#include #include #include #include "snake.h" #define ASSERT_RET(x, ret) \ do{ \ if (x) \ return ret; \ }while(0) rt_list_t snake_head; SNAKE_DIR prevdir; static SNAKE_DIR dir_adjust(SNAKE_DIR dir) { if ( (SNAKE_DIR_UP == prevdir && SNAKE_DIR_DOWN != dir) || (SNAKE_DIR_DOWN == prevdir && SNAKE_DIR_UP != dir) || (SNAKE_DIR_LEFT == prevdir && SNAKE_DIR_RIGHT != dir) || (SNAKE_DIR_RIGHT == prevdir && SNAKE_DIR_LEFT != dir) ) { prevdir = dir; } else { rt_kprintf("dirction change error\n\r"); } return prevdir; } static void across_XY(point_t *node, const map_t *map) { RT_ASSERT(node != RT_NULL && map != RT_NULL); // 如果长度超出当前边框则可以穿越墙到对面 node->x = (node->x + map->width) % map->width; node->y = (node->y + map->height) % map->height; } static SYS_STE node_update(snake_t *tail, const point_t *node, map_t *map) { SYS_STE ret; point_t *pos; RT_ASSERT(tail != RT_NULL && node != RT_NULL && map != RT_NULL); pos = map->snake_flush; pos[0].x = pos[0].y = -1; pos[1].x = pos[1].y = -1; ret = (SYS_STE)map->range[node->y * map->width + node->x]; if (FOOD == map->range[node->y * map->width + node->x]) { // 吃一个食物增加一个节点 snake_t *new = (snake_t*)rt_malloc(sizeof(snake_t)); if (!new) return NORMAL; pos[0] = *node; new->body = *node; rt_list_insert_after(&snake_head, &new->list); } else if (NORMAL == map->range[node->y * map->width + node->x]) { // 将尾巴修改后拿到头部,其他不变 rt_list_remove(&tail->list); map->range[tail->body.y * map->width + tail->body.x] = NORMAL; pos[0] = *node; pos[1] = tail->body; tail->body = *node; rt_list_insert_after(&snake_head, &tail->list); } map->range[node->y * map->width + node->x] = OVER; return ret; } map_t* map_init(rt_uint32_t width, rt_uint32_t heigth) { map_t *map = rt_malloc(sizeof(map_t)); if (map != RT_NULL) { map->range = rt_malloc(heigth * width); if (!map->range) { rt_free(map); map = RT_NULL; } else { map->width = width; map->height = heigth; memset(map->range, NORMAL, heigth * width); } } return map; } // 构造一条指定长度的蛇在指定点 rt_bool_t snake_init(const point_t *start, const int length, const SNAKE_DIR dir, map_t *map) { rt_int32_t i; rt_int32_t inc_x, inc_y; point_t old = *start; ASSERT_RET(!map || !start, RT_FALSE); rt_list_init(&snake_head); if (dir == SNAKE_DIR_UP || dir == SNAKE_DIR_DOWN) { if (map->height <= length) return RT_FALSE; inc_x = 0; inc_y = dir == SNAKE_DIR_DOWN ? 1 : -1; // 反向延长身子,头部在指定位置 old.y -= inc_y; } else { if (map->width <= length) return RT_FALSE; inc_y = 0; inc_x = dir == SNAKE_DIR_RIGHT ? -1 : 1; old.x -= inc_x; } for (i=0; ibody.y = inc_y + old.y; new->body.x = inc_x + old.x; // 如果长度超出当前边框则可以穿越墙到对面 across_XY(&new->body, map); map->range[new->body.y * map->width + new->body.x] = OVER; old = new->body; rt_list_insert_before(&snake_head, &new->list); } prevdir = dir; return RT_TRUE; } // 构造出食物 rt_bool_t food_init(map_t *map, rt_uint32_t max_num) { point_t food; #ifndef FOOD_TIMEOUT #define FOOD_TIMEOUT 10 #endif rt_uint32_t timeout, num; ASSERT_RET(!map, RT_FALSE); num = 0; timeout = rt_tick_get(); srand(rand()); map->food_flush[0].x = map->food_flush[0].y = -1; do { food.x = rand() % map->width; food.y = rand() % map->height; if (map->range[food.y * map->width + food.x] == NORMAL) { map->food_flush[0] = food; map->range[food.y * map->width + food.x] = FOOD; num++; } } while (num < max_num && rt_tick_get() - timeout < FOOD_TIMEOUT); return num; } void map_deinit(map_t *map) { if (map) { if (map->range) { rt_free(map->range); map->range = RT_NULL; } rt_free(map); } } void snake_deinit(void) { snake_t *node; while (!rt_list_isempty(&snake_head)) { node = rt_list_entry(snake_head.prev, snake_t, list); rt_list_remove(&node->list); rt_free(node); } } void food_deinit(void) { } SYS_STE snake_step(SNAKE_DIR dir, map_t *map) { snake_t *tail, *head; point_t node; ASSERT_RET(!map, RT_FALSE); dir = dir_adjust(dir); // 取出头尾两个节点,其他节点不需要改变 tail = rt_list_entry(snake_head.prev, snake_t, list); head = rt_list_entry(snake_head.next, snake_t, list); node = head->body; // 构造一个新的蛇头坐标 switch (dir) { case SNAKE_DIR_UP: case SNAKE_DIR_DOWN: node.y = head->body.y + (dir == SNAKE_DIR_DOWN ? -1 : 1); break; case SNAKE_DIR_LEFT: case SNAKE_DIR_RIGHT: node.x = head->body.x + (dir == SNAKE_DIR_RIGHT ? 1 : -1); break; } across_XY(&node, map); return node_update(tail, &node, map); } rt_bool_t snake_restart(const point_t *start, const int length, const SNAKE_DIR dir, map_t *map) { ASSERT_RET(!map || !start, RT_FALSE); snake_deinit(); memset(map->range, NORMAL, map->width * map->height); return snake_init(start, length, dir, map); }