previously, then more time should be spent on mastering
+ * than learning new items. */
+ mnemon->to_master += item->score + 3;
+ /* We go to -2 to force a little extra reinforcement
+ * when re-learning an item, (otherwise, it will often
+ * get asked again immediately where it is easy to get
+ * a correct response without any learning). */
+ item->score = -2;
+ } else {
+ item->score--;
+ mnemon->to_master++;
+ }
+ }
+
+ printf (" ");
+ if (mnemon->to_introduce)
+ printf ("%d to come. ", mnemon->to_introduce);
+ if (mnemon->unlearned)
+ printf ("%d still unlearned. ", mnemon->unlearned);
+ if (mnemon->to_introduce == 0 && mnemon->to_master > 0)
+ printf ("%d items to master", mnemon->to_master);
+ printf ("\n\n");
+
+ bin = mnemon_get_bin (mnemon, item->score);
+
+ bin_add_item (bin, item);
+}
+
+static void
+mnemon_do_challenges (mnemon_t *mnemon)
+{
+ bin_t *bin;
+ int item_index;
+ item_t *item;
+ category_t *category;
+ char *response;
+ int i;
+
+ /* Count the number of items with negative scores. */
+ mnemon->unlearned = 0;
+ for (i = 0; i < mnemon->num_bins; i++) {
+ bin = &mnemon->bins[i];
+ if (bin->score >= 0)
+ break;
+ mnemon->unlearned += bin->num_items;
+ }
+
+ mnemon->to_introduce -= mnemon->unlearned;
+ if (mnemon->to_introduce < 0)
+ mnemon->to_introduce = 0;
+
+ /* Get rid of bin with score of 0 if we aren't going to be
+ * introducing anything from it. */
+ if (mnemon->to_introduce == 0) {
+ bin = mnemon_get_bin (mnemon, 0);
+ mnemon_remove_bin (mnemon, bin);
+ }
+
+ if (mnemon->unlearned) {
+ printf ("You've got %d items to learn already. ", mnemon->unlearned);
+ if (mnemon->to_introduce)
+ printf ("I'll introduce %d more as we go.", mnemon->to_introduce);
+ printf ("\n");
+ } else {
+ printf ("Introducing %d new items.\n", mnemon->to_introduce);
+ }
+ printf ("\n");
+
+ do {
+ struct timeval start, end;
+
+ mnemon_select_item (mnemon, &bin, &item_index, &category);
+ item = bin->items[item_index];
+
+ while (1) {
+ if (category->time_limit > 0.0) {
+ response = readline ("The next one is timed. Press enter when ready:");
+ free (response);
+ }
+
+ printf ("%s\n", item->challenge);
+
+ gettimeofday (&start, NULL);
+ response = readline ("> ");
+ gettimeofday (&end, NULL);
+
+ /* Terminate on EOF */
+ if (response == NULL) {
+ printf ("\n");
+ return;
+ }
+
+ if (response[0] == '/') {
+ mnemon_handle_command (mnemon, response + 1);
+ free (response);
+ } else {
+ break;
+ }
+ }
+
+ mnemon_handle_response (mnemon, bin, item_index,
+ item, response,
+ (end.tv_sec + end.tv_usec / 1e6) -
+ (start.tv_sec + start.tv_usec / 1e6),
+ category->time_limit);
+ free (response);
+ } while (mnemon->to_introduce ||
+ mnemon->unlearned ||
+ mnemon->to_master > 0);