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remove: legacy core code

legacy
Dnomd343 2 years ago
parent
commit
8bf3374e4d
  1. 38
      include/klotski.h
  2. 256
      src-legacy/main.cc

38
include/klotski.h

@ -3,25 +3,25 @@
#include <cstdint>
#define B_space 0x0
#define B_fill 0x7
#define B_1x2 0x1
#define B_2x1 0x2
#define B_1x1 0x3
#define B_2x2 0x4
#define C_1x1 uint64_t(0x3)
#define C_1x2 uint64_t(0x39)
#define C_2x1 uint64_t(0x7002)
#define C_2x2 uint64_t(0x3F03C)
#define F_1x1 uint64_t(0x7)
#define F_1x2 uint64_t(0x3F)
#define F_2x1 uint64_t(0x7007)
#define F_2x2 uint64_t(0x3F03F)
uint64_t compact_code(uint64_t code);
uint64_t extract_code(uint64_t code);
//#define B_space 0x0
//#define B_fill 0x7
//#define B_1x2 0x1
//#define B_2x1 0x2
//#define B_1x1 0x3
//#define B_2x2 0x4
//#define C_1x1 uint64_t(0x3)
//#define C_1x2 uint64_t(0x39)
//#define C_2x1 uint64_t(0x7002)
//#define C_2x2 uint64_t(0x3F03C)
//
//#define F_1x1 uint64_t(0x7)
//#define F_1x2 uint64_t(0x3F)
//#define F_2x1 uint64_t(0x7007)
//#define F_2x2 uint64_t(0x3F03F)
//uint64_t compact_code(uint64_t code);
//uint64_t extract_code(uint64_t code);
#endif

256
src-legacy/main.cc

@ -1,17 +1,17 @@
#include "case.h"
#include "klotski.h"
//#include "case.h"
//#include "klotski.h"
#include <cstdio>
#include <cstdint>
#include <list>
#include <unordered_map>
#include <queue>
#define UP (-12)
#define LEFT (-3)
#define DOWN 12
#define DOWN_2 24
#define RIGHT 3
#define RIGHT_2 6
//#define UP (-12)
//#define LEFT (-3)
//#define DOWN 12
//#define DOWN_2 24
//#define RIGHT 3
//#define RIGHT_2 6
struct cache {
uint64_t code;
@ -30,245 +30,9 @@ struct klotski_info {
std::queue<klotski_info*> cal_cache;
std::unordered_map<uint64_t, klotski_info*> klotski_case;
void graph_output(uint64_t code) {
for (int i = 0; i < 20; ++i) {
switch (code & 0x7) {
case B_1x1:
printf("# ");
break;
case B_1x2:
printf("& ");
break;
case B_2x1:
printf("$ ");
break;
case B_2x2:
printf("@ ");
break;
case B_fill:
printf("* ");
break;
case B_space:
printf(". ");
break;
default:
printf("? ");
}
if ((i & 0x3) == 0x3) {
printf("\n");
}
code >>= 3;
}
}
inline bool move_block_release(uint64_t code, uint64_t filter) {
struct cache *p = move_cache;
for (; p < move_cache + move_cache_num; ++p) {
if (p->code == code) {
return false;
}
}
p->code = code;
p->filter = filter;
++move_cache_num;
return true;
}
void move_block_1x1(uint64_t code, int addr, int filter) {
int target_addr;
uint64_t ret_code;
if (filter != UP && addr >= 4 * 3 && !(code >> (target_addr = addr + UP) & F_1x1)) {
ret_code = code & ~(F_1x1 << addr) | C_1x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x1(ret_code, target_addr, DOWN);
}
}
if (filter != DOWN && addr <= 15 * 3 && !(code >> (target_addr = addr + DOWN) & F_1x1)) {
ret_code = code & ~(F_1x1 << addr) | C_1x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x1(ret_code, target_addr, UP);
}
}
if (filter != LEFT && (addr & 0x3) != 0 && !(code >> (target_addr = addr + LEFT) & F_1x1)) {
ret_code = code & ~(F_1x1 << addr) | C_1x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x1(ret_code, target_addr, RIGHT);
}
}
if (filter != RIGHT && (addr & 0x3) != 1 && !(code >> (target_addr = addr + RIGHT) & F_1x1)) {
ret_code = code & ~(F_1x1 << addr) | C_1x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x1(ret_code, target_addr, LEFT);
}
}
}
void move_block_1x2(uint64_t code, int addr, int filter) {
int target_addr;
uint64_t ret_code;
if (filter != UP && addr >= 4 * 3 && !(code >> (target_addr = addr + UP) & F_1x2)) {
ret_code = code & ~(F_1x2 << addr) | C_1x2 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x2(ret_code, target_addr, DOWN);
}
}
if (filter != DOWN && addr <= 14 * 3 && !(code >> (target_addr = addr + DOWN) & F_1x2)) {
ret_code = code & ~(F_1x2 << addr) | C_1x2 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x2(ret_code, target_addr, UP);
}
}
if (filter != LEFT && (addr & 0x3) != 0 && !(code >> (target_addr = addr + LEFT) & F_1x1)) {
ret_code = code & ~(F_1x2 << addr) | C_1x2 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x2(ret_code, target_addr, RIGHT);
}
}
if (filter != RIGHT && (addr & 0x3) != 2 && !(code >> (addr + RIGHT_2) & F_1x1)) {
ret_code = code & ~(F_1x2 << addr) | C_1x2 << (target_addr = addr + RIGHT);
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_1x2(ret_code, target_addr, LEFT);
}
}
}
void move_block_2x1(uint64_t code, int addr, int filter) {
int target_addr;
uint64_t ret_code;
if (filter != UP && addr >= 4 * 3 && !(code >> (target_addr = addr + UP) & F_1x1)) {
ret_code = code & ~(F_2x1 << addr) | C_2x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x1(ret_code, target_addr, DOWN);
}
}
if (filter != DOWN && addr <= 11 * 3 && !(code >> (addr + DOWN_2) & F_1x1)) {
ret_code = code & ~(F_2x1 << addr) | C_2x1 << (target_addr = addr + DOWN);
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x1(ret_code, target_addr, UP);
}
}
if (filter != LEFT && (addr & 0x3) != 0 && !(code >> (target_addr = addr + LEFT) & F_2x1)) {
ret_code = code & ~(F_2x1 << addr) | C_2x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x1(ret_code, target_addr, RIGHT);
}
}
if (filter != RIGHT && (addr & 0x3) != 1 && !(code >> (target_addr = addr + RIGHT) & F_2x1)) {
ret_code = code & ~(F_2x1 << addr) | C_2x1 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x1(ret_code, target_addr, LEFT);
}
}
}
void move_block_2x2(uint64_t code, int addr, int filter) {
int target_addr;
uint64_t ret_code;
if (filter != UP && addr >= 4 * 3 && !(code >> (target_addr = addr + UP) & F_1x2)) {
ret_code = code & ~(F_2x2 << addr) | C_2x2 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x2(ret_code, target_addr, DOWN);
}
}
if (filter != DOWN && addr <= 10 * 3 && !(code >> (addr + DOWN_2) & F_1x2)) {
ret_code = code & ~(F_2x2 << addr) | C_2x2 << (target_addr = addr + DOWN);
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x2(ret_code, target_addr, UP);
}
}
if (filter != LEFT && (addr & 0x3) != 0 && !(code >> (target_addr = addr + LEFT) & F_2x1)) {
ret_code = code & ~(F_2x2 << addr) | C_2x2 << target_addr;
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x2(ret_code, target_addr, RIGHT);
}
}
if (filter != RIGHT && (addr & 0x3) != 2 && !(code >> (addr + RIGHT_2) & F_2x1)) {
ret_code = code & ~(F_2x2 << addr) | C_2x2 << (target_addr = addr + RIGHT);
if (move_block_release(ret_code, uint64_t(0x7) << target_addr)) {
move_block_2x2(ret_code, target_addr, LEFT);
}
}
}
void add_new_case(klotski_info *src, uint64_t code, uint64_t filter) {
auto existing_case = klotski_case.find(code);
if (existing_case != klotski_case.end()) {
existing_case->second->filter |= filter;
if (existing_case->second->step != src->step) {
existing_case->second->src.push_back(src);
}
return;
}
auto info = new struct klotski_info;
info->code = code;
info->filter = filter;
info->step = src->step + 1;
info->src.push_back(src);
cal_cache.emplace(info);
klotski_case.emplace(code, info);
}
void next_step(klotski_info *klotski) {
move_cache->code = klotski->code;
uint64_t range = move_cache->code & ~klotski->filter;
for (int addr = 0; range; range >>= 3, addr += 3) {
move_cache_num = 1;
switch (range & 0x7) {
case B_2x2:
move_block_2x2(move_cache->code, addr, 0);
break;
case B_2x1:
move_block_2x1(move_cache->code, addr, 0);
break;
case B_1x2:
move_block_1x2(move_cache->code, addr, 0);
break;
case B_1x1:
move_block_1x1(move_cache->code, addr, 0);
break;
default:
continue;
}
for (struct cache *p = move_cache + 1; p < move_cache + move_cache_num; ++p) {
add_new_case(klotski, p->code, p->filter);
}
}
}
void cal_klotski(uint64_t code) {
auto setup = new klotski_info;
setup->step = 0;
setup->code = code;
setup->filter = 0x0;
klotski_case.clear();
klotski_case.emplace(code, setup);
cal_cache.push(setup);
while (!cal_cache.empty()) {
next_step(cal_cache.front());
cal_cache.pop();
}
// printf("count -> %zu\n", klotski_case.size());
}
int main() {
printf("Klotski engine\n");
std::vector<uint64_t> all_cases;
find_all_case(&all_cases);
// std::cout << "klotski cases -> " << all_cases.size() << std::endl;
printf("klotski cases -> %zu\n", all_cases.size());
return 0;
// printf("%lx\n", compact_code(0x0E58FC85FFEBC4DB));
// printf("%lx\n", compact_code(0x0603EDF5CAFFF5E2));
@ -307,9 +71,9 @@ int main() {
// uint64_t code = 0x0603EDF5CAFFF5E2;
uint64_t code = 0x0E58FC85FFEBC4DB;
for (int i = 0; i < 100; ++i) {
// for (int i = 0; i < 100; ++i) {
cal_klotski(code);
}
// }
return 0;
}

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