Okasaki's implementation in *Purely Functional Data Structures* (page 22) does it in two: one to merge the forest, and one to propagate the carries. This strikes me as harder to analyze, and also probably slower, than a one-pass version. Am I missing something?

Okasaki's implementation:

functor BinomialHeap (Element:ORDERED):HEAP= struct structure Elem=Element datatype Tree = Node of int*Elem.T*Tree list type Heap = Tree list fun link (t1 as Node (r,x1,c1), t2 as Node (_,x2,c2))= if Elem.leq(x1,x2) then Node (r+1,x1,t2::c1) else Node (r+1,x2,t1::c2) fun insTree (t,[])=[t] |insTree (t,ts as t'::ts')= if rank t < rank t' then t::ts else insTree(link(t,t'),ts') fun insert (x,ts)=insTree(Node(0,x,[]),ts) (*just for reference*) fun merge (ts1,[])=ts1 |merge ([],ts2)=ts2 |merge (ts1 as t1::ts1', ts2 as t2:ts2')= if rank t1 < rank t2 then t1::merge(ts1',ts2) else if rank t2 < rank t1 then t2::merge(ts1,ts2') else insTree (link(t1,t2), merge (ts1',ts2')) end

This strikes me as hard to analyze because you have to prove an upper bound on the cost of propagating all the carries (see below). The top-down merge implementation I came up with is much more obviously O(log n) where n is the size of the larger heap:

functor BinomialHeap (Element:ORDERED):HEAP= struct structure Elem=Element datatype Tree = Node of int*Elem.T*Tree list type Heap = Tree list fun rank (Node(r,_,_))=r fun link (t1 as Node (r,x1,c1), t2 as Node (_,x2,c2))= if Elem.leq(x1,x2) then Node (r+1,x1,t2::c1) else Node (r+1,x2,t1::c2) fun insTree (t,[])=[t] |insTree (t,ts as t'::ts')= if rank t < rank t' then t::ts else insTree(link(t,t'),ts') fun insert (x,ts)=insTree(Node(0,x,[]),ts) fun merge(ts1,[])=ts1 |merge([],ts2)=ts2 |merge (ts1 as t1::ts1', ts2 as t2::ts2')= if rank t1 < rank t2 then t1::merge(ts1',ts2) else if rank t2 < rank t1 then t2::merge(ts1,ts2') else mwc(link(t1,t2),ts1',ts2') (*mwc=merge with carry*) and mwc (c,ts1,[])=insTree(c,ts1) |mwc (c,[],ts2)=insTree(c,ts2) |mwc (c,ts1 as t1::ts1', ts2 as t2::ts2')= if rank c < rank t1 then if rank c < rank t2 then c::merge(ts1,ts2) else mwc(link(c,t2),ts1,ts2') else mwc(link(c,t1),ts1',ts2) end

Proof that Okasaki's implementation is O(log n): if a carry is "expensive" (requires one or more links), then it produces a zero. Therefore the next expensive carry will stop when it reaches that point. So the total number of links required to propagate all the carries is no more than around the total length of the binary representation before propagation, which is bounded above by ceil(log n), where n is the size of the larger heap.