| blob | 27a1a6a595e74c31888fceec0be592fd2c7cc0ad |
1 #include <assert.h>
2 #include <stdio.h>
3 #include <stdlib.h>
5 #define DEBUG
11 /* Is this ladder breaker friendly for the one who catches ladder. */
12 static bool
14 {
17 }
19 bool
21 {
26 /* Direction along border; xd is horiz. border, yd vertical. */
30 else
32 /* Direction from the border; -1 is above/left, 1 is below/right. */
36 /* | ? ?
37 * | . O #
38 * | c X #
39 * | . O #
40 * | ? ? */
41 /* This is normally caught, unless we have friends both above
42 * and below... */
46 /* ...or can't block where we need because of shortage
47 * of liberties. */
59 }
62 /* This is very trivial and gets a lot of corner cases wrong.
63 * We need this to be just very fast. One important point is
64 * that we sometimes might not notice a ladder but if we do,
65 * it should always work; thus we can use this for strong
66 * negative hinting safely. */
68 static bool
70 {
71 #define ladder_check(xd1_, yd1_, xd2_, yd2_, xd3_, yd3_) \
72 if (board_atxy(b, x, y) != S_NONE) { \
74 if (ladder_catcher(b, x, y, lcolor)) \
76 if (board_group_info(b, group_atxy(b, x, y)).lib[0] > 0) \
78 } else { \
79 /* No. So we are at new position. \
81 /* . 2 x 3 . \
82 * . x o O 1 <- only at O we can check for o at 2 \
83 * x o o x . otherwise x at O would be still deadly \
84 * o o x . . \
85 * We check for o and x at 1, these are vital. \
86 * We check only for o at 2; x at 2 would mean we \
88 coord_t c = coord_xy(b, x, y); \
89 coord_t c1 = coord_xy(b, x + (xd1_), y + (yd1_)); \
90 enum stone s1 = board_at(b, c1); \
91 if (s1 == lcolor) return false; \
92 if (s1 == stone_other(lcolor)) { \
93 /* One more thing - if the position at 3 is \
95 coord_t c3 = coord_xy(b, x + (xd3_), y + (yd3_)); \
96 return board_at(b, c3) != lcolor \
97 || board_group_info(b, group_at(b, c3)).libs < 2; \
98 } \
99 enum stone s2 = board_atxy(b, x + (xd2_), y + (yd2_)); \
100 if (s2 == lcolor) return false; \
101 if (neighbor_count_at(b, c1, lcolor) + neighbor_count_at(b, c1, S_OFFBOARD) >= 2) \
103 }
104 #define ladder_horiz do { if (DEBUGL(6)) fprintf(stderr, "%d,%d horiz step (%d,%d)\n", x, y, xd, yd); x += xd; ladder_check(xd, 0, -2 * xd, yd, 0, yd); } while (0)
105 #define ladder_vert do { if (DEBUGL(6)) fprintf(stderr, "%d,%d vert step of (%d,%d)\n", x, y, xd, yd); y += yd; ladder_check(0, yd, xd, -2 * yd, xd, 0); } while (0)
108 ladder_horiz;
110 ladder_vert;
111 ladder_horiz;
113 }
115 bool
117 {
120 /* Figure out the ladder direction */
129 }
131 /* For given (xd,yd), we have two possibilities where to move
132 * next. Consider (-1,-1):
133 * n X . n c X
134 * c O X X O #
135 * X # # . X #
136 */
140 /* We don't have to look at the other 'X' in the position - if it
141 * wouldn't be there, the group wouldn't be in atari. */
143 /* We do only tight ladders, not loose ladders. Furthermore,
144 * the ladders need to be simple:
145 * . X . . . X
146 * c O X supported . c O unsupported
147 * X # # X O #
148 */
151 /* TODO: In case of basic non-simple ladder, play out both variants. */
155 }
157 /* We do that below for further moves, but now initially - check
158 * that at 'c', we aren't putting any of the catching stones
159 * in atari. */
161 #define check_catcher_danger(b, x_, y_) do { \
162 if (board_atxy(b, (x_), (y_)) != S_OFFBOARD \
163 && board_group_info(b, group_atxy(b, (x_), (y_))).libs <= 2) { \
164 if (DEBUGL(5)) \
166 return false; \
167 } } while (0)
175 }
176 #undef check_catcher_danger
177 #endif
180 }