+ /*
+ * Next up (at the bottom) is "who's playing, what will he/she be playing, and
+ * optionally, how much to lead/win and how much to secure qualification" (the
+ * last one only in the final round). We assume playing is done in a modified
+ * zigzag; all the random songs are played first in zigzag/wrapping order (player
+ * 1 song 1, player 2 song 2, player 3 song 3, player 1 song 2, player 2 song 3,
+ * player 3 song 1, etc... assuming three songs and three players) and then all
+ * the chosen songs are played (we assume only one chosen song).
+ *
+ * The lines are as follows:
+ *
+ * <player>
+ * <song>
+ * High score: <hs> by <hsplayer> at <hsevent>
+ * Needs to lead: <leadscore>
+ * Needs to secure qualification: <qualscore>
+ * Needs to win group: <winscore>
+ */
+
+ /* Find the first player with the fewest songs played and part of this machine. */
+ unsigned min_played_songs = 9999, num_random_songs = 0;
+ Player *next_player = NULL;
+ unsigned m = 0;
+ for (std::vector<Player>::iterator i = group.players.begin(); i != group.players.end(); ++i) {
+ unsigned this_played = 0, this_random_songs = 0;
+ for (std::vector<Score>::const_iterator j = i->scores.begin(); j != i->scores.end(); ++j) {
+ if (j->score != -1)
+ ++this_played;
+ if (!j->chosen)
+ ++this_random_songs;
+ }
+
+ if ((m++ % num_machines == machine) && this_played < min_played_songs) {
+ min_played_songs = this_played;
+ next_player = &(*i);
+ num_random_songs = this_random_songs; // should be equal for all
+ }
+ }
+
+ /* Find out what song this player is supposed to play next; try random songs first */
+ Score *next_song = NULL;
+
+ for (unsigned i = 0; i < num_random_songs; ++i) {
+ unsigned j = (i + next_player->position - 1) % num_random_songs;
+ if (next_player->scores[j].score == -1) {
+ next_song = &(next_player->scores[j]);
+ break;
+ }
+ }
+
+ // then all songs, if that didn't work out (slightly icky, but hey)
+ if (next_song == NULL) {
+ for (unsigned i = 0; i < num_scores; ++i) {
+ unsigned j = (i + next_player->position) % num_scores;
+ if (next_player->scores[j].score == -1) {
+ next_song = &(next_player->scores[j]);
+ break;
+ }
+ }
+ }
+
+ if (next_song != NULL) {
+ widestring text = widestring("Next player: ") + next_player->nick;
+ unsigned this_width = my_draw_text(text, NULL, 24.0);
+ my_draw_text(text, buf, 24.0, (LOGICAL_SCREEN_WIDTH/2) - this_width/2, 420);
+
+ if (next_song->song.id != -1) {
+ this_width = my_draw_text(next_song->song.title, NULL, 20.0);
+ my_draw_text(next_song->song.title, buf, 20.0, (LOGICAL_SCREEN_WIDTH/2) - this_width/2, 457);
+
+ Highscore hs;
+ conn.perform(FetchHighscore(next_song->song.id, &hs));
+
+ if (hs.score != -1) {
+ text = widestring("High score: ") + widestring(pqxx::to_string(hs.score)) +
+ widestring(", by ") + hs.nick + widestring(" in ") + hs.tournament_name;
+ this_width = my_draw_text(text, NULL, 16.0);
+ my_draw_text(text, buf, 16.0, (LOGICAL_SCREEN_WIDTH/2) - this_width/2, 487);
+ }
+ }
+
+ // only show lead/win/qualify for the last song
+ if (min_played_songs == num_scores - 1) {
+ /*
+ * Find out how much we need to lead, how much we need to be guaranteed
+ * to win the group, and how much we need to secure qualification. (FIXME:
+ * do the last one :-) )
+ */
+
+ // find the best score we can get
+ unsigned max_score_this_song;
+ if (next_song->song.id != -1) {
+ // random song, or we know what song the player picked
+ max_score_this_song = song_scores[next_song->song.id];
+ } else {
+ max_score_this_song = player_scores[next_player->id];
+ }
+
+ unsigned y = 520;
+
+ // see what score this player must beat to lead
+ unsigned lead_beat = 0, win_beat = 0;
+ for (unsigned i = 0; i < group.players.size(); ++i) {
+ if (group.players[i].id == next_player->id)
+ continue;
+
+ lead_beat = std::max(lead_beat, group.players[i].total);
+ }
+
+ // find the best max score among the others
+ for (unsigned i = 0; i < group.players.size(); ++i) {
+ if (group.players[i].id == next_player->id)
+ continue;
+
+ win_beat = std::max(win_beat, max_score[i]);
+ }
+
+ /*
+ * There's a somewhat subtle point here. Normally, what a player would be interested in
+ * with regard to qualification would be a set of three values:
+ *
+ * 1. How much is the absolute minimum required to qualify, given that all others
+ * fail?
+ * 2. How much will give a reasonable chance of qualifying, given the expected performance
+ * of all the others?
+ * 3. How much will be enough to secure qualification, no matter what?
+ *
+ * Given perfect guessing, #2 would be "how much is needed to qualify"; however, it is
+ * completely impossible to give an exact value for that, and we're not into the guessing
+ * games. :-) #1 is often so low it's completely unrealistic (ie. far enough from #2 that
+ * it's not interesting), but #3, the most conservative estimate, is often a good measure.
+ * #3 is "how much is needed to _secure_ qualification", and that is usually what we
+ * print out when it's possible.
+ *
+ * However, in a few situations, #1 and #3 will be the exact same value, from which it
+ * follows (from the squeeze law, or just common sense :-) ) that #2 will be the same
+ * value as #1 and #3. (This usually happens near or at the end of a group.) In that
+ * case, we know the value we seek (ie. "how much is needed to qualify"), so we drop
+ * the word "secure" and just print it as-is.
+ *
+ * To find #1 and #3, we sort and pick out the values we need to beat in the best and
+ * the worst case.
+ */
+ int qualify_beat_worst_case = -1, qualify_beat_best_case = -1;
+
+ if (group.num_qualifying > 0) {
+ std::vector<unsigned> tmp;
+
+ for (unsigned i = 0; i < group.players.size(); ++i) {
+ if (group.players[i].id == next_player->id)
+ continue;
+ tmp.push_back(max_score[i]);
+ }
+ std::sort(tmp.begin(), tmp.end());
+ qualify_beat_worst_case = tmp[tmp.size() - group.num_qualifying];
+
+ std::vector<unsigned> tmp2;
+ for (unsigned i = 0; i < group.players.size(); ++i) {
+ if (group.players[i].id == next_player->id)
+ continue;
+ tmp2.push_back(min_score[i]);
+ }
+
+ std::sort(tmp2.begin(), tmp2.end());
+ qualify_beat_best_case = tmp2[tmp2.size() - group.num_qualifying];
+ }
+
+ // print out the lines we can attain
+ if (next_player->total + max_score_this_song > lead_beat && (lead_beat != win_beat)) {
+ int lead_need = std::max(lead_beat - next_player->total + 1, 0U);
+
+ if (lead_need > 0) {
+ text = widestring("Needs to lead: ") + widestring(pqxx::to_string(lead_need));
+ this_width = my_draw_text(text, NULL, 18.0);
+ my_draw_text(text, buf, 18.0, (LOGICAL_SCREEN_WIDTH/2) - this_width/2, y);
+
+ y += 30;
+ }
+ }
+
+ if (next_player->total + max_score_this_song > win_beat) {
+ int win_need = std::max(win_beat - next_player->total + 1, 0U);
+
+ if (win_need > 0) {
+ text = widestring("Needs to win: ") + widestring(pqxx::to_string(win_need));
+
+ this_width = my_draw_text(text, NULL, 18.0);
+ my_draw_text(text, buf, 18.0, (LOGICAL_SCREEN_WIDTH/2) - this_width/2, y);
+
+ y += 30;
+ }
+ }
+
+ if (group.num_qualifying > 0 &&
+ next_player->total + max_score_this_song > unsigned(qualify_beat_worst_case) &&
+ (unsigned(qualify_beat_worst_case) != win_beat)) {
+ int qual_need = std::max(qualify_beat_worst_case - next_player->total + 1, 0U);
+
+ if (qual_need > 0) {
+ if (qualify_beat_worst_case == qualify_beat_best_case) {
+ text = widestring("Needs to qualify: ") + widestring(pqxx::to_string(qual_need));
+ } else {
+ text = widestring("Needs to secure qualification: ") + widestring(pqxx::to_string(qual_need));
+ }
+
+ this_width = my_draw_text(text, NULL, 18.0);
+ my_draw_text(text, buf, 18.0, (LOGICAL_SCREEN_WIDTH/2) - this_width/2, y);
+
+ y += 30;
+ }
+ }
+ }
+ }
+