PNG  IHDR;IDATxܻn0K )(pA 7LeG{ §㻢|ذaÆ 6lذaÆ 6lذaÆ 6lom$^yذag5bÆ 6lذaÆ 6lذa{ 6lذaÆ `}HFkm,mӪôô! x|'ܢ˟;E:9&ᶒ}{v]n&6 h_tڠ͵-ҫZ;Z$.Pkž)!o>}leQfJTu іچ\X=8Rن4`Vwl>nG^is"ms$ui?wbs[m6K4O.4%/bC%t Mז -lG6mrz2s%9s@-k9=)kB5\+͂Zsٲ Rn~GRC wIcIn7jJhۛNCS|j08yiHKֶۛkɈ+;SzL/F*\Ԕ#"5m2[S=gnaPeғL lذaÆ 6l^ḵaÆ 6lذaÆ 6lذa; _ذaÆ 6lذaÆ 6lذaÆ RIENDB` #! /usr/bin/env python """N queens problem. The (well-known) problem is due to Niklaus Wirth. This solution is inspired by Dijkstra (Structured Programming). It is a classic recursive backtracking approach. """ N = 8 # Default; command line overrides class Queens: def __init__(self, n=N): self.n = n self.reset() def reset(self): n = self.n self.y = [None] * n # Where is the queen in column x self.row = [0] * n # Is row[y] safe? self.up = [0] * (2*n-1) # Is upward diagonal[x-y] safe? self.down = [0] * (2*n-1) # Is downward diagonal[x+y] safe? self.nfound = 0 # Instrumentation def solve(self, x=0): # Recursive solver for y in range(self.n): if self.safe(x, y): self.place(x, y) if x+1 == self.n: self.display() else: self.solve(x+1) self.remove(x, y) def safe(self, x, y): return not self.row[y] and not self.up[x-y] and not self.down[x+y] def place(self, x, y): self.y[x] = y self.row[y] = 1 self.up[x-y] = 1 self.down[x+y] = 1 def remove(self, x, y): self.y[x] = None self.row[y] = 0 self.up[x-y] = 0 self.down[x+y] = 0 silent = 0 # If true, count solutions only def display(self): self.nfound = self.nfound + 1 if self.silent: return print '+-' + '--'*self.n + '+' for y in range(self.n-1, -1, -1): print '|', for x in range(self.n): if self.y[x] == y: print "Q", else: print ".", print '|' print '+-' + '--'*self.n + '+' def main(): import sys silent = 0 n = N if sys.argv[1:2] == ['-n']: silent = 1 del sys.argv[1] if sys.argv[1:]: n = int(sys.argv[1]) q = Queens(n) q.silent = silent q.solve() print "Found", q.nfound, "solutions." if __name__ == "__main__": main()