\input macros.tex
\fi
-\chapter{Approaching Optimality}
+\chapter{Approaching Optimality}\id{optchap}%
\section{Soft heaps}
new left son to the parent. This way we obey the heap order and at the same time we keep
the white left son free of items.
-Ocassionally, we repeat this process once again and we concatenate the resulting lists
+Occasionally, we repeat this process once again and we concatenate the resulting lists
(we append the latter list to the former, using the smaller of the two \<ckey>'s). This
makes the lists grow longer and we want to do that roughly on every other level of the
tree. The exact condition will be that either the rank of the current vertex is odd,
(we report this by setting its \<ckey> to $+\infty$), the current vertex is no longer
needed --- the items would just pass through it unmodified. We therefore want to
remove it. Instead of deleting it directly, we rather make it point to its former
-grandsons and we remove the (now orhpaned) original son. This helps us to ensure
+grandsons and we remove the (now orphaned) original son. This helps us to ensure
that both sons always keep the same rank, which will be useful for the analysis.
When all refilling is done, we update the suffix minima by walking from the current
all queues in the heap, walks the trees and the item lists of all vertices. It records
all items seen, the corrupted ones are those that different from their \<ckey>.
-\paran{Analysis of accuracy}
+\paran{Analysis of accuracy}%
The description of the operations is now complete, so let us analyse their behavior
and verify that we have delivered what we promised --- first the accuracy of
the structure, then the time complexity of operations. In the whole analysis,
$$\ell(v) \le \max(1, 2^{\lceil \<rank>(v)/2 \rceil - r/2}).$$
\proof
-Initially, all item lists contain at most one item, so the ineqality trivially
+Initially, all item lists contain at most one item, so the inequality trivially
holds. Let us continue by induction. Melds can affect it only in the favorable
-direction (they ocassionally move an~item list to a~vertex of a~higher rank)
+direction (they occasionally move an~item list to a~vertex of a~higher rank)
and so do deletes (they only remove items from lists). The only potentially
dangerous place is the \<Refill> procedure.
this makes less than $n_k/2^{r-2}$ corrupted items as we asserted.
\qed
-\paran{Analysis of time complexity}
+\paran{Analysis of time complexity}%
Now we will examine the amortized time complexity of the individual operations.
We will show that if we charge $\O(r)$ time against every element inserted, it is enough
to cover the cost of all other operations.
Before we estimate the time spent on deletions, we analyse the refills.
\lemma
-Every invokation of the \<Refill> procedure takes time $\O(1)$ amortized.
+Every invocation of the \<Refill> procedure takes time $\O(1)$ amortized.
\proof
When \<Refill> is called from the \<DeleteMin> operation, it recurses on a~subtree of the
\rem
When we set $\varepsilon = 1/2n$, the soft heap is not allowed to corrupt any
-items, so it can be used like any usual heap. By the standard lower bound on
+items, so it can be used like any traditional heap. By the standard lower bound on
sorting it therefore requires $\Omega(\log n)$ time per operation, so the
time complexity is optimal for this choice of~$\varepsilon$. Chazelle \cite{chazelle:softheap}
proves that it is optimal for every choice of~$\varepsilon$.
The space consumed by the heap need not be linear in the \em{current} number
-of items, but if a~case where this matters ever occured, we could fix it easily
+of items, but if a~case where this matters ever occurred, we could fix it easily
by rebuilding the whole data structure completely after $n/2$ deletes. This
increases the number of potentially corrupted items, but at worst twice, so it
suffices to decrease~$\varepsilon$ twice.
\section{Robust contractions}
Having the soft heaps at hand, we would like to use them in a~conventional MST
-algorithm in place of a~usual heap. The most efficient specimen of a~heap-based
+algorithm in place of a~normal heap. The most efficient specimen of a~heap-based
algorithm we have seen so far is the Iterated Jarn\'\i{}k's algorithm (\ref{itjar}).
It is based on a~simple, yet powerful idea: Run the Jarn\'\i{}k's algorithm with
-limited heap size, so that it stops when the neighborhood of the tree becomes
+limited heap size, so that it stops when the neighborhood of the tree becomes too
large. Grow multiple such trees, always starting in a~vertex not visited yet. All
these trees are contained in the MST, so by the Contraction lemma
(\ref{contlemma}) we can contract each of them to a~single vertex and iterate
the algorithm on the resulting graph.
-We can try implanting the soft heap in this algorithm, preferably in the original
+We can try implanting the soft heap in this algorithm, preferably in its earlier
version without active edges (\ref{jarnik}) as the soft heap lacks the \<Decrease>
-operation. This honest, but somewhat simple-minded attempt is however doomed to
+operation. This brave, but somewhat simple-minded attempt is however doomed to
fail. The reason is of course the corruption of items inside the heap, which
-leads to increase of weights of a~subset of edges. In presence of corrupted
+leads to increase of weights of some subset of edges. In presence of corrupted
edges, most of the theory we have so carefully built breaks down. For example,
the Blue lemma (\ref{bluelemma}) now holds only when we consider a~cut with no
corrupted edges, with a~possible exception of the lightest edge of the cut.
There is fortunately some light in this darkness. While the basic structural
properties of MST's no longer hold, there is a~weaker form of the Contraction
lemma that takes the corrupted edges into account. Before we prove this lemma,
-we will expand our awareness of subgraphs which can be contracted.
+we expand our awareness of subgraphs which can be contracted.
\defn
A~subgraph $C\subseteq G$ is \df{contractible} iff for every pair of edges $e,f\in\delta(C)$\foot{That is,
-edges with exactly one endpoint in~$C$.} there exists a~path in~$C$ connecting the endpoints
+of~$G$'s edges with exactly one endpoint in~$C$.} there exists a~path in~$C$ connecting the endpoints
of the edges $e,f$ such that all edges on this path are lighter than either $e$ or~$f$.
\example\id{jarniscont}%
We can now easily reformulate the Contraction lemma (\ref{contlemma}) in the language
of contractible subgraphs. We again assume that we are working with multigraphs
and that they need not be connected.
-Furthermore, we slightly abuse the notation and we omit the explicit bijection
+Furthermore, we slightly abuse the notation in the way that we omit the explicit bijection
between $G-C$ and~$G/C$, so we can write $G=C \cup (G/C)$.
\lemman{Generalized contraction}
\proof
As both sides of the equality are forests spanning the same graph, it suffices
-to show that $\msf(G) \subseteq \msf(C)\cup\msf(G/C)$. We know that the edges which
-does not participate in the MSF are exactly those which are the heaviest on some cycle
-(this is the Cycle rule \ref{cyclerule}).
+to show that $\msf(G) \subseteq \msf(C)\cup\msf(G/C)$.
+Let us show that edges of~$G$ that do not belong to the right-hand side
+do not belong to the left-hand side either.
+We know that the edges that
+do not participate in the MSF of some graph are exactly those which are the heaviest
+on some cycle (this is the Cycle rule, \ref{cyclerule}).
Whenever an~edge~$g$ lies in~$C$, but not in~$\msf(C)$, then $g$~is the heaviest edge
on some cycle in~$C$. As this cycle is also contained in~$G$, the edge $g$~does not participate
in $\msf(G)$ either.
Similarly for $g\in (G/C)\setminus\msf(G/C)$: when the cycle does not contain
-the vertex~$c$ to which we contracted the subgraph~$C$, the cycle is present
-in~$G$, too. Otherwise we consider the edges $e,f$ adjacent to~$c$ on this cycle.
+the vertex~$c$ to which we have contracted the subgraph~$C$, this cycle is present
+in~$G$, too. Otherwise we consider the edges $e,f$ incident with~$c$ on this cycle.
Since $C$~is contractible, there must exist a~path~$P$ in~$C$ connecting the endpoints
of~$e$ and~$f$ in~$G$, such that all edges of~$P$ are lighter than either $e$ or~$f$
and hence also than~$g$. Expanding~$c$ in the cycle to the path~$P$ then produces
a~cycle in~$G$ whose heaviest edge is~$g$.
\qed
-We are ready to bring corruption back to the game now and state a~``robust'' version
+We are now ready to bring corruption back to the game and state a~``robust'' version
of this lemma. A~notation for corrupted graphs will be handy:
\nota\id{corrnota}%
When~$G$ is a~weighted graph and~$R$ a~subset of its edges, we will use $G\crpt
R$ to denote an arbitrary graph obtained from~$G$ by increasing the weights of
-some of the edges in~$R$. As usually, we will assume that all edge weights in this
-graph are pairwise distinct. While this is technically not true for the corruption
+some of the edges in~$R$. As usually, we will assume that all edges of this graph
+have pairwise distinct weights. While this is technically not true for the corruption
caused by soft heaps, we can easily make the weights unique.
-If~$C$ is a~subgraph of~$G$, we will refer to the edges of~$R$ whose exactly
-one endpoint lies in~$C$ by~$R^C$ (i.e., $R^C = R\cap \delta(C)$).
+Whenever~$C$ is a~subgraph of~$G$, we will use $R^C$ to refer to the edges of~$R$ with
+exactly one endpoint in~$C$ (i.e., $R^C = R\cap \delta(C)$).
-\lemman{Robust contraction}\id{robcont}%
+\lemman{Robust contraction, Chazelle \cite{chazelle:almostacker}}\id{robcont}%
Let $G$ be a~weighted graph and $C$~its subgraph contractible in~$G\crpt R$
-for some set of edges~$R$. Then $\msf(G) \subseteq \msf(C) \cup \msf((G/C) \setminus R^C) \cup R^C$.
+for some set~$R$ of edges. Then $\msf(G) \subseteq \msf(C) \cup \msf((G/C) \setminus R^C) \cup R^C$.
\proof
We will modify the proof of the previous lemma. We will again consider all possible types
-of edges which do not belong to the right-hand side and show that they are the
+of edges which do not belong to the right-hand side and we will show that they are the
heaviest edges of certain cycles. Every edge~$g$ of~$G$ lies either in~$C$, or in $H=(G/C)\setminus R^C$,
or possibly in~$R^C$.
If $g\in C\setminus\msf(C)$, then the same argument as before applies.
-If $g\in H\setminus\msf(H)$, we consider the cycle in~$H$ on which $e$~is the heaviest.
-When $c$ (the vertex to which we have contracted~$C$) is outside this cycle, we are finished.
+If $g\in H\setminus\msf(H)$, we consider the cycle in~$H$ on which $g$~is the heaviest.
+When $c$ (the vertex to which we have contracted~$C$) is outside this cycle, we are done.
Otherwise we observe that the edges $e,f$ adjacent to~$c$ on this cycle cannot be corrupted
(they would be in~$R^C$ otherwise, which is impossible). By contractibility of~$C$ there exists
-a~path~$P$ in~$(G\crpt R)\cup C$ such that all edges of~$P$ are lighter than $e$ or~$f$ and hence
+a~path~$P$ in~$C\crpt (R\cap C)$ such that all edges of~$P$ are lighter than $e$ or~$f$ and hence
also than~$g$. The weights of the edges of~$P$ in the original graph~$G$ cannot be higher than
in~$G\crpt R$, so the path~$P$ is lighter than~$g$ even in~$G$ and we can again perform the
trick with expanding the vertex~$c$ to~$P$ in the cycle~$C$. Hence $g\not\in\mst(G)$.
\qed
\para
-Our plan still is to mimic the Iterative Jarn\'\i{}k's algorithm. We will grow a~collection~$\C$
-of non-overlapping contractible subgraphs and put aside the edges which got corrupted in the process.
-We recursively compute the MSF of the subgraphs and of the contracted graph. Then we take the
+We still intend to mimic the Iterative Jarn\'\i{}k's algorithm. We will partition the given graph to a~collection~$\C$
+of non-overlapping contractible subgraphs called \df{clusters} and we put aside all edges that got corrupted in the process.
+We recursively compute the MSF of that subgraphs and of the contracted graph. Then we take the
union of these MSF's and add the corrupted edges. According to the previous lemma, this does not produce
-the final MSF, but a~sparser graph containing it, on which we can continue.
+the MSF of~$G$, but a~sparser graph containing it, on which we can continue.
-We can formulate the exact partitioning algorithm as follows:
+We can formulate the exact partitioning algorithm and its properties as follows:
-\algn{Partition a~graph to a~collection of contractible subgraphs}\id{partition}%
+\algn{Partition a~graph to a~collection of contractible clusters}\id{partition}%
\algo
-\algin A~graph~$G$ with an~edge comparison oracle, a~parameter~$t$ controlling the size of the subgraphs,
+\algin A~graph~$G$ with an~edge comparison oracle, a~parameter~$t$ controlling the size of the clusters,
and an~accuracy parameter~$\varepsilon$.
\:Mark all vertices as ``live''.
\:$\C\=\emptyset$, $R^\C\=\emptyset$. \cmt{Start with an~empty collection and no corrupted edges.}
\:While there is a~live vertex~$v_0$:
-\::$T=\{v_0\}$. \cmt{the tree we currently grow}
-\::$K=\emptyset$. \cmt{edges known to be corrupted}
-\::\<Create> a~soft heap with accuracy~$\varepsilon$ and \<Insert> the edges adjacent to~$v_0$ in it.
+\::$T=\{v_0\}$. \cmt{the tree that we currently grow}
+\::$K=\emptyset$. \cmt{edges known to be corrupted in the current iteration}
+\::\<Create> a~soft heap with accuracy~$\varepsilon$ and \<Insert> the edges adjacent to~$v_0$ into it.
\::While the heap is not empty and $\vert T\vert \le t$:
\:::\<DeleteMin> an~edge $uv$ from the heap, assume $u\in T$.
\:::If $uv$ was corrupted, add it to~$K$.
\:::$T\=T\cup\{v\}$.
\:::If $v$ is dead, break out of the current loop.
\:::Insert all edges incident with~$v$ to the heap.
-\::$\C\=\C \cup \{G[T]\}$. \cmt{Record the subgraph induced by the tree.}
+\::$\C\=\C \cup \{G[T]\}$. \cmt{Record the cluster induced by the tree.}
\::\<Explode> the heap and add all remaining corrupted edges to~$K$.
-\::$R^\C\=R^\C \cup \{ K^T \}$. \cmt{Record the ``interesting'' corrupted edges.}
+\::$R^\C\=R^\C \cup K^T$. \cmt{Record the ``interesting'' corrupted edges.}
\::$G\=G\setminus K^T$. \cmt{Remove the corrupted edges from~$G$.}
\::Mark all vertices of~$T$ as ``dead''.
-\algout The collection $\C$ of contractible subgraphs and the set~$R^\C$ of
-corrupted edges in the neighborhood of these subgraphs.
+\algout The collection $\C$ of contractible clusters and the set~$R^\C$ of
+corrupted edges in the neighborhood of these clusters.
\endalgo
-\thmn{Partitioning to contractible subgraphs, Pettie and Ramachandran \cite{pettie:optimal}}\id{partthm}%
+\thmn{Partitioning to contractible clusters, Chazelle \cite{chazelle:almostacker}}\id{partthm}%
Given a~weighted graph~$G$ and parameters $\varepsilon$ ($0<\varepsilon\le 1/2$)
-and~$t$, the Partition algorithm \ref{partition} constructs a~collection
-$\C=\{C_1,\ldots,C_k\}$ of subgraphs and a~set~$R^\C$ of corrupted edges such that:
+and~$t$, the Partition algorithm (\ref{partition}) constructs a~collection
+$\C=\{C_1,\ldots,C_k\}$ of clusters and a~set~$R^\C$ of edges such that:
\numlist\ndotted
-\:All the $C_i$'s and the set~$R^\C$ are edge-disjoint.
-\:Each $C_i$ contains at most~$t$ vertices.
-\:Each vertex of~$G$ is contained in at least one~$C_i$.
-\:The connected components of the union of all $C_i$'s have at least~$t$ vertices each,
- except perhaps for those which are equal to a~connected component of~$G\setminus R^\C$.
+\:All the clusters and the set~$R^\C$ are mutually edge-disjoint.
+\:Each cluster contains at most~$t$ vertices.
+\:Each vertex of~$G$ is contained in at least one cluster.
+\:The connected components of the union of all clusters have at least~$t$ vertices each,
+ except perhaps for those which are equal to a~connected component of $G\setminus R^\C$.
\:$\vert R^\C\vert \le 2\varepsilon m$.
\:$\msf(G) \subseteq \bigcup_i \msf(C_i) \cup \msf\bigl((G / \bigcup_i C_i) \setminus R^\C\bigr) \cup R^\C$.
\:The algorithm runs in time $\O(n+m\log (1/\varepsilon))$.
\endlist
\proof
-The algorithm grows a~series of trees. A~tree is built from edges adjacent to live vertices
+Claim~1: The Partition algorithm grows a~series of trees which induce the clusters~$C_i$ in~$G$.
+A~tree is built from edges adjacent to live vertices
and once it is finished, all vertices of the tree die, so no edge is ever reused in another
-tree. Edges of~$R^\C$ are immediately deleted from the graph, so they never participate
-in any tree. The algorithm stops only if all vertices are dead, so each vertex must have
-entered some tree. Each $C_i$ is induced by some tree and the trees have at most~$t$ vertices
-each, which limits the size of the $C_i$'s as well. This proves claims 1--3.
+tree. The edges that enter~$R^\C$ are immediately deleted from the graph, so they never participate
+in any tree.
+
+Claim~2: The algorithm stops when all vertices are dead, so each vertex must have
+entered some tree.
+
+Claim~3: The trees have at most~$t$ vertices each, which limits the size of the
+$C_i$'s as well.
Claim~4: We can show that each connected component has $t$~or more vertices as we already did
-in the proof of Lemma \ref{ijsize}: How can a~new tree stop growing? Either it already
-has~$t$ vertices, or it joins one of the existing trees (which only increases the
+in the proof of Lemma \ref{ijsize}: How can a~new tree stop growing? Either it gathers
+$t$~vertices, or it joins one of the existing trees (this only increases the
size of the component), or the heap becomes empty (which means that the tree spans
-a~full component of the current graph and hence also of~$G\setminus R^\C$).
+a~full component of the current graph and hence also of the final~$G\setminus R^\C$).
Claim~5: The set~$R^\C$ contains a~subset of edges corrupted by the soft heaps over
-the course of the algorithm. As every edge is inserted to a~heap at most once
-in every direction, the heaps can corrupt at worst $2\varepsilon m$ edges altogether.
+the course of the algorithm. As every edge is inserted to a~heap at most once per
+its endpoint, the heaps can corrupt at worst $2\varepsilon m$ edges altogether.
We will prove the remaining two claims as separate lemmata.
\qed
\proof
By iterating the Robust contraction lemma (\ref{robcont}). Let $K_i$ be the set of edges
-corrupted when constructing the subgraph~$C_i$ in the $i$-th phase (iteration of the outer
-loop) of the algorithm, and similarly for the state of the other variables at that time.
+corrupted when constructing the cluster~$C_i$ in the $i$-th phase of the algorithm,
+and similarly for the state of the other variables at that time.
We will use induction on~$i$ to prove that the lemma holds at the end of every phase.
At the beginning, the statement is obviously true, even as an~equality.
-In the $i$-th phase, we construct the subgraph~$C_j$ by running the partial Jarn\'\i{}k's algorithm on the graph
-$G_i = G\setminus\bigcup_{j<i} K_{\smash j}^{\C_j}$.
-If it were not for corruption, the subgraph~$C_i$ would be contractible, as we already know from Example \ref{jarniscont}.
-When the edges in~$K_i$ get corrupted, the subgraph is contractible in some corrupted graph
+In the $i$-th phase we construct the cluster~$C_i$ by running the partial Jarn\'\i{}k's algorithm on the graph
+$G_i = G\setminus\bigcup_{j<i} K_{\smash j}^{C_j}$.
+If it were not for corruption, the cluster~$C_i$ would be contractible, as we already know from Example \ref{jarniscont}.
+When the edges in~$K_i$ get corrupted, the cluster is contractible in some corrupted graph
$G_i \crpt K_i$. (We have to be careful as the edges are becoming corrupted gradually,
-but it is easy to check that it can only improve the situation.) Since $C_i$~is edge-disjoint
-with the previous trees, it is also a~contractible subgraph of $(G_i / \bigcup_{j<i} C_j) \crpt K_i$.
+but it is easy to check that it can only improve the situation.) Since $C_i$~shares no edges
+with~$C_j$ for any~$j<i$, we know that~$C_i$ also a~contractible subgraph of $(G_i / \bigcup_{j<i} C_j) \crpt K_i$.
Now we can use the Robust contraction lemma to show that:
$$
-\msf\biggl(\bigl(G / \bigcup_{i<j} \bigr) \setminus \bigcup_{i<j} K_j^{\C_j} \biggr) \subseteq
-\msf(C_i) \cup \msf\biggl(\bigl(G / \bigcup_{i\le j} \bigr) \setminus \bigcup_{i\le j} K_j^{\C_j} \biggr) \cup K_i^{C_i},
+\msf\biggl(\bigl(G / \bigcup_{j<i} C_j \bigr) \setminus \bigcup_{j<i} K_j^{C_j} \biggr) \subseteq
+\msf(C_i) \cup \msf\biggl(\bigl(G / \bigcup_{j\le i} C_j \bigr) \setminus \bigcup_{j\le i} K_j^{C_j} \biggr) \cup K_i^{C_i}.
$$
-which completes the induction step.
+This completes the induction step, because $K_j^{C_j} = K_j^{\C_j}$ for all~$j$.
\qed
\lemman{Efficiency of Partition, Claim 7 of Theorem \ref{partthm}}
The Partition algorithm runs in time $\O(n+m\log(1/\varepsilon))$.
\proof
-The inner loop (steps 7--13) processes the edges of the current subgraph~$C_i$ and also
-the edges in its neighborhood $\delta(C_i)$. Steps 6 and~13 insert each such edge to the heap
-at most once, so steps 8--12 also visit each edge at most once. For every edge, we spend
+The inner loop (steps 7--13) processes the edges of the current cluster~$C_i$ and also
+the edges in its neighborhood $\delta(C_i)$. Steps 6 and~13 insert every such edge to the heap
+at most once, so steps 8--12 visit each edge also at most once. For every edge, we spend
$\O(\log(1/\varepsilon))$ time amortized on inserting it and $\O(1)$ on the other operations
(by Theorem \ref{softheap} on performance of the soft heaps).
Each edge of~$G$ can participate in some $C_i\cup \delta(C_i)$ only twice before both its
-ends die. The inner loop therefore processes $\O(m)$ edges total, so we spend $\O(m\log(1/\varepsilon))$
-time there. The rest of the algorithm spends $\O(m)$ time on the other operations with subgraphs
-and $\O(n)$ on identifying the live vertices.
+endpoints die. The inner loop therefore processes $\O(m)$ edges total, so it takes $\O(m\log(1/\varepsilon))$
+time. The remaining parts of the algorithm spend $\O(m)$ time on operations with clusters and corrupted edges
+and additionally $\O(n)$ on identifying the live vertices.
\qed
%--------------------------------------------------------------------------------
The Pettie's and Ramachandran's algorithm combines the idea of robust partitioning with optimal decision
trees constructed by brute force for very small subgraphs. In this section, we will
explain the basics of the decision trees and prove several lemmata which will
-turn out to be useful for the analysis of time complexity of the whole algorithm.
+turn out to be useful for the analysis of time complexity of the final algorithm.
-Let us consider all computations of a~comparison-based MST algorithm when we
+Let us consider all computations of some comparison-based MST algorithm when we
run it on a~fixed graph~$G$ with all possible permutations of edge weights.
-They can be described by a~tree. The root of the tree corresponds to the first
+The computations can be described by a~binary tree. The root of the tree corresponds to the first
comparison performed by the algorithm and depending to its result, the computation
continues either in the left subtree or in the right subtree. There it encounters
another comparison and so on, until it arrives to a~leaf of the tree where the
\defnn{Decision trees and their complexity}\id{decdef}%
A~\df{MSF decision tree} for a~graph~$G$ is a~binary tree. Its internal vertices
-are labeled with pairs of edges to be compared, each of the two outgoing edges
-corresponds to one possible result of the comparison.\foot{There is no reason
-to compare an~edge with itself and we, as usually, expect that the edge weights are distinct.}
+are labeled with pairs of $G$'s edges to be compared, each of the two outgoing edges
+corresponds to one possible result of the comparison.\foot{There are two possible
+outcomes since there is no reason to compare an~edge with itself and we, as usually,
+expect that the edge weights are distinct.}
Leaves of the tree are labeled with spanning trees of the graph~$G$.
A~\df{computation} of the decision tree on a~specific permutation of edge weights
The \df{time complexity} of a~decision tree is defined as its depth. It therefore
bounds the number of comparisons spent on every path. (It need not be equal since
some paths need not correspond to an~actual computation --- the sequence of outcomes
-on the path can be unsatifisfiable.)
+on the path could be unsatifisfiable.)
A~decision tree is called \df{optimal} if it is correct and its depth is minimum possible
among the correct decision trees for the given graph.
$D(m,n) \le 4/3 \cdot n^2$.
\proof
-Let us count the comparisons performed by the contractive Bor\o{u}vka's algorithm.
-(\ref{contbor}), tightening up the constants in the original analysis in Theorem
-\ref{contborthm}. In the first phase, each edge participates in two comparisons
+Let us count the comparisons performed by the Contractive Bor\o{u}vka's algorithm.
+(\ref{contbor}), tightening up the constants in its previous analysis in Theorem
+\ref{contborthm}. In the first iteration, each edge participates in two comparisons
(one for each its endpoint), so the algorithm performs at most $2m \le 2{n\choose 2} \le n^2$
comparisons. Then the number of vertices drops at least by a~factor of two, so
-the subsequent phases spend at most $(n/2)^2, (n/4)^2, \ldots$ comparisons, which sums
+the subsequent iterations spend at most $(n/2)^2, (n/4)^2, \ldots$ comparisons, which sums
to less than $n^2\cdot\sum_{i=0}^\infty (1/4)^i = 4/3 \cdot n^2$. Between the phases,
we flatten the multigraph to a~simple graph, which also needs some comparisons,
but for every such comparison we remove one of the participating edges, which saves
will be of course enormous, but as we already promised, we will need the optimal
trees only for very small subgraphs.
-\lemman{Construction of optimal decision trees}
-Optimal MST decision trees for all graphs on at most~$k$ vertices can be
-constructed on the Pointer machine in time $\O(2^{2^{4k^2}})$.
+\lemman{Construction of optimal decision trees}\id{odtconst}%
+An~optimal MST decision tree for a~graph~$G$ on~$n$ vertices can be constructed on
+the Pointer machine in time $\O(2^{2^{4n^2}})$.
\proof
-There are $2^{k\choose 2} \le 2^{k^2}$ undirected graphs on~$k$ vertices. Any
-graph on less than~$k$ vertices can be extended to $k$~vertices by adding isolated
-vertices, which obviously do not affect the optimal decision tree.
-
-For every graph~$G$, we will try all possible decision trees of depth at most $2k^2$
-(we know from the previous lemma that the optimal tree is shallower). We can obtain
+We will try all possible decision trees of depth at most $2n^2$
+(we know from the previous lemma that the desired optimal tree is shallower). We can obtain
any such tree by taking the complete binary tree of exactly this depth
-and labeling its $2\cdot 2^{2k^2}-1$ vertices with comparisons and spanning trees. Those labeled
+and labeling its $2\cdot 2^{2n^2}-1$ vertices with comparisons and spanning trees. Those labeled
with comparisons become internal vertices of the decision tree, the others
-become leaves and the parts of the tree below them are cut. There are less
-than $k^4$ possible comparisons and less than $2^{k^2}$ spanning trees of~$G$,
+become leaves and the parts of the tree below them are removed. There are less
+than $n^4$ possible comparisons and less than $2^{n^2}$ spanning trees of~$G$,
so the number of candidate decision trees is bounded by
-$(k^4+2^{k^2})^{2^{2k^2+1}} \le 2^{(k^2+1)\cdot 2^{2k^2+1}} \le 2^{2^{2k^2+2}} \le 2^{2^{3k^2}}$.
+$(n^4+2^{n^2})^{2^{2n^2+1}} \le 2^{(n^2+1)\cdot 2^{2n^2+1}} \le 2^{2^{2n^2+2}} \le 2^{2^{3n^2}}$.
-We will enumerate the trees in an~arbitrary order, test each for correctness and
+We will enumerate the trees in an~arbitrary order, test each of them for correctness and
find the shallowest tree among those correct. Testing can be accomplished by running
through all possible permutations of edges, each time calculating the MSF using any
of the known algorithms and comparing it with the result given by the decision tree.
-The number of permutations does not exceed $(k^2)! \le (k^2)^{k^2} \le k^{2k^2} \le 2^{k^3}$
-and each permutation can be checked in time $\O(\poly(k))$.
+The number of permutations does not exceed $(n^2)! \le (n^2)^{n^2} \le n^{2n^2} \le 2^{n^3}$
+and each permutation can be checked in time $\O(\poly(n))$.
-On the Pointer machine, graphs, trees and permutations can be certainly enumerated in time
-$\O(\poly(k))$ per object. The time complexity of the whole algorithm is therefore
-$\O(2^{k^2} \cdot 2^{2^{3k^2}} \cdot 2^{k^3} \cdot \poly(k)) = \O(2^{2^{4k^2}})$.
+On the Pointer machine, trees and permutations can be certainly enumerated in time
+$\O(\poly(n))$ per object. The time complexity of the whole algorithm is therefore
+$\O(2^{2^{3n^2}} \cdot 2^{n^3} \cdot \poly(n)) = \O(2^{2^{4n^2}})$.
\qed
-\paran{Basic properties of decision trees}
+\paran{Basic properties of decision trees}%
The following properties will be useful for analysis of algorithms based
on precomputed decision trees. We will omit some technical details, referring
-the reader to section 5.1 of the Pettie's paper \cite{pettie:optimal}.
+the reader to section 5.1 of the Pettie's article \cite{pettie:optimal}.
\lemma\id{dtbasic}%
The decision tree complexity $D(m,n)$ of the MSF satisfies:
\numlist\ndotted
\:$D(m,n) \ge m/2$ for $m,n > 2$.
-\:$D(m',n') \ge D(m,n)$ whenever $m'\ge m, n'\ge n$.
+\:$D(m',n') \ge D(m,n)$ whenever $m'\ge m$ and $n'\ge n$.
\endlist
\proof
For every $m,n>2$ there is a~graph on $n$~vertices and $m$~edges such that
every edge lies on a~cycle. Every correct MSF decision tree for this graph
has to compare each edge at least once. Otherwise the decision tree cannot
-distinguish between the case when the edge has the lowest of all weights (and
+distinguish between the case when an~edge has the lowest of all weights (and
thus it is forced to belong to the MSF) and when it has the highest weight (so
it is forced out of the MSF).
$\msf(G) = \bigcup_i \msf(C_i)$ for every permutation of edge weights.
\lemma\id{partiscomp}%
-The subgraphs $C_1,\ldots,C_k$ generated by the Partition procedure of the
+The clusters $C_1,\ldots,C_k$ generated by the Partition procedure of the
previous section (Algorithm \ref{partition}) are compartments of the graph
$H=\bigcup_i C_i$.
it is the heaviest edge on some cycle. It is therefore sufficient to prove that
every cycle in~$H$ is contained within a~single~$C_i$.
-Let us consider a~cycle $K\subseteq H$ and a~subgraph~$C_i$ such that it contains
-an~edge~$e$ of~$K$ and all subgraphs constructed later by the procedure do not contain
+Let us consider a~cycle $K\subseteq H$ and a~cluster~$C_i$ such that it contains
+an~edge~$e$ of~$K$ and all clusters constructed later by the procedure do not contain
any. If $K$~is not fully contained in~$C_i$, we can extend the edge~$e$ to a~maximal
path contained in both~$K$ and~$C_i$. Since $C_i$ shares at most one vertex with the
-earlier components, there can be at most one edge from~$K$ adjacent to the maximal path,
+earlier clusters, there can be at most one edge from~$K$ adjacent to the maximal path,
which is impossible.
\qed
\lemma
Let $C_1,\ldots,C_k$ be compartments of a~graph~$G$. Then there exists an~optimal
-MSF decision tree for~$G$ that does not compare edges from distinct compartments.
+MSF decision tree for~$G$ that does not compare edges of distinct compartments.
\proofsketch
Consider a~subset~$\cal P$ of edge weight permutations~$w$ that satisfy $w(e) < w(f)$
to a~decision tree for~$G$. We take the decision tree for~$C_1$, replace every its leaf
by a~copy of the tree for~$C_2$ and so on. Every leaf~$\ell$ of the compound tree will be
labeled with the union of labels of the original leaves encountered on the path from
-the root to the new leaf~$\ell$. This proves that $D(G) \le \sum_i D(C_i)$.
+the root to~$\ell$. This proves that $D(G) \le \sum_i D(C_i)$.
The other inequality requires more effort. We use the previous lemma to transform
the optimal decision tree for~$G$ to another of the same depth, but without inter-compartment
comparisons. Then we prove by induction on~$k$ and then on the depth of the tree
-that the tree can be re-arranged, so that every computation first compares edges
+that this tree can be re-arranged, so that every computation first compares edges
from~$C_1$, then from~$C_2$ and so on. This means that the tree can be decomposed
-to decision trees for the $C_i$'s and without loss of generality all trees for
-a~single~$C_i$ can be made isomorphic.
+to decision trees for the $C_i$'s. Also, without loss of generality all trees for
+a~single~$C_i$ can be made isomorphic to~${\cal D}(C_i)$.
\qed
\cor\id{dtpart}%
-If $C_1,\ldots,C_k$ are the subgraphs generated by the Partition procedure (Algorithm \ref{partition}),
+If $C_1,\ldots,C_k$ are the clusters generated by the Partition procedure (Algorithm \ref{partition}),
then $D(\bigcup_i C_i) = \sum_i D(C_i)$.
\proof
%--------------------------------------------------------------------------------
-\section{An optimal algorithm}
+\section{An optimal algorithm}\id{optalgsect}%
Once we have developed the soft heaps, partitioning and MST decision trees,
-it is now simple to state the Pettie's and Ramachandran's MST algorithm \cite{pettie:optimal}
+it is now simple to state the Pettie's and Ramachandran's MST algorithm
and prove that it is asymptotically optimal among all MST algorithms in
comparison-based models. Several standard MST algorithms from the previous
-chapters will play their roles.
+chapters will also play their roles.
We will describe the algorithm as a~recursive procedure. When the procedure is
-called on a~graph~$G$, it sets the parameter~$t$ to rougly $\log^{(3)} n$ and
+called on a~graph~$G$, it sets the parameter~$t$ to roughly $\log^{(3)} n$ and
it calls the \<Partition> procedure to split the graph into a~collection of
-subgraphs of size~$t$ and a~set of corrupted edges. Then it uses precomputed decision
-trees to find the MSF of the small subgraphs. The graph obtained by contracting
-the subgraphs is on the other hand dense enough, so that the Iterated Jarn\'\i{}k's
-algorithm runs on it in linear time. Afterwards we combine the MSF's of the subgraphs
+clusters of size~$t$ and a~set of corrupted edges. Then it uses precomputed decision
+trees to find the MSF of the clusters. The graph obtained by contracting
+the clusters is on the other hand dense enough, so that the Iterated Jarn\'\i{}k's
+algorithm runs on it in linear time. Afterwards we combine the MSF's of the clusters
and of the contracted graphs, we mix in the corrupted edges and run two iterations
-of the Contractive Bor\o{u}vka's algorithm. The resulting graph will have both the number of
-vertices and edges reduced by a~constant factor and we recurse on it.
+of the Contractive Bor\o{u}vka's algorithm. This guarantees reduction in the number of
+both vertices and edges by a~constant factor, so we can efficiently recurse on the
+resulting graph.
\algn{Optimal MST algorithm, Pettie and Ramachandran \cite{pettie:optimal}}\id{optimal}%
\algo
\algin A~connected graph~$G$ with an~edge comparison oracle.
\:If $G$ has no edges, return an~empty tree.
-\:$t\=\lceil\log^{(3)} n\rceil$. \cmt{the size of subgraphs}
+\:$t\=\lfloor\log^{(3)} n\rfloor$. \cmt{the size of clusters}
\:Call \<Partition> (\ref{partition}) on $G$ and $t$ with $\varepsilon=1/8$. It returns
- a~collection~$\C=\{C_1,\ldots,C_k\}$ of subgraphs and a~set~$R^\C$ of corrupted edges.
-\:$F_i \= \mst(C_i)$ for all~$i$ obtained using optimal decision trees.
+ a~collection~$\C=\{C_1,\ldots,C_k\}$ of clusters and a~set~$R^\C$ of corrupted edges.
+\:$F_i \= \mst(C_i)$ for all~$i$, obtained using optimal decision trees.
\:$G_A \= (G / \bigcup_i C_i) \setminus R^\C$. \cmt{the contracted graph}
\:$F_A \= \msf(G_A)$ calculated by the Iterated Jarn\'\i{}k's algorithm (\ref{itjar}).
\:$G_B \= \bigcup_i F_i \cup F_A \cup R^\C$. \cmt{combine subtrees with corrupted edges}
$$
T(m,n) \le \sum_i c_1 D(C_i) + T(m/2, n/4) + c_2 m,
$$
-where~$c_1$ and~$c_2$ are some constants and $D$~is the decision tree complexity
+where~$c_1$ and~$c_2$ are some positive constants and $D$~is the decision tree complexity
from the previous section.
\proof
The first two steps of the algorithm are trivial as we have linear time at our
disposal.
-By the Parititioning theorem (\ref{partthm}), the call to \<Partition> with~$\varepsilon$
-set to a~constant takes $\O(m)$ time and it produces a~collection of subgraphs of size
+By the Partitioning theorem (\ref{partthm}), the call to \<Partition> with~$\varepsilon$
+set to a~constant takes $\O(m)$ time and it produces a~collection of clusters of size
at most~$t$ and at most $m/4$ corrupted edges. It also guarantees that the
connected components of the union of the $C_i$'s have at least~$t$ vertices
(unless there is just a~single component).
-\FIXME{Decision trees and sorting}
+To apply the decision trees, we will use the framework of topological computations developed
+in Section \ref{bucketsort}. We pad all clusters in~$\C$ with isolated vertices, so that they
+have exactly~$t$ vertices. We use a~computation that labels the graph with a~pointer to
+its optimal decision tree. Then we apply Theorem \ref{topothm} combined with the
+brute-force construction of optimal decision trees from Lemma \ref{odtconst}. Together they guarantee
+that we can assign the decision trees to the clusters in time:
+$$\O\Bigl(\Vert\C\Vert + t^{t(t+2)} \cdot \bigl(2^{2^{4t^2}} + t^2\bigr)\Bigr)
+= \O\Bigl(m + 2^{2^{2^t}}\Bigr)
+= \O(m).$$
+Execution of the decision tree on each cluster~$C_i$ then takes $\O(D(C_i))$ steps.
The contracted graph~$G_A$ has at most $n/t = \O(n / \log^{(3)}n)$ vertices and asymptotically
-the same number of edges as~$G$, so according to Corollary \ref{ijdens} the Iterated Jarn\'\i{}k's
+the same number of edges as~$G$, so according to Corollary \ref{ijdens}, the Iterated Jarn\'\i{}k's
algorithm runs on it in linear time.
The combined graph~$G_B$ has~$n$ vertices, but less than~$n$ edges from the
or in case of the contractions by the bucket-sorting techniques of Section \ref{bucketsort}.
\qed
-\paran{Optimality}
+\paran{Optimality}%
The properties of decision tree complexity, which we have proven in the previous
-section, will help us show that the time complexity recurrence is satisfied by the
-decision tree complexity $D(m,n)$ itself. This way, we prove the following theorem:
+section, will help us show that the time complexity recurrence is satisfied by a~constant
+multiple of the decision tree complexity $D(m,n)$ itself. This way, we will prove
+the following theorem:
\thmn{Optimality of the Optimal algorithm}
The time complexity of the Optimal MST algorithm \ref{optimal} is $\Theta(D(m,n))$.
$$\vcenter{\openup\jot\halign{\strut\hfil $\displaystyle{#}$&$\displaystyle{{}#}$\hfil&\quad#\hfil\cr
T(m,n)
&\le \sum_i c_1 D(C_i) + T(m/2, n/4) + c_2 m &(Lemma \ref{optlemma})\cr
- &\le c_1 D(m,n) + T(m/2, n/4) + c_2m &(Corollary \ref{dtpart})\cr
+ &\le c_1 D({\textstyle\bigcup}_i C_i) + T(m/2, n/4) + c_2 m &(Corollary \ref{dtpart})\cr
+ &\le c_1 D(m,n) + T(m/2, n/4) + c_2m &(definition of $D(m,n)$)\cr
&\le c_1 D(m,n) + cD(m/2, n/4) + c_2m &(induction hypothesis)\cr
&\le c_1 D(m,n) + c/2\cdot D(m,n/2) + c_2m &(Corollary \ref{dttwice})\cr
&\le c_1 D(m,n) + c/2\cdot D(m,n) + 2c_2 D(m,n) &(Lemma \ref{dtbasic})\cr
&\le (c_1 + c/2 + 2c_2) \cdot D(m,n)&\cr
&\le cD(m,n). &(by setting $c=2c_1+4c_2$)\cr
}}$$
-The other inequality is obvious as $D(m,n)$ is an~asymptotic lower bound for
+The other inequality is obvious as $D(m,n)$ is an~asymptotic lower bound on
the time complexity of every comparison-based algorithm.
\qed
-\paran{Complexity}
+\paran{Complexity of MST}%
As we have already noted, the exact decision tree complexity $D(m,n)$ of the MST problem
is still open and so is therefore the time complexity of the optimal algorithm. However,
every time we come up with another comparison-based algorithm, we can use its complexity
(or more specifically the number of comparisons it performs, which can be even lower)
-as an~upper bound for the optimal algorithm.
+as an~upper bound on the optimal algorithm.
The best explicit comparison-based algorithm known to date achieves complexity $\O(m\timesalpha(m,n))$.
It has been discovered by Chazelle \cite{chazelle:ackermann} as an~improvement of his previous
$\O(m\timesalpha(m,n)\cdot\log\alpha(m,n))$ algorithm \cite{chazelle:almostacker}.
-It is also based on the ideas of this section --- in particular the soft heaps and robust contractions.
-The algorithm is unfortunately very complex and it involves a~lot of elaborate
-technical details, so we will only refer to the original paper here. Another algorithm of the same
-complexity, based on similar ideas, has been discovered independently by Pettie \cite{pettie:ackermann}, who,
-having the optimal algorithm at hand, does not take care about the low-level details and only
+It is also based on the ideas of this chapter --- in particular the soft heaps and robust contractions.
+The algorithm is very complex and it involves a~lot of elaborate
+technical details, so we only refer to the original paper here. Another algorithm of the same
+complexity, using similar ideas, has been discovered independently by Pettie \cite{pettie:ackermann}, who,
+having the optimal algorithm at hand, does not take care about the low-level details and he only
bounds the number of comparisons. Using any of these results, we can prove an~Ackermannian
upper bound on the optimal algorithm:
\thmn{Upper bound on complexity of the Optimal algorithm}
-The time complexity of the Optimal MST algorithm is bounded by $\O(m\timesalpha(m,n))$.
+The time complexity of the Optimal MST algorithm is $\O(m\timesalpha(m,n))$.
\proof
-Bound $D(m,n)$ by the number of comparisons performed by the algorithms of Chazelle \cite{chazelle:ackermann}
+We bound $D(m,n)$ by the number of comparisons performed by the algorithm of Chazelle \cite{chazelle:ackermann}
or Pettie \cite{pettie:ackermann}.
\qed
+Similarly to the Iterated Jarn\'\i{}k's algorithm, this bound is actually linear for classes of graphs
+that do not have density extremely close to constant:
+
+\cor
+The Optimal MST algorithm runs in linear time whenever $m\ge n\cdot a(k,n)$ for any fixed~$k$.
+
+\proof
+Combine the previous theorem with Lemma \ref{alphaconst}.
+\qed
+
\rem
It is also known from \cite{pettie:optimal} that when we run the Optimal algorithm on a~random
graph drawn from either $G_{n,p}$ (random graphs on~$n$ vertices, each edge is included with probability~$p$
set of all graphs with~$n$ vertices and $m$~edges), it runs in linear time with high probability,
regardless of the edge weights.
-\paran{Models of computation}
+\paran{Models of computation}%
Another important consequence of the optimal algorithm is that when we aim for a~linear-time
MST algorithm (or for proving that it does not exist), we do not need to care about computational
models at all. The elaborate RAM data structures of Chapter \ref{ramchap}, which have helped us
world of decision trees and thus we can use it to show that the algorithm we already knew is
also linear.
-This however applies to deterministic algorithms only --- we already know that access to a~source
-of random bits allows us to compute the MST in expected linear time (the KKT Algorithm, \ref{kkt}).
+This however applies to deterministic algorithms only --- we have shown that access to a~source
+of random bits allows us to compute the MST in expected linear time (the KKT algorithm, \ref{kkt}).
There were attempts to derandomize the KKT algorithm, but so far the best result in this direction
is the randomized algorithm also by Pettie \cite{pettie:minirand} which achieves expected linear time
complexity with only $\O(\log^* n)$ random bits.
-
-
\endpart