Combinatorial Functions

Combinatorial Functions Recursion for problem solving L14Comb

Enumerating Initial segments (prefixes) inits [1,2,3] = [[],[1],[1,2],[1,2,3]] inits [2,3] = [ [], [2], [2,3] ] fun inits [] = [[]] | inits (x::xs) = []:: (map (fn ys => x::ys) (inits xs) ); fun inits [] = [[]] | inits xs = (inits (init xs))@[xs]; L14Comb

Enumerating Subsequences subseq [2,3] = [[],[2],[3],[2,3]]; subseq [1,2,3] = [[], [1],[2],[3], [1,2],[1,3],[2,3],[1,2,3] ]; fun subseq [] = [[]] | subseq (x::xs) = letval ss = subseq xs in ss@(map (fn ys => x::ys) ss) end; L14Comb

Enumerating permutations perms [2] = [[2]] perms [1,2] = [[1,2], [2,1]] perms [0,1,2] = [[0,1,2],[1,0,2],[1,2,0], [0,2,1],[2,0,1],[2,1,0]] fun interleave x [] = [[x]] | interleave x (y::ys) = (x::y::ys) :: (map(fn xs=>y::xs)(interleave x ys)); fun perms [] = [[]] | perms (x::xs) = foldr (op @) [] (map (interleave x) (perms xs)) ; L14Comb

List partitions • The list of non-empty lists [L1,L2,…,Lm] forms a list-partition of a list Liff concat [L1,L2,…,Lm] = L [1,2] -> [[[1,2]], [[1],[2]]] [0,1,2] -> [ [[0,1,2]], [[0,1],[2]], [[0],[1,2]], [[0],[1],[2]] ] L14Comb

Counting problem fun cnt_lp 0 = 0 | cnt_lp 1 = 1 | cnt_lp n = 2 * (cnt_lp (n-1)); (* cnt_lp n = 2^(n-1) for n > 0 *) Property: cnt_lp (length xs) = (length (list_partition xs)) L14Comb

Constructing List Partitions fun lp [] = [] | lp (x::[]) = [ [[x]] ] | lp (y::x::xs) = letval aux = lp (x::xs) in (map (fn ss => [y]::ss) aux) @ (map (fn ss => (y::(hd ss)) :: (tl ss)) aux) end; L14Comb

Set partition • The set of (non-empty) sets [s1,s2,…,sm] forms a set partition of siff the sets si’s are collectively exhaustive and pairwise-disjoint. • E.g., set partitions of{1,2,3} -> { {{1,2,3}}, { {1}, {2,3}}, {{1,2}, {3}}, {{2}, {1,3}}, { {1},{2},{3}} } (Cf. list partition, number partition, etc.) L14Comb

Divide and Conquer m-partition of {1,2,3} 1occurring with with a part in m-partition of {2,3} (m-1)-partition of {2,3} solitary part{1}:: 2-partitions of {1,2,3} = {{ {1},{2,3}} } U {{{1,2},{3} } , { {2},{1,3} }} L14Comb

Counting problem fun cnt_m_sp 1 n = 1 | cnt_m_sp m n = if m > n then 0 elseif m = n then 1 else (cnt_m_sp (m-1) (n-1)) + (m * (cnt_m_sp m (n-1))); • Dependency (visualization) • Basis: Row 1 and diagonal (Half-plane inapplicable) • Recursive step: Previous row, previous column L14Comb

(cont’d) upto 3 6 = [3,4,5,6] fun upto m n = if (m > n) then [] else if (m = n) then [m] else m:: upto (m+1) n; fun cnt_sp n = foldr (op +) 0 (map (fn m => cnt_m_sp m n) (upto 1 n)); L14Comb

Constructing set partitions fun set_parts s = foldr (op@) [] ( map (fn m => (m_set_parts m s)) (upto 1 (length s)) ); fun ins_all e [] = [] | ins_all e (s::ss) = (((e::s)::ss) :: ( map (fnts => s :: ts) (ins_all e ss))); L14Comb

fun m_set_parts 1 s = [[s]] | m_set_parts m (s as hs::ts)= letval n = (length s) in if m > n then [] else if m = n then [foldr (fn (e,ss)=>[e]::ss ) [] s] elselet val p1 = (m_set_parts (m-1) ts) val p2 = (m_set_parts m ts) in (map (fn ss => [hs]::ss) p1) @ (foldr (op@) [](map (ins_all hs) p2 )) end end; L14Comb

Combinatorial Functions

Combinatorial Functions

Presentation Transcript

Combinatorial testing

Combinatorial chemistry

Combinatorial Chemistry

Combinatorial Optimization

Approximability of Combinatorial Optimization Problems with Submodular Cost Functions

Combinatorial Chemistry

COMBINATORIAL CHEMISTRY AND DYNAMIC COMBINATORIAL CHEMISTRY

Combinatorial Betting

Combinatorial Chemistry

Combinatorial Auction

Combinatorial auctions

Combinatorial Algorithms

Combinatorial Optimization

Combinatorial Search

Combinatorial Background

Combinatorial Mathematics

Combinatorial auctions

COMBINATORIAL CONFIGURATIONS

Combinatorial Auction