2016-12-28 23:54:51 +01:00
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\chapter{Square root algorithms}
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2017-01-25 22:13:05 +01:00
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\index{square root algorithm}
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2016-12-28 23:54:51 +01:00
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2017-01-25 22:13:05 +01:00
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A \key{square root algorithm} is an algorithm
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that has a square root in its time complexity.
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A square root can be seen as a ''poor man's logarithm'':
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the complexity $O(\sqrt n)$ is better than $O(n)$
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but worse than $O(\log n)$.
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In any case, many square root algorithms are fast and usable in practice.
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2017-02-11 20:24:28 +01:00
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As an example, let us consider the problem of
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creating a data structure that supports
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two operations on an array:
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modifying an element at a given position
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and calculating the sum of elements in the given range.
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We have previously solved the problem using
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binary indexed and segment trees,
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that support both operations in $O(\log n)$ time.
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However, now we will solve the problem
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in another way using a square root structure
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that allows us to modify elements in $O(1)$ time
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and calculate sums in $O(\sqrt n)$ time.
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2016-12-28 23:54:51 +01:00
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2017-04-22 10:57:37 +02:00
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The idea is to divide the array into \emph{blocks}
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of size $\sqrt n$ so that each block contains
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the sum of elements inside the block.
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For example, an array of 16 elements will be
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divided into blocks of 4 elements as follows:
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\begin{center}
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\begin{tikzpicture}[scale=0.7]
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\draw (0,0) grid (16,1);
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\draw (0,1) rectangle (4,2);
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\draw (4,1) rectangle (8,2);
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\draw (8,1) rectangle (12,2);
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\draw (12,1) rectangle (16,2);
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\node at (0.5, 0.5) {5};
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\node at (1.5, 0.5) {8};
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\node at (2.5, 0.5) {6};
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\node at (3.5, 0.5) {3};
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\node at (4.5, 0.5) {2};
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\node at (5.5, 0.5) {7};
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\node at (6.5, 0.5) {2};
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\node at (7.5, 0.5) {6};
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\node at (8.5, 0.5) {7};
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\node at (9.5, 0.5) {1};
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\node at (10.5, 0.5) {7};
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\node at (11.5, 0.5) {5};
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\node at (12.5, 0.5) {6};
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\node at (13.5, 0.5) {2};
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\node at (14.5, 0.5) {3};
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\node at (15.5, 0.5) {2};
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\node at (2, 1.5) {21};
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\node at (6, 1.5) {17};
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\node at (10, 1.5) {20};
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\node at (14, 1.5) {13};
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\end{tikzpicture}
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\end{center}
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2017-04-22 10:57:37 +02:00
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In this structure,
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it is easy to modify array elements,
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because it is only needed to update
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the sum of a single block
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after each modification,
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which can be done in $O(1)$ time.
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For example, the following picture shows
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how the value of an element and
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the sum of the corresponding block change:
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\begin{center}
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\begin{tikzpicture}[scale=0.7]
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\fill[color=lightgray] (5,0) rectangle (6,1);
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\draw (0,0) grid (16,1);
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\fill[color=lightgray] (4,1) rectangle (8,2);
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\draw (0,1) rectangle (4,2);
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\draw (4,1) rectangle (8,2);
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\draw (8,1) rectangle (12,2);
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\draw (12,1) rectangle (16,2);
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\node at (0.5, 0.5) {5};
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\node at (1.5, 0.5) {8};
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\node at (2.5, 0.5) {6};
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\node at (3.5, 0.5) {3};
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\node at (4.5, 0.5) {2};
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\node at (5.5, 0.5) {5};
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\node at (6.5, 0.5) {2};
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\node at (7.5, 0.5) {6};
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\node at (8.5, 0.5) {7};
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\node at (9.5, 0.5) {1};
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\node at (10.5, 0.5) {7};
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\node at (11.5, 0.5) {5};
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\node at (12.5, 0.5) {6};
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\node at (13.5, 0.5) {2};
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\node at (14.5, 0.5) {3};
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\node at (15.5, 0.5) {2};
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\node at (2, 1.5) {21};
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\node at (6, 1.5) {15};
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\node at (10, 1.5) {20};
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\node at (14, 1.5) {13};
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\end{tikzpicture}
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\end{center}
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2017-02-11 20:24:28 +01:00
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Calculating the sum of elements in a range is
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a bit more difficult.
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It turns out that we can always divide
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the range into three parts such that
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the sum consists of values of single elements
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and sums of blocks between them:
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\begin{center}
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\begin{tikzpicture}[scale=0.7]
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\fill[color=lightgray] (3,0) rectangle (4,1);
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\fill[color=lightgray] (12,0) rectangle (13,1);
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\fill[color=lightgray] (13,0) rectangle (14,1);
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\draw (0,0) grid (16,1);
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\fill[color=lightgray] (4,1) rectangle (8,2);
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\fill[color=lightgray] (8,1) rectangle (12,2);
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\draw (0,1) rectangle (4,2);
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\draw (4,1) rectangle (8,2);
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\draw (8,1) rectangle (12,2);
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\draw (12,1) rectangle (16,2);
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\node at (0.5, 0.5) {5};
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\node at (1.5, 0.5) {8};
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\node at (2.5, 0.5) {6};
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\node at (3.5, 0.5) {3};
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\node at (4.5, 0.5) {2};
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\node at (5.5, 0.5) {5};
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\node at (6.5, 0.5) {2};
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\node at (7.5, 0.5) {6};
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\node at (8.5, 0.5) {7};
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\node at (9.5, 0.5) {1};
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\node at (10.5, 0.5) {7};
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\node at (11.5, 0.5) {5};
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\node at (12.5, 0.5) {6};
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\node at (13.5, 0.5) {2};
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\node at (14.5, 0.5) {3};
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\node at (15.5, 0.5) {2};
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\node at (2, 1.5) {21};
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\node at (6, 1.5) {15};
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\node at (10, 1.5) {20};
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\node at (14, 1.5) {13};
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\draw [decoration={brace}, decorate, line width=0.5mm] (14,-0.25) -- (3,-0.25);
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\end{tikzpicture}
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\end{center}
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2017-02-11 20:24:28 +01:00
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Since the number of single elements is $O(\sqrt n)$
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and the number of blocks is also $O(\sqrt n)$,
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the time complexity of the sum query is $O(\sqrt n)$.
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In this case, the parameter $\sqrt n$ balances two things:
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the array is divided into $\sqrt n$ blocks,
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each of which contains $\sqrt n$ elements.
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In practice, it is not needed to use the
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exact value of $\sqrt n$ as a parameter, but it may be better to
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use parameters $k$ and $n/k$ where $k$ is
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different from $\sqrt n$.
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The optimal parameter depends on the problem and input.
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For example, if an algorithm often goes
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through the blocks but rarely inspects
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single elements inside the blocks,
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it may be a good idea to divide the array into
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$k < \sqrt n$ blocks, each of which contains $n/k > \sqrt n$
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elements.
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\section{Batch processing}
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\index{batch processing}
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Sometimes the operations of an algorithm
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can be divided into \emph{batches}.
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Each batch contains a sequence of operations
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which will be processed one after another.
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Some precalculation is done
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between the batches
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in order to process the future operations more efficiently.
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If there are $O(\sqrt n)$ batches of size $O(\sqrt n)$,
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this results in a square root algorithm.
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As an example, let us consider a problem
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where a grid of size $k \times k$
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initially consists of white squares
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and our task is to perform $n$ operations,
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each of which is one of the following:
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\begin{itemize}
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\item
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paint square $(y,x)$ black
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\item
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find the nearest black square to
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square $(y,x)$ where the distance
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between squares $(y_1,x_1)$ and $(y_2,x_2)$
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is $|y_1-y_2|+|x_1-x_2|$
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\end{itemize}
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2017-02-11 20:24:28 +01:00
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We can solve the problem by dividing
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the operations into
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$O(\sqrt n)$ batches, each of which consists
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of $O(\sqrt n)$ operations.
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At the beginning of each batch,
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we calculate for each square of the grid
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the smallest distance to a black square.
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This can be done in $O(k^2)$ time using breadth-first search.
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When processing a batch, we maintain a list of squares
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that have been painted black in the current batch.
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The list contains $O(\sqrt n)$ elements,
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because there are $O(\sqrt n)$ operations in each batch.
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Now, the distance from a square to the nearest black
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square is either the precalculated distance or the distance
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to a square that appears in the list.
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The algorithm works in
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$O((k^2+n) \sqrt n)$ time.
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First, there are $O(\sqrt n)$ breadth-first searches
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and each search takes $O(k^2)$ time.
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Second, the total number of
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distances calculated during the algorithm
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is $O(n)$, and when calculating each distance,
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we go through a list of $O(\sqrt n)$ squares.
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If the algorithm would perform a breadth-first search
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at each operation, the time complexity would be
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$O(k^2 n)$.
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And if the algorithm would go through all painted
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squares at each operation,
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the time complexity would be $O(n^2)$.
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Thus, the time complexity of the square root algorithm
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is a combination of these time complexities,
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but in addition, a factor of $n$ is replaced by $\sqrt n$.
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\section{Subalgorithms}
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2017-04-22 10:57:37 +02:00
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Some square root algorithms consist of
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\emph{subalgorithms} that are specialized for different
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input parameters.
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Typically, there are two subalgorithms:
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one algorithm is efficient when
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some parameter is smaller than $\sqrt n$,
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and another algorithm is efficient
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when the parameter is larger than $\sqrt n$.
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As an example, let us consider a problem where
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we are given a tree of $n$ nodes,
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each with some color. Our task is to find two nodes
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that have the same color and whose distance
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is as large as possible.
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For example, in the following tree,
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the maximum distance is 4 between
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the red nodes 3 and 4:
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2017-02-11 20:24:28 +01:00
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\begin{center}
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\begin{tikzpicture}[scale=0.9]
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\node[draw, circle, fill=green!40] (1) at (1,3) {$2$};
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\node[draw, circle, fill=red!40] (2) at (4,3) {$3$};
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\node[draw, circle, fill=red!40] (3) at (1,1) {$5$};
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\node[draw, circle, fill=blue!40] (4) at (4,1) {$6$};
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\node[draw, circle, fill=red!40] (5) at (-2,1) {$4$};
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\node[draw, circle, fill=blue!40] (6) at (-2,3) {$1$};
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\path[draw,thick,-] (1) -- (2);
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\path[draw,thick,-] (1) -- (3);
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\path[draw,thick,-] (3) -- (4);
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\path[draw,thick,-] (3) -- (6);
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\path[draw,thick,-] (5) -- (6);
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\end{tikzpicture}
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\end{center}
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2017-02-11 20:24:28 +01:00
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The problem can be solved by going through
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all colors and calculating
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the maximum distance between two nodes
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separately for each color.
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Assume that the current color is $x$ and
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there are $c$ nodes whose color is $x$.
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There are two subalgorithms
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that are specialized for small and large
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values of $c$:
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\emph{Case 1}: $c \le \sqrt n$.
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If the number of nodes is small,
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we go through all pairs of nodes whose
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color is $x$ and select the pair that
|
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|
|
has the maximum distance.
|
2017-02-11 20:24:28 +01:00
|
|
|
For each node, it is needed to calculate the distance
|
2017-02-11 20:27:03 +01:00
|
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|
to $O(\sqrt n)$ other nodes (see Chapter 18.3),
|
2017-01-25 22:13:05 +01:00
|
|
|
so the total time needed for processing all
|
2017-02-11 20:24:28 +01:00
|
|
|
nodes is $O(n \sqrt n)$.
|
2017-01-25 22:13:05 +01:00
|
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|
2017-02-11 20:24:28 +01:00
|
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|
\emph{Case 2}: $c > \sqrt n$.
|
2017-01-25 22:13:05 +01:00
|
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|
If the number of nodes is large,
|
2017-02-11 20:24:28 +01:00
|
|
|
we go through the whole tree
|
2017-01-25 22:13:05 +01:00
|
|
|
and calculate the maximum distance between
|
|
|
|
two nodes with color $x$.
|
|
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|
The time complexity of the tree traversal is $O(n)$,
|
|
|
|
and this will be done at most $O(\sqrt n)$ times,
|
2017-02-11 20:24:28 +01:00
|
|
|
so the total time needed is $O(n \sqrt n)$.
|
|
|
|
|
2017-01-25 22:13:05 +01:00
|
|
|
The time complexity of the algorithm is $O(n \sqrt n)$,
|
2017-02-18 17:46:37 +01:00
|
|
|
because both cases take a total of $O(n \sqrt n)$ time.
|
2017-01-25 22:13:05 +01:00
|
|
|
|
2017-05-02 18:49:34 +02:00
|
|
|
\section{Integer partitions}
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|
Some square root algorithms are based on
|
|
|
|
the following observation:
|
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|
|
if a positive integer $n$ is represented as
|
|
|
|
a sum of positive integers,
|
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|
|
such a sum contains only $O(\sqrt n)$ \emph{distinct} numbers.
|
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|
|
The reason for this is that a sum with
|
|
|
|
the maximum amount of distinct numbers has to be of the form
|
|
|
|
\[1+2+3+ \cdots = n.\]
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|
|
The sum of the numbers $1,2,\ldots,k$ is
|
|
|
|
\[\frac{k(k+1)}{2},\]
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|
|
|
so the maximum amount of distinct numbers is $k = O(\sqrt n)$.
|
|
|
|
Next we will discuss two problems that can be solved
|
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|
|
efficiently using this observation.
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|
\subsubsection{Knapsack}
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|
Suppose that we are given a list of integer weights
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|
|
whose sum is $n$.
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|
Our task is to find out all sums that can be formed using
|
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|
|
a subset of the weights. For example, if the weights are
|
|
|
|
$\{1,3,3\}$, the possible sums are as follows:
|
|
|
|
|
|
|
|
\begin{itemize}[noitemsep]
|
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|
|
\item $0$ (empty set)
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|
|
\item $1$
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|
|
\item $3$
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|
|
\item $1+3=4$
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|
|
\item $3+3=6$
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|
|
\item $1+3+3=7$
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|
|
\end{itemize}
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|
|
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|
|
|
|
Using the standard knapsack approach (see Chapter 7.4),
|
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|
|
the problem can be solved as follows:
|
|
|
|
we define a function $f(k,s)$ whose value is 1
|
|
|
|
if the sum $s$ can be formed using the first $k$ weights,
|
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|
|
and 0 otherwise.
|
|
|
|
All values of this function can be calculated
|
|
|
|
in $O(n^2)$ time using dynamic programming.
|
|
|
|
|
|
|
|
However, we can make the algorithm more efficient
|
|
|
|
by using the fact that the sum of the weights is $n$,
|
|
|
|
which means that there are at most $O(\sqrt n)$
|
|
|
|
distinct weights.
|
|
|
|
Thus, we can process the weights in groups
|
|
|
|
such that all weights in each group are equal.
|
|
|
|
It turns out that we can process each group
|
|
|
|
in $O(n)$ time, which yields an $O(n \sqrt n)$ time algorithm.
|
|
|
|
|
|
|
|
The idea is to use an array that records the sums of weights
|
|
|
|
that can be formed using the groups processed so far.
|
|
|
|
The array contains $n$ elements: element $k$ is 1 if the sum
|
|
|
|
$k$ can be formed and 0 otherwise.
|
|
|
|
To process a group of weights, we can easily scan the array
|
|
|
|
from left to right and record the new sums of weights that
|
|
|
|
can be formed using this group and the previous groups.
|
|
|
|
|
|
|
|
\subsubsection{String construction}
|
|
|
|
|
|
|
|
Given a string and a dictionary of words,
|
|
|
|
consider the problem of counting the number of ways
|
|
|
|
the string can be constructed using the dictionary words.
|
|
|
|
For example,
|
|
|
|
if the string is \texttt{ABAB} and the dictionary is
|
|
|
|
$\{\texttt{A},\texttt{B},\texttt{AB}\}$,
|
|
|
|
there are 4 ways:
|
|
|
|
$\texttt{A}+\texttt{B}+\texttt{A}+\texttt{B}$,
|
|
|
|
$\texttt{AB}+\texttt{A}+\texttt{B}$,
|
|
|
|
$\texttt{A}+\texttt{B}+\texttt{AB}$ and
|
|
|
|
$\texttt{AB}+\texttt{AB}$.
|
|
|
|
|
|
|
|
Assume that the length of the string is $n$
|
|
|
|
and the total length of the dictionary words is $m$.
|
|
|
|
A natural way to solve the problem is to use dynamic
|
|
|
|
programming: we can define a function $f$ such that
|
|
|
|
$f(k)$ denotes the number of ways to construct a prefix
|
|
|
|
of length $k$ of the string using the dictionary words.
|
|
|
|
Using this function, $f(n)$ gives the answer to the problem.
|
|
|
|
|
|
|
|
There are several ways to calculate the values of $f$.
|
|
|
|
One method is to store the dictionary words
|
|
|
|
in a trie and go through all ways to select the
|
|
|
|
last word in each prefix, which results in an $O(n^2)$ time algorithm.
|
|
|
|
However, instead of using a trie, we can also use string hashing
|
|
|
|
and always go through the dictionary words and compare their
|
|
|
|
hash values.
|
|
|
|
|
|
|
|
The most straightforward implementation of this idea
|
|
|
|
yields an $O(nm)$ time algorithm,
|
|
|
|
because the dictionary may contain $m$ words.
|
|
|
|
However, we can make the algorithm more efficient
|
|
|
|
by considering the dictionary words grouped by their lengths.
|
|
|
|
Each group can be processed in constant time,
|
|
|
|
because all hash values of dictionary words may be stored in a set.
|
|
|
|
Since the total length of the words is $m$,
|
|
|
|
there are at most $O(\sqrt m)$ distinct word lengths
|
|
|
|
and at most $O(\sqrt m)$ groups.
|
|
|
|
Thus, the running time of the algorithm is only $O(n \sqrt m)$.
|
|
|
|
|
2017-01-25 22:13:05 +01:00
|
|
|
\section{Mo's algorithm}
|
|
|
|
|
|
|
|
\index{Mo's algorithm}
|
|
|
|
|
2017-02-22 20:53:11 +01:00
|
|
|
\key{Mo's algorithm}\footnote{According to \cite{cod15}, this algorithm
|
|
|
|
is named after Mo Tao, a Chinese competitive programmer, but
|
2017-04-22 11:00:43 +02:00
|
|
|
the technique has appeared earlier in the literature \cite{ken06}.}
|
|
|
|
can be used in many problems
|
2017-01-26 22:12:30 +01:00
|
|
|
that require processing range queries in
|
2017-01-25 22:13:05 +01:00
|
|
|
a \emph{static} array.
|
2017-04-22 10:57:37 +02:00
|
|
|
Since the array is static, the queries can be
|
|
|
|
processed in any order.
|
2017-01-26 22:12:30 +01:00
|
|
|
Before processing the queries, the algorithm
|
|
|
|
sorts them in a special order which guarantees
|
2017-02-11 20:24:28 +01:00
|
|
|
that the algorithm works efficiently.
|
2017-01-26 22:12:30 +01:00
|
|
|
|
|
|
|
At each moment in the algorithm, there is an active
|
2017-02-11 20:24:28 +01:00
|
|
|
range and the algorithm maintains the answer
|
|
|
|
to a query related to that range.
|
|
|
|
The algorithm processes the queries one by one,
|
2017-02-18 17:46:37 +01:00
|
|
|
and always moves the endpoints of the
|
2017-02-11 20:24:28 +01:00
|
|
|
active range by inserting and removing elements.
|
2017-01-25 22:13:05 +01:00
|
|
|
The time complexity of the algorithm is
|
2017-02-18 17:46:37 +01:00
|
|
|
$O(n \sqrt n f(n))$ when the array contains
|
|
|
|
$n$ elements, there are $n$ queries
|
2017-01-26 22:12:30 +01:00
|
|
|
and each insertion and removal of an element
|
|
|
|
takes $O(f(n))$ time.
|
|
|
|
|
2017-02-11 20:24:28 +01:00
|
|
|
The trick in Mo's algorithm is the order
|
|
|
|
in which the queries are processed:
|
|
|
|
The array is divided into blocks of $O(\sqrt n)$
|
2017-01-26 22:12:30 +01:00
|
|
|
elements, and the queries are sorted primarily by
|
2017-02-11 20:24:28 +01:00
|
|
|
the number of the block that contains the first element
|
|
|
|
in the range, and secondarily by the position of the
|
|
|
|
last element in the range.
|
2017-01-25 22:13:05 +01:00
|
|
|
It turns out that using this order, the algorithm
|
2017-01-26 22:12:30 +01:00
|
|
|
only performs $O(n \sqrt n)$ operations,
|
2017-04-22 10:57:37 +02:00
|
|
|
because the left endpoint moves
|
2017-01-26 22:12:30 +01:00
|
|
|
$n$ times $O(\sqrt n)$ steps,
|
2017-04-22 10:57:37 +02:00
|
|
|
and the right endpoint moves
|
2017-02-11 20:24:28 +01:00
|
|
|
$\sqrt n$ times $O(n)$ steps. Thus, both
|
|
|
|
endpoints move a total of $O(n \sqrt n)$ steps during the algorithm.
|
2017-01-25 22:13:05 +01:00
|
|
|
|
|
|
|
\subsubsection*{Example}
|
|
|
|
|
2017-02-11 20:24:28 +01:00
|
|
|
As an example, consider a problem
|
|
|
|
where we are given a set of queries,
|
|
|
|
each of them corresponding to a range in an array,
|
|
|
|
and our task is to calculate for each query
|
2017-02-18 17:46:37 +01:00
|
|
|
the number of \emph{distinct} elements in the range.
|
2017-01-25 22:13:05 +01:00
|
|
|
|
|
|
|
In Mo's algorithm, the queries are always sorted
|
2017-02-11 20:24:28 +01:00
|
|
|
in the same way, but it depends on the problem
|
|
|
|
how the answer to the query is maintained.
|
2017-01-25 22:13:05 +01:00
|
|
|
In this problem, we can maintain an array
|
2017-04-22 10:57:37 +02:00
|
|
|
\texttt{count} where $\texttt{count}[x]$
|
2017-02-18 17:46:37 +01:00
|
|
|
indicates the number of times an element $x$
|
2017-02-11 20:24:28 +01:00
|
|
|
occurs in the active range.
|
2017-01-25 22:13:05 +01:00
|
|
|
|
2017-02-11 20:24:28 +01:00
|
|
|
When we move from one query to another query,
|
|
|
|
the active range changes.
|
|
|
|
For example, if the current range is
|
2016-12-28 23:54:51 +01:00
|
|
|
\begin{center}
|
|
|
|
\begin{tikzpicture}[scale=0.7]
|
|
|
|
\fill[color=lightgray] (1,0) rectangle (5,1);
|
|
|
|
\draw (0,0) grid (9,1);
|
|
|
|
\node at (0.5, 0.5) {4};
|
|
|
|
\node at (1.5, 0.5) {2};
|
|
|
|
\node at (2.5, 0.5) {5};
|
|
|
|
\node at (3.5, 0.5) {4};
|
|
|
|
\node at (4.5, 0.5) {2};
|
|
|
|
\node at (5.5, 0.5) {4};
|
|
|
|
\node at (6.5, 0.5) {3};
|
|
|
|
\node at (7.5, 0.5) {3};
|
|
|
|
\node at (8.5, 0.5) {4};
|
|
|
|
\end{tikzpicture}
|
|
|
|
\end{center}
|
2017-02-11 20:24:28 +01:00
|
|
|
and the next range is
|
2016-12-28 23:54:51 +01:00
|
|
|
\begin{center}
|
|
|
|
\begin{tikzpicture}[scale=0.7]
|
|
|
|
\fill[color=lightgray] (2,0) rectangle (7,1);
|
|
|
|
\draw (0,0) grid (9,1);
|
|
|
|
\node at (0.5, 0.5) {4};
|
|
|
|
\node at (1.5, 0.5) {2};
|
|
|
|
\node at (2.5, 0.5) {5};
|
|
|
|
\node at (3.5, 0.5) {4};
|
|
|
|
\node at (4.5, 0.5) {2};
|
|
|
|
\node at (5.5, 0.5) {4};
|
|
|
|
\node at (6.5, 0.5) {3};
|
|
|
|
\node at (7.5, 0.5) {3};
|
|
|
|
\node at (8.5, 0.5) {4};
|
|
|
|
\end{tikzpicture}
|
|
|
|
\end{center}
|
2017-01-25 22:13:05 +01:00
|
|
|
there will be three steps:
|
2017-04-17 11:18:29 +02:00
|
|
|
the left endpoint moves one step to the right,
|
2017-02-11 20:24:28 +01:00
|
|
|
and the right endpoint moves two steps to the right.
|
2017-01-25 22:13:05 +01:00
|
|
|
|
2017-04-22 10:57:37 +02:00
|
|
|
After each step, the array \texttt{count}
|
2017-02-11 20:38:13 +01:00
|
|
|
needs to be updated.
|
2017-02-11 20:31:56 +01:00
|
|
|
After adding an element $x$,
|
|
|
|
we increase the value of
|
2017-04-22 10:57:37 +02:00
|
|
|
$\texttt{count}[x]$ by 1,
|
|
|
|
and if $\texttt{count}[x]=1$ after this,
|
|
|
|
we also increase the answer to the query by 1.
|
2017-02-11 20:38:13 +01:00
|
|
|
Similarly, after removing an element $x$,
|
2017-02-11 20:31:56 +01:00
|
|
|
we decrease the value of
|
2017-04-22 10:57:37 +02:00
|
|
|
$\texttt{count}[x]$ by 1,
|
|
|
|
and if $\texttt{count}[x]=0$ after this,
|
|
|
|
we also decrease the answer to the query by 1.
|
2017-01-25 22:13:05 +01:00
|
|
|
|
|
|
|
In this problem, the time needed to perform
|
|
|
|
each step is $O(1)$, so the total time complexity
|
2017-01-26 22:12:30 +01:00
|
|
|
of the algorithm is $O(n \sqrt n)$.
|