Dave Reed

Dave Reed • AI as search • problem states, state spaces • uninformed search strategies • depth first search • depth first search with cycle checking • breadth first search • iterative deepening

AI as search • GOFAI philosophy: Problem Solving = Knowledge Representation + Search (a.k.a. deduction) • to build a system to solve a problem: • define the problem precisely i.e., describe initial situation, goals, … • analyze the problem • isolate and represent task knowledge • choose an appropriate problem solving technique we'll look at a simple representation (states) first & focus on search more advanced representation techniques will be explored later

Example: airline connections • suppose you are planning a trip from Omaha to Los Angeles initial situation: located in Omaha goal: located in Los Angeles possible flights: Omaha  Chicago Denver  Los Angeles Omaha  Denver Denver  Omaha Chicago  Denver Los Angeles  Chicago Chicago  Los Angeles Los Angeles  Denver Chicago  Omaha • this is essentially the same problem as the earlier city connections • we could define special purpose predicates, recursive rules to plan route flight(omaha, chicago). flight(denver, los_angeles). . . . route(City1, City2, [City1,City2]) :- flight(City1, City2). route(City1, City2, [City1|Rest]) :- flight(City1, City3), route(City3, City2, Rest).

State spaces • or, could define a more general solution framework state : a situation or position state space : the set of legal/attainable states for a given problem • a state space can be represented as a directed graph (nodes = states) • in general: to solve a problem • define a state space, then search for a path from start state to a goal state

Example: airline state space • define a state with: loc(City) • define state transitions with: move(loc(City1), loc(City2)) • to find a route from Omaha to Los Angeles: • search for a sequence of transitions from start state to goal state: loc(omaha)  loc(los_angeles) %%% travel.pro Dave Reed 2/15/02 %%% %%% This file contains the state space definition %%% for air travel. %%% %%% loc(City): defines the state where the person %%% is in the specified City. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% move(loc(omaha), loc(chicago)). move(loc(omaha), loc(denver)). move(loc(chicago), loc(denver)). move(loc(chicago), loc(los_angeles)). move(loc(chicago), loc(omaha)). move(loc(denver), loc(los_angeles)). move(loc(denver), loc(omaha)). move(loc(los_angeles), loc(chicago)). move(loc(los_angeles), loc(denver)).

Example: water jug problem • Suppose you have two empty water jugs: • large jug can hold 4 gallons, small jug can hold 3 gallons • starting with empty jugs (and an endless supply of water), want to end up with exactly 2 gallons in the large jug • state? • start state? • goal state? • transitions?

Example: water jug state space • define a state with: jugs(LargeJug, SmallJug) • define state transitions with: move(jugs(J1,J2), jugs(J3,J4)) • to solve the problem: • search for a sequence of transitions from start state to goal state: jugs(0,0)  jugs(2,0) %%% jugs.pro Dave Reed 2/15/02 %%% %%% This file contains the state space definition %%% for the Water Jug problem. %%% %%% jugs(J1, J2): J1 is the contents of the large %%% (4 gallon) jug, and J2 is the contents of %%% the small (3 gallon) jug. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% move(jugs(J1,J2), jugs(4,J2)) :- J1 < 4. move(jugs(J1,J2), jugs(J1,3)) :- J2 < 3. move(jugs(J1,J2), jugs(0,J2)) :- J1 > 0. move(jugs(J1,J2), jugs(J1,0)) :- J2 > 0. move(jugs(J1,J2), jugs(4,N)) :- J2 > 0, J1 + J2 >= 4, N is J2 - (4 - J1). move(jugs(J1,J2), jugs(N,3)) :- J1 > 0, J1 + J2 >= 3, N is J1 - (3 - J2). move(jugs(J1,J2), jugs(N,0)) :- J2 > 0, J1 + J2 < 4, N is J1 + J2. move(jugs(J1,J2), jugs(0,N)) :- J1 > 0, J1 + J2 < 3, N is J1 + J2.

Example: 8-tiles puzzle • Consider the children's puzzle with 8 sliding tiles in a 3x3 board • a tile adjacent to the empty space can be shifted into that space • goal is to arrange the tiles in increasing order around the outside • state? • start state? • goal state? • transitions?

Example: 8-tiles state space • define a state with: tiles(Row1,Row2,Row3) • define state transitions with: move(tiles(R1,R2,R3), tiles(R4,R5,R6)). • to solve the problem: • search for a sequence of transitions from start state to goal state: tiles([1,2,3],[8,6,space],[7,5,4])  tiles([1,2,3],[8,space,4],[7,6,5]) %%% puzzle.pro Dave Reed 2/15/02 %%% %%% This file contains an UGLY, BRUTE-FORCE state %%% space definition for the 8-puzzle problem. %%% %%% tiles(R1, R2, R3): each row is a list of three %%% numbers (or space) specifying the tiles in %%% that row. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% move(tiles([space,T1,T2],[T3,T4,T5],[T6,T7,T8]), tiles([T1,space,T2],[T3,T4,T5],[T6,T7,T8])). move(tiles([space,T1,T2],[T3,T4,T5],[T6,T7,T8]), tiles([T3,T1,T2],[space,T4,T5],[T6,T7,T8])). move(tiles([T1,space,T2],[T3,T4,T5],[T6,T7,T8]), tiles([space,T1,T2],[T3,T4,T5],[T6,T7,T8])). move(tiles([T1,space,T2],[T3,T4,T5],[T6,T7,T8]), tiles([T1,T2,space],[T3,T4,T5],[T6,T7,T8])). move(tiles([T1,space,T2],[T3,T4,T5],[T6,T7,T8]), tiles([T1,T4,T2],[T3,space,T5],[T6,T7,T8])). move(tiles([T1,T2,space],[T3,T4,T5],[T6,T7,T8]), tiles([T1,space,T2],[T3,T4,T5],[T6,T7,T8])). move(tiles([T1,T2,space],[T3,T4,T5],[T6,T7,T8]), tiles([T1,T2,T5],[T3,T4,space],[T6,T7,T8])). . . .

State space + control • once you formalize a problem by defining a state space: • you need a methodology for applying actions/transitions to search through the space (from start state to goal state) i.e., you need a control strategy • control strategies can be: tentative or bold; informed or uninformed • a bold strategy picks an action/transition, does it, and commits • a tentative strategy burns no bridges • an informed strategy makes use of problem-specific knowledge (heuristics) to guide the search • an uninformed strategy is blind

Uninformed strategies • bold + uninformed: STUPID! • tentative + uninformed: • depth first search (DFS) • breadth first search (BFS) example: water jugs state space (drawn as a tree with duplicate nodes)

Depth first search • basic idea: • if the current state is a goal, then SUCCEED • otherwise, move to a next state and DFS from there • if no next state (i.e., deadend), then BACKTRACK %%% dfs.pro Dave Reed 2/15/02 %%% %%% Depth first search %%% dfs(Current, Goal): succeeds if there is %%% a sequence of states that lead from %%% Current to Goal %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% dfs(Goal, Goal). dfs(State, Goal) :- move(State, NextState), dfs(NextState, Goal). • note: Prolog computation is basically depth first search • if goal list is empty, SUCCEED • otherwise, find fact/rule that matches the first goal & replace the goal with the rule premises (if any) • if no matching fact/rule, then BACKTRACK

Depth first search • generally, want to not only know that a path exists, but what states are in that path • i.e., what actions lead from start state to goal state? %%% dfs.pro Dave Reed 2/15/02 %%% %%% Depth first search %%% dfs(Current, Goal, Path): Path is a list %%% of states that lead from Current to Goal %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% dfs(Goal, Goal, [Goal]). dfs(State, Goal, [State|Path]) :- move(State, NextState), dfs(NextState, Goal, Path). • add an argument to the dfs predicate, which "returns" the path • if current state is a goal, then path is just that state • otherwise, make a move and use recursion to find a path from that new state (but must add that state back onto path)

DFS examples ?- dfs(loc(omaha), loc(los_angeles), Path). Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles), loc(chicago), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles), loc(chicago), loc(denver), loc(los_angeles), loc(chicago), loc(...)|...] Yes all are legitimate paths, but not "optimal" ?- dfs(jugs(0,0), jugs(2,0), Path). ERROR: Out of local stack WHY? ?- dfs(tiles([1,2,3],[8,6,space],[7,5,4]), tiles([1,2,3],[8,space,4],[7,6,5]), Path). ERROR: Out of local stack WHY?

DFS and cycles • since DFS moves blindly down one path, • looping (cycles) is a SERIOUS problem

Depth first search with cycle checking • it often pays to test for cycles (as in city connections example): • must keep track of the path so far • make sure current goal is not revisited %%% dfsnocyc.pro Dave Reed 2/15/02 %%% %%% Depth first search with cycle checking %%% dfs_no_cycles(Current, Goal, Path): Path is a list %%% of states that lead from Current to Goal %%% %%% dfs_nocyc_help(PathSoFar, Goal, Path): Path is a list %%% of states that lead from the PathSoFar (with current %%% state at the head) to Goal without duplicate states. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% dfs_no_cycles(State, Goal, Path) :- dfs_nocyc_help([State], Goal, RevPath), reverse(RevPath, Path). dfs_nocyc_help([Goal|PathSoFar], Goal, [Goal|PathSoFar]). dfs_nocyc_help([State|PathSoFar], Goal, Path) :- move(State, NextState), not(member(NextState, [State|PathSoFar])), dfs_nocyc_help([NextState,State|PathSoFar], Goal, Path).

Examples w/ cycle checking ?- dfs_no_cycles(loc(omaha), loc(los_angeles), Path). Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(los_angeles)] ; Path = [loc(omaha), loc(denver), loc(los_angeles)] ; No finds all paths that don’t have cycles ?- dfs_no_cycles(jugs(0,0), jugs(2,0), Path). Path = [jugs(0, 0), jugs(4, 0), jugs(4, 3), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(0, 2), jugs(..., ...)] ; Path = [jugs(0, 0), jugs(4, 0), jugs(1, 3), jugs(4, 3), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(..., ...)|...] Yes finds solutions, but not optimal (SWI uses … for long answers) ?- dfs(tiles([1,2,3],[8,6,space],[7,5,4]), tiles([1,2,3],[8,space,4],[7,6,5]), Path). ERROR: Out of local stack but it takes longer…

Breadth vs. depth • even with cycle checking, DFS may not find the shortest solution • breadth first search (BFS) • extend the search one level at a time • i.e., from the start state, try every possible move (& remember them all) • if don't reach goal, then try every possible move from those states • . . . • requires keeping a list of partially expanded search paths • ensure breadth by treating the list as a queue • when want to expand shortest path: take off front, extend & add to back [ omaha ] [ chicagoomaha, denveromaha ] [ denveromaha, denverchicagoomaha, los_angeleschicagoomaha, omahachicagoomaha ] [ denverchicagoomaha, los_angeleschicagoomaha, omahachicagoomaha, los_angelesdenveromaha, omahadenveromaha ] [ los_angeleschicagoomaha, omahachicagoomaha, los_angelesdenveromaha, omahadenveromaha, los_angelesdenverchicagoomaha, omahadenverchicagoomaha ]

Breadth first search %%% bfs.pro Dave Reed 2/15/02 %%% %%% Breadth first search %%% bfs(Current, Goal, Path): Path is a list %%% of states that lead from Current to Goal %%% %%% bfs_help(ListOfPaths, Goal, Path): Path is a list %%% of states that lead from one of the paths in ListOfPaths %%% (a list of lists) to Goal. %%% %%% extend(Path, ListOfPaths): ListOfPaths is the list of all %%% possible paths obtainable by extending Path (at the head). %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% bfs(State, Goal, Path) :- bfs_help([[State]], Goal, RevPath), reverse(RevPath, Path). bfs_help([[Goal|Path]|_], Goal, [Goal|Path]). bfs_help([Path|RestPaths], Goal, SolnPath) :- extend(Path, NewPaths), append(RestPaths, NewPaths, TotalPaths), bfs_help(TotalPaths, Goal, SolnPath). extend([State|Path], NewPaths) :- bagof([NextState,State|Path], move(State,NextState), NewPaths), !. extend(_, []). • bagof(X,p(X),List): • List is a list of all X's for which p(X) holds • equivalent to hitting ';' repeatedly to exhaust all answers, then putting them in a list • ! • exclamation point is the cut operator • it cuts choice points, committing the interpreter to that match

BFS examples ?- bfs(loc(omaha), loc(los_angeles), Path). Path = [loc(omaha), loc(chicago), loc(los_angeles)] ; Path = [loc(omaha), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(los_angeles), loc(chicago), loc(los_angeles)] Yes finds shorter paths first, but no loop checking ?- bfs(jugs(0,0), jugs(2,0), Path). Path = [jugs(0, 0), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(0, 2), jugs(2, 0)] ; Path = [jugs(0, 0), jugs(4, 0), jugs(1, 3), jugs(1, 0), jugs(0, 1), jugs(4, 1), jugs(2, 3), jugs(2, 0)] ; Path = [jugs(0, 0), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(4, 2), jugs(0, 2), jugs(2, 0)] Yes finds shorter paths first, but slow (& looping is possible) ?- bfs(tiles([1,2,3],[8,6,space],[7,5,4]), tiles([1,2,3],[8,space,4],[7,6,5]), Path). Path = [tiles([1, 2, 3], [8, 6, space], [7, 5, 4]), tiles([1, 2, 3], [8, 6, 4], [7, 5, space]), tiles([1, 2, 3], [8, 6, 4], [7, space, 5]), tiles([1, 2, 3], [8, space, 4], [7, 6, 5])] Yes it works!

Breadth first search w/ cycle checking %%% bfs.pro Dave Reed 2/15/02 %%% Breadth first search with cycle checking %%% bfs(Current, Goal, Path): Path is a list of states %%% that lead from Current to Goal with no duplicate states. %%% %%% bfs_help(ListOfPaths, Goal, Path): Path is a list %%% of states that lead from one of the paths in ListOfPaths %%% (a list of lists) to Goal with no duplicate states. %%% %%% extend(Path, ListOfPaths): ListOfPaths is the list of all %%% possible paths obtainable by extending Path (at the head) %%% with no duplicate states. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% bfs(State, Goal, Path) :- bfs_help([[State]], Goal, RevPath), reverse(RevPath, Path). bfs_help([[Goal|Path]|_], Goal, [Goal|Path]). bfs_help([Path|RestPaths], Goal, SolnPath) :- extend(Path, NewPaths), append(RestPaths, NewPaths, TotalPaths), bfs_help(TotalPaths, Goal, SolnPath). extend([State|Path], NewPaths) :- bagof([NextState,State|Path], (move(State, NextState), not(member(NextState, [State|Path]))), NewPaths), !. extend(_, []). since you are already having to store entire paths for BFS, cycle checking is easy when extending, exclude states already on the path

Examples w/ cycle checking ?- bfs(loc(omaha), loc(los_angeles), Path). Path = [loc(omaha), loc(chicago), loc(los_angeles)] ; Path = [loc(omaha), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles)] ; No finds all paths without cycles, shorter paths first ?- bfs(jugs(0,0), jugs(2,0), Path). Path = [jugs(0, 0), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(0, 2), jugs(2, 0)] ; Path = [jugs(0, 0), jugs(4, 0), jugs(1, 3), jugs(1, 0), jugs(0, 1), jugs(4, 1), jugs(2, 3), jugs(2, 0)] ; Path = [jugs(0, 0), jugs(4, 0), jugs(4, 3), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(0, 2), jugs(..., ...)] Yes finds 14 unique paths, shorter paths first ?- bfs(tiles([1,2,3],[8,6,space],[7,5,4]), tiles([1,2,3],[8,space,4],[7,6,5]), Path). Path = [tiles([1, 2, 3], [8, 6, space], [7, 5, 4]), tiles([1, 2, 3], [8, 6, 4], [7, 5, space]), tiles([1, 2, 3], [8, 6, 4], [7, space, 5]), tiles([1, 2, 3], [8, space, 4], [7, 6, 5])] Yes same as before (by definition, shortest path will not have cycle)

DFS vs. BFS • Advantages of DFS • requires less memory than BFS since only need to remember the current path • if lucky, can find a solution without examining much of the state space • with cycle-checking, looping can be avoided • Advantages of BFS • guaranteed to find a solution if one exists – in addition, finds optimal (shortest) solution first • will not get lost in a blind alley (i.e., does not require backtracking or cycle checking) • can add cycle checking with very little cost note: just because BFS finds the optimal solution, it does not necessarily mean that it is the optimal control strategy!

Iterative deepening • interesting hybrid: DFS with iterative deepening • alter DFS to have a depth bound • (i.e., search will fail if it extends beyond a specific depth bound) • repeatedly call DFS with increasing depth bounds until a solution is found • DFS with bound = 1 • DFS with bound = 2 • DFS with bound = 3 • . . . • advantages: • yields the same solutions, in the same order, as BFS • doesn't have the extensive memory requirements of BFS • disadvantage: • lots of redundant search – each time the bound is increased, the entire search from the previous bound is redone!

Depth first search with iterative deepening %%% dfsdeep.pro Dave Reed 2/15/02 %%% Depth first search with iterative deepening %%% dfs_deep(Current, Goal, Path): Path is a list of states %%% that lead from Current to Goal. %%% %%% dfs_deep_help(State, Goal, Path, DepthBound): Path is a %%% list of states (length = DepthBound) that lead from %%% State to Goal. THIS PREDICATE PERFORMS THE ITERATIVE %%% DEEPENING BY INCREASING THE DEPTH BOUND BY 1 EACH TIME. %%% %%% dfs_bounded(State, Goal, Path, DepthBound): Path is a %%% list of states (length = DepthBound) that lead from %%% State to Goal. THIS PREDICATE PERFORMS THE BOUNDED DFS, %%% REQUIRING A SOLUTION THAT IS EXACTLY DepthBound LONG. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% dfs_deep(State, Goal, Path) :- dfs_deep_help(State, Goal, Path, 1). dfs_deep_help(State, Goal, Path, DepthBound) :- dfs_bounded(State, Goal, Path, DepthBound). dfs_deep_help(State, Goal, Path, DepthBound) :- NewDepth is DepthBound + 1, dfs_deep_help(State, Goal, Path, NewDepth). dfs_bounded(Goal, Goal, [Goal], 1). dfs_bounded(State, Goal, [State|Path], DepthBound) :- DepthBound > 0, move(State, NextState), NewDepth is DepthBound - 1, dfs_bounded(NextState, Goal, Path, NewDepth). can even set up the bounds checking so that answers are not revisited on each pass – only report answer first time it is found

DFS w/ iterative deepening & cycle checking %%% dfsdeep.pro Dave Reed 2/15/02 %%% Depth first search with iterative deepening & cycle checking %%% dfs_deep(Current, Goal, Path): Path is a list of states %%% that lead from Current to Goal, with no duplicate states. %%% %%% dfs_deep_help(State, Goal, Path, DepthBound): Path is a %%% list of states (length = DepthBound) that lead from %%% State to Goal, with no duplicate states. THIS PREDICATE %%% PERFORMS THE ITERATIVE DEEPENING BY INCREASING THE DEPTH %%% BOUND BY 1 EACH TIME. %%% %%% dfs_bounded(State, Goal, Path, DepthBound): Path is a %%% list of states (length = DepthBound) that lead from %%% State to Goal with no duplicate states. THIS PREDICATE %%% PERFORMS THE BOUNDED DFS, REQUIRING A SOLUTION THAT IS %%% EXACTLY DepthBound LONG. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% dfs_no_cycles_deep(State, Goal, Path) :- dfs_deep_help([State], Goal, RevPath, 1), reverse(RevPath, Path). dfs_deep_help(PathSoFar, Goal, Path, DepthBound) :- dfs_bounded(PathSoFar, Goal, Path, DepthBound). dfs_deep_help(PathSoFar, Goal, Path, DepthBound) :- NewDepth is DepthBound + 1, dfs_deep_help(PathSoFar, Goal, Path, NewDepth). dfs_bounded([Goal|PathSoFar], Goal, [Goal|PathSoFar], 1). dfs_bounded([State|PathSoFar], Goal, Path, DepthBound) :- DepthBound > 0, move(State, NextState), not(member(NextState, [State|PathSoFar])) , NewDepth is DepthBound - 1, dfs_bounded([NextState,State|PathSoFar], Goal, Path, NewDepth). as with DFS, can add cycle checking by storing the current path and checking for duplicate states

Examples w/ cycle checking ?- dfs_no_cycles_deep(loc(omaha), loc(los_angeles), Path). Path = [loc(omaha), loc(chicago), loc(los_angeles)] ; Path = [loc(omaha), loc(denver), loc(los_angeles)] ; Path = [loc(omaha), loc(chicago), loc(denver), loc(los_angeles)] ; finds same answers as BFS, but hangs after last answer -- WHY? ?- dfs_no_cycles_deep(jugs(0,0), jugs(2,0), Path). Path = [jugs(0, 0), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(0, 2), jugs(2, 0)] ; Path = [jugs(0, 0), jugs(4, 0), jugs(1, 3), jugs(1, 0), jugs(0, 1), jugs(4, 1), jugs(2, 3), jugs(2, 0)] ; Path = [jugs(0, 0), jugs(4, 0), jugs(4, 3), jugs(0, 3), jugs(3, 0), jugs(3, 3), jugs(4, 2), jugs(0, 2), jugs(..., ...)] Yes finds same answers as BFS, but similarly hangs ?- bfs(tiles([1,2,3],[8,6,space],[7,5,4]), tiles([1,2,3],[8,space,4],[7,6,5]), Path). Path = [tiles([1, 2, 3], [8, 6, space], [7, 5, 4]), tiles([1, 2, 3], [8, 6, 4], [7, 5, space]), tiles([1, 2, 3], [8, 6, 4], [7, space, 5]), tiles([1, 2, 3], [8, space, 4], [7, 6, 5])] Yes finds same answers as BFS, noticeably faster

Cost of iterative deepening • just how costly is iterative deepening? 1st pass searches entire tree up to depth 1 2nd pass searches entire tree up to depth 2 (including depth 1) 3rd pass searches entire tree up to depth 3 (including depths 1 & 2) • in reality, this duplication is not very costly at all! • Theorem: Given a "full" tree with constant branching factor B, the number of nodes at any given level is greater than the number of nodes in all levels above. • e.g., Binary tree (B = 2): 1  2  4  8  16  32  64  128  … • repeating the search of all levels above for each pass merely doubles the amount of work for each pass. • in general, this repetition only increases the cost by a constant factor < (B+1)/(B-1)

Dave Reed

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