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Solve the Rush Hour puzzle with prolog. Read more about this puzzle at https://en.wikipedia.org/wiki/Rush_Hour_(puzzle) Here is the Python code: import rush_hour.state as st def run(puzzle):

Solve the Rush Hour puzzle with prolog. Read more about this puzzle at https://en.wikipedia.org/wiki/Rush_Hour_(puzzle)

Here is the Python code:

import rush_hour.state as st def run(puzzle): """Solve a Rush hour puzzle represented as 36-character string listing the 6x6 cells of the board in row-major order. Empty cells are marked with "o". Occupied cells are marked with letters representing pieces. Cells occupied by the same piece carry the same letter.""" return _Solver(puzzle).run() class _Solver: """The state of the solver""" def __init__(self, string_rep): start_state = st.from_string_rep(string_rep) self._current = [([], start_state)] self._next = [] self._seen = {start_state} def run(self): """Run the solver from the start state.""" while True: for seq in self._current: sol = self._search(seq) if sol: return sol if self._next: self._current = self._next self._next = [] else: return None def _search(self, path): """See whether the given path (sequence of moves) can be extended with a single move to obtain a solution. If so, return this solution. Otherwise, return None and, as a side effect, add all extensions of this path that end in a previously unexplored state to the frontier to be explored at the next BFS level.""" state = path[1] for (next_state, move) in self._moves(state): if st.is_solved(next_state): return path[0] + [move] if next_state not in self._seen: self._next.append((path[0] + [move], next_state)) self._seen.add(next_state) return None @staticmethod def _moves(state): """Generate all valid moves from the given state. This is an iterator that yields (new_state, move) pairs where move is a valid move applicable to state and new_state is the resulting new state.""" for pos in range(64): if st.is_end(state, pos): if st.is_horizontal(state, pos): for k in range(1, 5): new_state = st.horizontal_move(state, pos, k) if not new_state: break yield (new_state, st.make_move(pos, k)) for k in range(1, 5): new_state = st.horizontal_move(state, pos, -k) if not new_state: break yield (new_state, st.make_move(pos, -k)) if st.is_vertical(state, pos): for k in range(1, 5): new_state = st.vertical_move(state, pos, k) if not new_state: break yield (new_state, st.make_move(pos, k)) for k in range(1, 5): new_state = st.vertical_move(state, pos, -k) if not new_state: break yield (new_state, st.make_move(pos, -k))

Below are the modules for the above methods:

"""This module provides the primitives for manipulating and querying the current game state. The game state is represented as a tuple of 4 64-bit words (occupied, horiz, vert, ends). Each bit corresponds to a cell of an 8x8 board numbered in row-major order. Referring to the ith bit of a bit vector vec as vec[i], these four words have the following meaning: - occupied[i] = 1 if cell i is occupied by a piece - horiz[i] = 1 if cell i is occupied by a horizontal piece - vert[i] = 1 if cell i is occupied by a vertical piece - ends[i] = 1 if cell i is the rightmost or bottommost cell of a piece""" from io import StringIO from itertools import chain def from_string_rep(string_rep): """Construct a state from its string representation. The input is a 36-character string listing the 6x6 cells of the board in row-major order. Empty cells are marked with "o". Occupied cells are marked with letters representing pieces. Cells occupied by the same piece carry the same letter.""" grid = _grid_from_string_rep(string_rep) horiz, horiz_ends = _find_horiz_pieces(grid) vert, vert_ends = _find_vert_pieces(grid) occupied = vert | horiz ends = horiz_ends | vert_ends return (occupied, horiz, vert, ends) def _grid_from_string_rep(string_rep): """Pad a 36-character string representation of a state into a 64-character representation that includes empty cells to represent the borders around the board.""" grid = StringIO() print("oooooooo", file=grid, end="") for i in range(6): print("o{}o".format(string_rep[6*i:6*(i+1)]), file=grid, end="") print("oooooooo", file=grid, end="") return grid.getvalue() def _find_vert_pieces(grid): """Find all vertical pieces on the board and return two words representing the cells occupied by these pieces and the cells that are the bottommost cells of these pieces.""" transposed_grid = _transpose_grid(grid) transposed_bits, transposed_ends = \ _find_horiz_pieces(transposed_grid) return _transpose_bits(transposed_bits), \ _transpose_bits(transposed_ends) def _find_horiz_pieces(grid): """Find all horizontal pieces on the board and return two words representing the cells occupied by these pieces and the cells that are the rightmost cells of these pieces.""" bits = 0xff000000000000ff ends = 0 for i in range(64): cellbit, cellend = _horiz_bits(grid, i) bits |= cellbit ends |= cellend return bits, ends def _horiz_bits(grid, pos): """Return a pair of words representing position pos on the board. The first word is 1 << pos if the position is occupied and 0 otherwise. The second word is 1 << pos if the position is the rightmost position of a piece and 0 otherwise.""" if grid[pos] == "o": return 0, 0 if grid[pos] == grid[pos+1]: return 1 << pos, 0 if grid[pos] == grid[pos-1]: return 1 << pos, 1 << pos else: return 0, 0 def _transpose_grid(grid): """Rearranges the character in a 64-character string represending an 8x8 Rush Hour board so as to transpose the board.""" transposed_grid = StringIO() for i in range(64): j = ((i & 7) << 3) | ((i & 56) >> 3) print(grid[j], file=transposed_grid, end="") return transposed_grid.getvalue() def _transpose_bits(bits): """Rearranges the bits in a 64-bit bit string representing an 8x8 board so as to transpose the board.""" # 2x2 transpose of individual bits trans = (bits ^ (bits << 7)) & 0x5500550055005500 bits = bits ^ trans ^ (trans >> 7) # 2x2 transpose of 2x2 blocks trans = (bits ^ (bits << 14)) & 0x3333000033330000 bits = bits ^ trans ^ (trans >> 14) # 2x2 transpose of 4x4 blocks trans = (bits ^ (bits << 28)) & 0x0f0f0f0f00000000 bits = bits ^ trans ^ (trans >> 28) return bits def pretty_print(state): """Produce a vector of 14 14-character strings that, if printed in consecutive rows display the Rush Hour board. (The 14 rows and 14 columns result from using 2x2 characters for every board cell and one character for the border. Since there are 6x6 cells on the board, this gives 14 rows and 14 columns.)""" rows = [[_format_cell(state, row + col) for col in range(1, 7)] for row in range(8, 63, 8)] lines = [""] + \ ["".join(chain.from_iterable(line)) for line in chain.from_iterable((zip(*row) for row in rows))] + \ [""] left_wall = "" right_wall = " " return ["".join(line) for line in zip(left_wall, lines, right_wall)] def _format_cell(state, pos): if not is_occupied(state, pos): return [" ", " "] if is_horizontal(state, pos): if not is_horizontal(state, pos - 1) or is_end(state, pos - 1): left = "" else: left = "" if not is_horizontal(state, pos + 1) or is_end(state, pos): right = "" else: right = "" return ["".join(line) for line in zip(left, right)] if not is_vertical(state, pos - 8) or is_end(state, pos - 8): top = "" else: top = "" if not is_vertical(state, pos + 8) or is_end(state, pos): bottom = "" else: bottom = "" return [top, bottom] def is_occupied(state, pos): """Check whether the posth cell is occupied.""" return state[0] & (1 << pos) def is_horizontal(state, pos): """Check whether the posth cell is occupied by a horizontal piece.""" return state[1] & (1 << pos) def is_vertical(state, pos): """Check whether the posth cell is occupied by a vertical piece.""" return state[2] & (1 << pos) def is_end(state, pos): """Check whether the posth cell is the rightmost or bottommost cell of a piece.""" return state[3] & (1 << pos) def is_solved(state): """Check whether the board is solved. This is the case when the horizontal on the 3rd row is moved all the way to the right, that is cell 30 is occupied by a horizontal piece.""" return is_horizontal(state, 30) def make_move(pos, offset): """Construct a move object from a given position-offset pair""" return (pos << 8) | (offset + 4) def vertical_move(state, pos, offset): """Move the vertical piece occupying position pos by offset positions. A negative offset means move up. A positive offset means move down. The return value is the new state and a representation of the move as a 16-bit word. If the move is invalid because it moves the piece off the board or across another piece, two None values are returned.""" stop = state[0] & \ (state[1] ^ 0xffffffffffffffff) & \ (state[3] ^ 0xffffffffffffffff) return _move(state, pos, offset, stop, 8, 0x0101010101010101) def horizontal_move(state, pos, offset): """Move the horizontal piece occupying position pos by offset positions. A negative offset means move left. A positive offset means move right. The return value is the new state and a representation of the move as a 16-bit word. If the move is invalid because it moves the piece off the board or across another piece, two None values are returned.""" stop = state[0] & \ (state[2] ^ 0xffffffffffffffff) & \ (state[3] ^ 0xffffffffffffffff) return _move(state, pos, offset, stop, 1, 0xffffffffffffffff) def _move(state, pos, offset, stop, skip, mask): """This is the worker that implements both horizontal and vertical moves.""" # Construct the bit vector representing the positions occupied by the piece # to be moved piece = 1 << pos left = piece >> skip while stop & left: piece |= left left >>= skip # Construct the new piece resulting from the move and # - the leftmost and rightmost of piece and new_piece # - the end positions of the leftmost and rightmost pieces if offset < 0: new_piece = piece >> (-offset * skip) left, right = new_piece, piece left_pos, right_pos = pos + offset * skip, pos else: new_piece = piece << (offset * skip) left, right = piece, new_piece left_pos, right_pos = pos, pos + offset * skip # Abort if the new piece is out of bounds if left_pos < 9 + skip or right_pos > 54: return None # Construct the swath of cells over which the piece moves from its old to # its new position. left = left | (mask << left_pos) right = right | (mask >> (64 - right_pos - skip)) swath = (left & right) ^ piece # Abort if any of them is occupied. if state[0] & swath: return None # Construct the change in occupied cells and the change in end cells # resulting from the move piece_delta = piece ^ new_piece end_delta = (1 << pos) | (1 << (pos + offset * skip)) # Update occupied, horiz, and end if this was a horizontal move. # Otherwise, update, occupied, vert, and end. if skip == 1: return ( state[0] ^ piece_delta, state[1] ^ piece_delta, state[2], state[3] ^ end_delta ) return ( state[0] ^ piece_delta, state[1], state[2] ^ piece_delta, state[3] ^ end_delta ) def apply_move(state, move): """Try to apply the given move to state. Return the new state if this succeeds. Otherwise, return None.""" pos = move >> 8 offset = (move & 0xff) - 4 if not is_occupied(state, pos): return None if is_horizontal(state, pos): return horizontal_move(state, pos, offset) return vertical_move(state, pos, offset) 

With this as a guideline as a solution, implement it in the functional Prolog language.

Here are the main predicates to be used in Prolog. Please include them:

% Main predicate main :- get_args(PuzzleNumber), load_puzzle(PuzzleNumber, Puzzle), !, solve_puzzle(Puzzle, Moves), format("~s~n", [Puzzle]), print_moves(Moves), halt. % Get the puzzle number from the command line get_args(PuzzleNumber) :- current_prolog_flag(argv, [PuzzleNumberStr]), string_int(PuzzleNumberStr, PuzzleNumber), !. get_args(_) :- format("USAGE: rush_hour_solve.pl ~n"), !, fail. % Convert a string into an integer string_int(String, Int) :- atom_codes(String, Codes), phrase(int(Int), Codes). % Deterministic clause grammar for an integer literal int(X) --> digit(D), digits(Ds), { number_codes(X, [D|Ds]) }. digits([D|Ds]) --> digit(D), !, digits(Ds). digits([]) --> []. digit(D) --> [D], { code_type(D, digit) }. % Load the given puzzle from the database load_puzzle(Number, Puzzle) :- puzzle(Number, _, Puzzle, _), !. load_puzzle(_, []) :- num_puzzles(Total), format("ERROR: There are only ~d puzzles~n", [Total]), !, fail. % Print the list of moves print_moves([]). print_moves([Move|Moves]) :- move_string(Move, String), format(String), print_moves(Moves).

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