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537 lines
23 KiB
Racket
537 lines
23 KiB
Racket
#lang racket/base
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;; Adapted from work by Peter Norvig
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;; http://aima-python.googlecode.com/svn/trunk/csp.py
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(require racket/list racket/bool racket/contract racket/class racket/match)
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(require "utils.rkt" "search.rkt")
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(define CSP (class Problem
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#|
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This class describes finite-domain Constraint Satisfaction Problems.
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A CSP is specified by the following inputs:
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vars A list of variables; each is atomic (e.g. int or string).
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domains A dict of {var:[possible_value, ...]} entries.
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neighbors A dict of {var:[var,...]} that for each variable lists
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the other variables that participate in constraints.
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constraints A function f(A, a, B, b) that returns true if neighbors
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A, B satisfy the constraint when they have values A=a, B=b
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In the textbook and in most mathematical definitions, the
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constraints are specified as explicit pairs of allowable values,
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but the formulation here is easier to express and more compact for
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most cases. (For example, the n-Queens problem can be represented
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in O(n) space using this notation, instead of O(N^4) for the
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explicit representation.) In terms of describing the CSP as a
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problem, that's all there is.
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However, the class also supports data structures and methods that help you
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solve CSPs by calling a search function on the CSP. Methods and slots are
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as follows, where the argument 'a' represents an assignment, which is a
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dict of {var:val} entries:
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assign(var, val, a) Assign a[var] = val; do other bookkeeping
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unassign(var, a) Do del a[var], plus other bookkeeping
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nconflicts(var, val, a) Return the number of other variables that
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conflict with var=val
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curr_domains[var] Slot: remaining consistent values for var
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Used by constraint propagation routines.
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The following methods are used only by graph_search and tree_search:
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actions(state) Return a list of actions
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result(state, action) Return a successor of state
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goal_test(state) Return true if all constraints satisfied
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The following are just for debugging purposes:
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nassigns Slot: tracks the number of assignments made
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display(a) Print a human-readable representation
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|#
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(super-new)
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;; Construct a CSP problem. If vars is empty, it becomes domains.keys().
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(init-field vars domains neighbors constraints)
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(when (not vars) (set! vars (hash-keys domains)))
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(inherit-field initial)
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(set! initial (hash))
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(field [curr_domains #f][pruned #f][nassigns 0][fc #f][mac #f])
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(define/public (assign var val assignment)
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;; Add {var: val} to assignment; Discard the old value if any.
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;; Do bookkeeping for curr_domains and nassigns.
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(set! nassigns (add1 nassigns))
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(hash-set! assignment var val)
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(if curr_domains
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(when fc
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(forward_check var val assignment))
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(when mac
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(AC3 (map (λ(Xk) (cons Xk var)) (hash-ref neighbors var))))))
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(define/public (unassign var val assignment)
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;; Remove {var: val} from assignment; that is backtrack.
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;; DO NOT call this if you are changing a variable to a new value;
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;; just call assign for that.
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(when (hash-has-key? assignment var)
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;; Reset the curr_domain to be the full original domain
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(when curr_domains
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(hash-set! curr_domains var (hash-ref domains var)))
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(hash-remove! assignment var)))
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(define/public (nconflicts var val assignment)
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;; Return the number of conflicts var=val has with other variables.
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;; Subclasses may implement this more efficiently
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(define (conflict var2)
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(define val2 (hash-ref assignment var2 #f))
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(and val2 (not (constraints var val var2 val2))))
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(count_if conflict (hash-ref neighbors var)))
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(define/public (forward_check var val assignment)
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;; Do forward checking (current domain reduction) for this assignment.
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(when curr_domains
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;; Restore prunings from previous value of var
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(for ([Bb-pair (in-list (hash-ref pruned var))])
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(match-define (cons B b) Bb-pair)
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(hash-update! curr_domains B (λ(v) (append v b))))
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(hash-set! pruned var #f)
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;; Prune any other B=b assignment that conflicts with var=val
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(for ([B (in-list (hash-ref neighbors var))])
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(when (not (hash-has-key? assignment B))
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(for ([b (in-list (hash-ref curr_domains B))])
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(when (not (constraints var val B b))
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(remove b (hash-ref curr_domains B))
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(append (hash-ref pruned var) (cons B b))))))))
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(define/public (display assignment)
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;; Show a human-readable representation of the CSP.
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(displayln (format "CSP: ~a with assignment: ~a" this assignment)))
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;; These methods are for the tree and graph search interface:
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(define/public (succ assignment)
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;; Return a list of (action, state) pairs
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(if (= (length assignment) (length vars))
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null
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(let ()
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(define var (find_if (λ(v) (not (hash-has-key? assignment v))) vars))
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(define result null)
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(for ([val (in-list (hash-ref domains var))])
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(when (= (nconflicts var val assignment) 0)
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(define a (hash-copy assignment)) ;; !! typo fix in original
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(hash-set! a var val)
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(set! result (append result (cons (cons var val) a)))))
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result)))
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;; todo: calls to append need to mutate.
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(define/public (AC3 csp [queue #f])
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(void))
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))
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#|
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(define (actions csp state)
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;; Return a list of applicable actions: nonconflicting
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;; assignments to an unassigned variable.
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(if (= (length state) (length (hash-ref csp 'vars)))
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null
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(let ()
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(define assignment (make-hash state))
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(define var (findf (λ(v) (not (hash-has-key? assignment v))) (hash-ref csp 'vars)))
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(map (λ(val) (list var val))
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(filter (λ(val) (= 0 (nconflicts csp var val assignment))) (hash-ref (hash-ref csp 'domains) var))))))
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|#
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#|
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def actions(self, state):
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"""Return a list of applicable actions: nonconflicting
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assignments to an unassigned variable."""
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if len(state) == len(self.vars):
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return []
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else:
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assignment = dict(state)
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var = find_if(lambda v: v not in assignment, self.vars)
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return [(var, val) for val in self.domains[var]
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if self.nconflicts(var, val, assignment) == 0]
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def result(self, state, (var, val)):
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"Perform an action and return the new state."
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return state + ((var, val),)
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def goal_test(self, state):
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"The goal is to assign all vars, with all constraints satisfied."
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assignment = dict(state)
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return (len(assignment) == len(self.vars) and
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every(lambda var: self.nconflicts(var, assignment[var],
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assignment) == 0,
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self.vars))
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## These are for constraint propagation
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def support_pruning(self):
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"""Make sure we can prune values from domains. (We want to pay
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for this only if we use it.)"""
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if self.curr_domains is None:
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self.curr_domains = dict((v, list(self.domains[v]))
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for v in self.vars)
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def suppose(self, var, value):
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"Start accumulating inferences from assuming var=value."
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self.support_pruning()
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removals = [(var, a) for a in self.curr_domains[var] if a != value]
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self.curr_domains[var] = [value]
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return removals
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def prune(self, var, value, removals):
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"Rule out var=value."
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self.curr_domains[var].remove(value)
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if removals is not None: removals.append((var, value))
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def choices(self, var):
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"Return all values for var that aren't currently ruled out."
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return (self.curr_domains or self.domains)[var]
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def infer_assignment(self):
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"Return the partial assignment implied by the current inferences."
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self.support_pruning()
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return dict((v, self.curr_domains[v][0])
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for v in self.vars if 1 == len(self.curr_domains[v]))
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def restore(self, removals):
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"Undo a supposition and all inferences from it."
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for B, b in removals:
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self.curr_domains[B].append(b)
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## This is for min_conflicts search
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def conflicted_vars(self, current):
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"Return a list of variables in current assignment that are in conflict"
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return [var for var in self.vars
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if self.nconflicts(var, current[var], current) > 0]
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#______________________________________________________________________________
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# CSP Backtracking Search
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def backtracking_search(csp, mcv=False, lcv=False, fc=False, mac=False):
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"""Set up to do recursive backtracking search. Allow the following options:
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mcv - If true, use Most Constrained Variable Heuristic
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lcv - If true, use Least Constraining Value Heuristic
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fc - If true, use Forward Checking
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mac - If true, use Maintaining Arc Consistency. [Fig. 5.3]
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>>> backtracking_search(australia)
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{'WA': 'B', 'Q': 'B', 'T': 'B', 'V': 'B', 'SA': 'G', 'NT': 'R', 'NSW': 'R'}
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"""
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if fc or mac:
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csp.curr_domains, csp.pruned = {}, {}
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for v in csp.vars:
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csp.curr_domains[v] = csp.domains[v][:]
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csp.pruned[v] = []
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update(csp, mcv=mcv, lcv=lcv, fc=fc, mac=mac)
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return recursive_backtracking({}, csp)
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def recursive_backtracking(assignment, csp):
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"""Search for a consistent assignment for the csp.
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Each recursive call chooses a variable, and considers values for it."""
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if len(assignment) == len(csp.vars):
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return assignment
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var = select_unassigned_variable(assignment, csp)
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for val in order_domain_values(var, assignment, csp):
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if csp.fc or csp.nconflicts(var, val, assignment) == 0:
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csp.assign(var, val, assignment)
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result = recursive_backtracking(assignment, csp)
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if result is not None:
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return result
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csp.unassign(var, assignment)
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return None
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def select_unassigned_variable(assignment, csp):
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"Select the variable to work on next. Find"
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if csp.mcv: # Most Constrained Variable
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unassigned = [v for v in csp.vars if v not in assignment]
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return argmin_random_tie(unassigned,
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lambda var: -num_legal_values(csp, var, assignment))
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else: # First unassigned variable
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for v in csp.vars:
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if v not in assignment:
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return v
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def order_domain_values(var, assignment, csp):
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"Decide what order to consider the domain variables."
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if csp.curr_domains:
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domain = csp.curr_domains[var]
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else:
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domain = csp.domains[var][:]
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if csp.lcv:
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# If LCV is specified, consider values with fewer conflicts first
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key = lambda val: csp.nconflicts(var, val, assignment)
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domain.sort(lambda(x,y): cmp(key(x), key(y)))
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while domain:
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yield domain.pop()
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def num_legal_values(csp, var, assignment):
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if csp.curr_domains:
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return len(csp.curr_domains[var])
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else:
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return count_if(lambda val: csp.nconflicts(var, val, assignment) == 0,
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csp.domains[var])
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#______________________________________________________________________________
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# Constraint Propagation with AC-3
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def AC3(csp, queue=None):
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"""[Fig. 5.7]"""
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if queue == None:
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queue = [(Xi, Xk) for Xi in csp.vars for Xk in csp.neighbors[Xi]]
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while queue:
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(Xi, Xj) = queue.pop()
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if remove_inconsistent_values(csp, Xi, Xj):
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for Xk in csp.neighbors[Xi]:
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queue.append((Xk, Xi))
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def remove_inconsistent_values(csp, Xi, Xj):
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"Return true if we remove a value."
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removed = False
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for x in csp.curr_domains[Xi][:]:
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# If Xi=x conflicts with Xj=y for every possible y, eliminate Xi=x
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if every(lambda y: not csp.constraints(Xi, x, Xj, y),
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csp.curr_domains[Xj]):
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csp.curr_domains[Xi].remove(x)
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removed = True
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return removed
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#______________________________________________________________________________
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# Min-conflicts hillclimbing search for CSPs
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def min_conflicts(csp, max_steps=1000000):
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"""Solve a CSP by stochastic hillclimbing on the number of conflicts."""
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# Generate a complete assignement for all vars (probably with conflicts)
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current = {}; csp.current = current
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for var in csp.vars:
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val = min_conflicts_value(csp, var, current)
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csp.assign(var, val, current)
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# Now repeapedly choose a random conflicted variable and change it
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for i in range(max_steps):
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conflicted = csp.conflicted_vars(current)
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if not conflicted:
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return current
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var = random.choice(conflicted)
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val = min_conflicts_value(csp, var, current)
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csp.assign(var, val, current)
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return None
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def min_conflicts_value(csp, var, current):
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"""Return the value that will give var the least number of conflicts.
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If there is a tie, choose at random."""
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return argmin_random_tie(csp.domains[var],
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lambda val: csp.nconflicts(var, val, current))
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#______________________________________________________________________________
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# Map-Coloring Problems
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class UniversalDict:
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"""A universal dict maps any key to the same value. We use it here
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as the domains dict for CSPs in which all vars have the same domain.
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>>> d = UniversalDict(42)
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>>> d['life']
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42
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"""
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def __init__(self, value): self.value = value
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def __getitem__(self, key): return self.value
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def __repr__(self): return '{Any: %r}' % self.value
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def different_values_constraint(A, a, B, b):
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"A constraint saying two neighboring variables must differ in value."
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return a != b
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def MapColoringCSP(colors, neighbors):
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"""Make a CSP for the problem of coloring a map with different colors
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for any two adjacent regions. Arguments are a list of colors, and a
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dict of {region: [neighbor,...]} entries. This dict may also be
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specified as a string of the form defined by parse_neighbors"""
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if isinstance(neighbors, str):
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neighbors = parse_neighbors(neighbors)
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return CSP(neighbors.keys(), UniversalDict(colors), neighbors,
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different_values_constraint)
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def parse_neighbors(neighbors, vars=[]):
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"""Convert a string of the form 'X: Y Z; Y: Z' into a dict mapping
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regions to neighbors. The syntax is a region name followed by a ':'
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followed by zero or more region names, followed by ';', repeated for
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each region name. If you say 'X: Y' you don't need 'Y: X'.
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>>> parse_neighbors('X: Y Z; Y: Z')
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{'Y': ['X', 'Z'], 'X': ['Y', 'Z'], 'Z': ['X', 'Y']}
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"""
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dict = DefaultDict([])
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for var in vars:
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dict[var] = []
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specs = [spec.split(':') for spec in neighbors.split(';')]
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for (A, Aneighbors) in specs:
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A = A.strip();
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dict.setdefault(A, [])
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for B in Aneighbors.split():
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dict[A].append(B)
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dict[B].append(A)
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return dict
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australia = MapColoringCSP(list('RGB'),
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'SA: WA NT Q NSW V; NT: WA Q; NSW: Q V; T: ')
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usa = MapColoringCSP(list('RGBY'),
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"""WA: OR ID; OR: ID NV CA; CA: NV AZ; NV: ID UT AZ; ID: MT WY UT;
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UT: WY CO AZ; MT: ND SD WY; WY: SD NE CO; CO: NE KA OK NM; NM: OK TX;
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ND: MN SD; SD: MN IA NE; NE: IA MO KA; KA: MO OK; OK: MO AR TX;
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TX: AR LA; MN: WI IA; IA: WI IL MO; MO: IL KY TN AR; AR: MS TN LA;
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LA: MS; WI: MI IL; IL: IN; IN: KY; MS: TN AL; AL: TN GA FL; MI: OH;
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OH: PA WV KY; KY: WV VA TN; TN: VA NC GA; GA: NC SC FL;
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PA: NY NJ DE MD WV; WV: MD VA; VA: MD DC NC; NC: SC; NY: VT MA CA NJ;
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NJ: DE; DE: MD; MD: DC; VT: NH MA; MA: NH RI CT; CT: RI; ME: NH;
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HI: ; AK: """)
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#______________________________________________________________________________
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# n-Queens Problem
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def queen_constraint(A, a, B, b):
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"""Constraint is satisfied (true) if A, B are really the same variable,
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or if they are not in the same row, down diagonal, or up diagonal."""
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return A == B or (a != b and A + a != B + b and A - a != B - b)
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class NQueensCSP(CSP):
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"""Make a CSP for the nQueens problem for search with min_conflicts.
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Suitable for large n, it uses only data structures of size O(n).
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Think of placing queens one per column, from left to right.
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That means position (x, y) represents (var, val) in the CSP.
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The main structures are three arrays to count queens that could conflict:
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rows[i] Number of queens in the ith row (i.e val == i)
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downs[i] Number of queens in the \ diagonal
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such that their (x, y) coordinates sum to i
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ups[i] Number of queens in the / diagonal
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such that their (x, y) coordinates have x-y+n-1 = i
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We increment/decrement these counts each time a queen is placed/moved from
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a row/diagonal. So moving is O(1), as is nconflicts. But choosing
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a variable, and a best value for the variable, are each O(n).
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If you want, you can keep track of conflicted vars, then variable
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selection will also be O(1).
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>>> len(backtracking_search(NQueensCSP(8)))
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8
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>>> len(min_conflicts(NQueensCSP(8)))
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8
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"""
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def __init__(self, n):
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"""Initialize data structures for n Queens."""
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CSP.__init__(self, range(n), UniversalDict(range(n)),
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UniversalDict(range(n)), queen_constraint)
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update(self, rows=[0]*n, ups=[0]*(2*n - 1), downs=[0]*(2*n - 1))
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def nconflicts(self, var, val, assignment):
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"""The number of conflicts, as recorded with each assignment.
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Count conflicts in row and in up, down diagonals. If there
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is a queen there, it can't conflict with itself, so subtract 3."""
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n = len(self.vars)
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c = self.rows[val] + self.downs[var+val] + self.ups[var-val+n-1]
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if assignment.get(var, None) == val:
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c -= 3
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return c
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def assign(self, var, val, assignment):
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"Assign var, and keep track of conflicts."
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oldval = assignment.get(var, None)
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if val != oldval:
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if oldval is not None: # Remove old val if there was one
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self.record_conflict(assignment, var, oldval, -1)
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self.record_conflict(assignment, var, val, +1)
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CSP.assign(self, var, val, assignment)
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|
|
def unassign(self, var, assignment):
|
|
"Remove var from assignment (if it is there) and track conflicts."
|
|
if var in assignment:
|
|
self.record_conflict(assignment, var, assignment[var], -1)
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|
CSP.unassign(self, var, assignment)
|
|
|
|
def record_conflict(self, assignment, var, val, delta):
|
|
"Record conflicts caused by addition or deletion of a Queen."
|
|
n = len(self.vars)
|
|
self.rows[val] += delta
|
|
self.downs[var + val] += delta
|
|
self.ups[var - val + n - 1] += delta
|
|
|
|
def display(self, assignment):
|
|
"Print the queens and the nconflicts values (for debugging)."
|
|
n = len(self.vars)
|
|
for val in range(n):
|
|
for var in range(n):
|
|
if assignment.get(var,'') == val: ch ='Q'
|
|
elif (var+val) % 2 == 0: ch = '.'
|
|
else: ch = '-'
|
|
print ch,
|
|
print ' ',
|
|
for var in range(n):
|
|
if assignment.get(var,'') == val: ch ='*'
|
|
else: ch = ' '
|
|
print str(self.nconflicts(var, val, assignment))+ch,
|
|
print
|
|
|
|
#______________________________________________________________________________
|
|
# The Zebra Puzzle
|
|
|
|
def Zebra():
|
|
"Return an instance of the Zebra Puzzle."
|
|
Colors = 'Red Yellow Blue Green Ivory'.split()
|
|
Pets = 'Dog Fox Snails Horse Zebra'.split()
|
|
Drinks = 'OJ Tea Coffee Milk Water'.split()
|
|
Countries = 'Englishman Spaniard Norwegian Ukranian Japanese'.split()
|
|
Smokes = 'Kools Chesterfields Winston LuckyStrike Parliaments'.split()
|
|
vars = Colors + Pets + Drinks + Countries + Smokes
|
|
domains = {}
|
|
for var in vars:
|
|
domains[var] = range(1, 6)
|
|
domains['Norwegian'] = [1]
|
|
domains['Milk'] = [3]
|
|
neighbors = parse_neighbors("""Englishman: Red;
|
|
Spaniard: Dog; Kools: Yellow; Chesterfields: Fox;
|
|
Norwegian: Blue; Winston: Snails; LuckyStrike: OJ;
|
|
Ukranian: Tea; Japanese: Parliaments; Kools: Horse;
|
|
Coffee: Green; Green: Ivory""", vars)
|
|
for type in [Colors, Pets, Drinks, Countries, Smokes]:
|
|
for A in type:
|
|
for B in type:
|
|
if A != B:
|
|
if B not in neighbors[A]: neighbors[A].append(B)
|
|
if A not in neighbors[B]: neighbors[B].append(A)
|
|
def zebra_constraint(A, a, B, b, recurse=0):
|
|
same = (a == b)
|
|
next_to = abs(a - b) == 1
|
|
if A == 'Englishman' and B == 'Red': return same
|
|
if A == 'Spaniard' and B == 'Dog': return same
|
|
if A == 'Chesterfields' and B == 'Fox': return next_to
|
|
if A == 'Norwegian' and B == 'Blue': return next_to
|
|
if A == 'Kools' and B == 'Yellow': return same
|
|
if A == 'Winston' and B == 'Snails': return same
|
|
if A == 'LuckyStrike' and B == 'OJ': return same
|
|
if A == 'Ukranian' and B == 'Tea': return same
|
|
if A == 'Japanese' and B == 'Parliaments': return same
|
|
if A == 'Kools' and B == 'Horse': return next_to
|
|
if A == 'Coffee' and B == 'Green': return same
|
|
if A == 'Green' and B == 'Ivory': return (a - 1) == b
|
|
if recurse == 0: return zebra_constraint(B, b, A, a, 1)
|
|
if ((A in Colors and B in Colors) or
|
|
(A in Pets and B in Pets) or
|
|
(A in Drinks and B in Drinks) or
|
|
(A in Countries and B in Countries) or
|
|
(A in Smokes and B in Smokes)): return not same
|
|
raise 'error'
|
|
return CSP(vars, domains, neighbors, zebra_constraint)
|
|
|
|
def solve_zebra(algorithm=min_conflicts, **args):
|
|
z = Zebra()
|
|
ans = algorithm(z, **args)
|
|
for h in range(1, 6):
|
|
print 'House', h,
|
|
for (var, val) in ans.items():
|
|
if val == h: print var,
|
|
print
|
|
return ans['Zebra'], ans['Water'], z.nassigns, ans,
|
|
|
|
|
|
|#
|