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  <div class="section" id="module-heapq">
<h1>8.4. <tt class="xref docutils literal"><span class="pre">heapq</span></tt> &#8212; Heap queue algorithm<a class="headerlink" href="#module-heapq" title="Permalink to this headline">¶</a></h1>
<p class="versionadded">
<span class="versionmodified">New in version 2.3.</span></p>
<p>This module provides an implementation of the heap queue algorithm, also known
as the priority queue algorithm.</p>
<p>Heaps are arrays for which <tt class="docutils literal"><span class="pre">heap[k]</span> <span class="pre">&lt;=</span> <span class="pre">heap[2*k+1]</span></tt> and <tt class="docutils literal"><span class="pre">heap[k]</span> <span class="pre">&lt;=</span>
<span class="pre">heap[2*k+2]</span></tt> for all <em>k</em>, counting elements from zero.  For the sake of
comparison, non-existing elements are considered to be infinite.  The
interesting property of a heap is that <tt class="docutils literal"><span class="pre">heap[0]</span></tt> is always its smallest
element.</p>
<p>The API below differs from textbook heap algorithms in two aspects: (a) We use
zero-based indexing.  This makes the relationship between the index for a node
and the indexes for its children slightly less obvious, but is more suitable
since Python uses zero-based indexing. (b) Our pop method returns the smallest
item, not the largest (called a &#8220;min heap&#8221; in textbooks; a &#8220;max heap&#8221; is more
common in texts because of its suitability for in-place sorting).</p>
<p>These two make it possible to view the heap as a regular Python list without
surprises: <tt class="docutils literal"><span class="pre">heap[0]</span></tt> is the smallest item, and <tt class="docutils literal"><span class="pre">heap.sort()</span></tt> maintains the
heap invariant!</p>
<p>To create a heap, use a list initialized to <tt class="docutils literal"><span class="pre">[]</span></tt>, or you can transform a
populated list into a heap via function <a title="heapq.heapify" class="reference internal" href="#heapq.heapify"><tt class="xref docutils literal"><span class="pre">heapify()</span></tt></a>.</p>
<p>The following functions are provided:</p>
<dl class="function">
<dt id="heapq.heappush">
<tt class="descclassname">heapq.</tt><tt class="descname">heappush</tt><big>(</big><em>heap</em>, <em>item</em><big>)</big><a class="headerlink" href="#heapq.heappush" title="Permalink to this definition">¶</a></dt>
<dd>Push the value <em>item</em> onto the <em>heap</em>, maintaining the heap invariant.</dd></dl>

<dl class="function">
<dt id="heapq.heappop">
<tt class="descclassname">heapq.</tt><tt class="descname">heappop</tt><big>(</big><em>heap</em><big>)</big><a class="headerlink" href="#heapq.heappop" title="Permalink to this definition">¶</a></dt>
<dd>Pop and return the smallest item from the <em>heap</em>, maintaining the heap
invariant.  If the heap is empty, <a title="exceptions.IndexError" class="reference external" href="exceptions.html#exceptions.IndexError"><tt class="xref docutils literal"><span class="pre">IndexError</span></tt></a> is raised.</dd></dl>

<dl class="function">
<dt id="heapq.heappushpop">
<tt class="descclassname">heapq.</tt><tt class="descname">heappushpop</tt><big>(</big><em>heap</em>, <em>item</em><big>)</big><a class="headerlink" href="#heapq.heappushpop" title="Permalink to this definition">¶</a></dt>
<dd><p>Push <em>item</em> on the heap, then pop and return the smallest item from the
<em>heap</em>.  The combined action runs more efficiently than <a title="heapq.heappush" class="reference internal" href="#heapq.heappush"><tt class="xref docutils literal"><span class="pre">heappush()</span></tt></a>
followed by a separate call to <a title="heapq.heappop" class="reference internal" href="#heapq.heappop"><tt class="xref docutils literal"><span class="pre">heappop()</span></tt></a>.</p>
<p class="versionadded">
<span class="versionmodified">New in version 2.6.</span></p>
</dd></dl>

<dl class="function">
<dt id="heapq.heapify">
<tt class="descclassname">heapq.</tt><tt class="descname">heapify</tt><big>(</big><em>x</em><big>)</big><a class="headerlink" href="#heapq.heapify" title="Permalink to this definition">¶</a></dt>
<dd>Transform list <em>x</em> into a heap, in-place, in linear time.</dd></dl>

<dl class="function">
<dt id="heapq.heapreplace">
<tt class="descclassname">heapq.</tt><tt class="descname">heapreplace</tt><big>(</big><em>heap</em>, <em>item</em><big>)</big><a class="headerlink" href="#heapq.heapreplace" title="Permalink to this definition">¶</a></dt>
<dd><p>Pop and return the smallest item from the <em>heap</em>, and also push the new <em>item</em>.
The heap size doesn&#8217;t change. If the heap is empty, <a title="exceptions.IndexError" class="reference external" href="exceptions.html#exceptions.IndexError"><tt class="xref docutils literal"><span class="pre">IndexError</span></tt></a> is raised.
This is more efficient than <a title="heapq.heappop" class="reference internal" href="#heapq.heappop"><tt class="xref docutils literal"><span class="pre">heappop()</span></tt></a> followed by  <a title="heapq.heappush" class="reference internal" href="#heapq.heappush"><tt class="xref docutils literal"><span class="pre">heappush()</span></tt></a>, and
can be more appropriate when using a fixed-size heap.  Note that the value
returned may be larger than <em>item</em>!  That constrains reasonable uses of this
routine unless written as part of a conditional replacement:</p>
<div class="highlight-python"><div class="highlight"><pre><span class="k">if</span> <span class="n">item</span> <span class="o">&gt;</span> <span class="n">heap</span><span class="p">[</span><span class="mi">0</span><span class="p">]:</span>
    <span class="n">item</span> <span class="o">=</span> <span class="n">heapreplace</span><span class="p">(</span><span class="n">heap</span><span class="p">,</span> <span class="n">item</span><span class="p">)</span>
</pre></div>
</div>
</dd></dl>

<p>Example of use:</p>
<div class="highlight-python"><div class="highlight"><pre><span class="gp">&gt;&gt;&gt; </span><span class="kn">from</span> <span class="nn">heapq</span> <span class="kn">import</span> <span class="n">heappush</span><span class="p">,</span> <span class="n">heappop</span>
<span class="gp">&gt;&gt;&gt; </span><span class="n">heap</span> <span class="o">=</span> <span class="p">[]</span>
<span class="gp">&gt;&gt;&gt; </span><span class="n">data</span> <span class="o">=</span> <span class="p">[</span><span class="mi">1</span><span class="p">,</span> <span class="mi">3</span><span class="p">,</span> <span class="mi">5</span><span class="p">,</span> <span class="mi">7</span><span class="p">,</span> <span class="mi">9</span><span class="p">,</span> <span class="mi">2</span><span class="p">,</span> <span class="mi">4</span><span class="p">,</span> <span class="mi">6</span><span class="p">,</span> <span class="mi">8</span><span class="p">,</span> <span class="mi">0</span><span class="p">]</span>
<span class="gp">&gt;&gt;&gt; </span><span class="k">for</span> <span class="n">item</span> <span class="ow">in</span> <span class="n">data</span><span class="p">:</span>
<span class="gp">... </span>    <span class="n">heappush</span><span class="p">(</span><span class="n">heap</span><span class="p">,</span> <span class="n">item</span><span class="p">)</span>
<span class="gp">...</span>
<span class="gp">&gt;&gt;&gt; </span><span class="n">ordered</span> <span class="o">=</span> <span class="p">[]</span>
<span class="gp">&gt;&gt;&gt; </span><span class="k">while</span> <span class="n">heap</span><span class="p">:</span>
<span class="gp">... </span>    <span class="n">ordered</span><span class="o">.</span><span class="n">append</span><span class="p">(</span><span class="n">heappop</span><span class="p">(</span><span class="n">heap</span><span class="p">))</span>
<span class="gp">...</span>
<span class="gp">&gt;&gt;&gt; </span><span class="k">print</span> <span class="n">ordered</span>
<span class="go">[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]</span>
<span class="gp">&gt;&gt;&gt; </span><span class="n">data</span><span class="o">.</span><span class="n">sort</span><span class="p">()</span>
<span class="gp">&gt;&gt;&gt; </span><span class="k">print</span> <span class="n">data</span> <span class="o">==</span> <span class="n">ordered</span>
<span class="go">True</span>
</pre></div>
</div>
<p>Using a heap to insert items at the correct place in a priority queue:</p>
<div class="highlight-python"><div class="highlight"><pre><span class="gp">&gt;&gt;&gt; </span><span class="n">heap</span> <span class="o">=</span> <span class="p">[]</span>
<span class="gp">&gt;&gt;&gt; </span><span class="n">data</span> <span class="o">=</span> <span class="p">[(</span><span class="mi">1</span><span class="p">,</span> <span class="s">&#39;J&#39;</span><span class="p">),</span> <span class="p">(</span><span class="mi">4</span><span class="p">,</span> <span class="s">&#39;N&#39;</span><span class="p">),</span> <span class="p">(</span><span class="mi">3</span><span class="p">,</span> <span class="s">&#39;H&#39;</span><span class="p">),</span> <span class="p">(</span><span class="mi">2</span><span class="p">,</span> <span class="s">&#39;O&#39;</span><span class="p">)]</span>
<span class="gp">&gt;&gt;&gt; </span><span class="k">for</span> <span class="n">item</span> <span class="ow">in</span> <span class="n">data</span><span class="p">:</span>
<span class="gp">... </span>    <span class="n">heappush</span><span class="p">(</span><span class="n">heap</span><span class="p">,</span> <span class="n">item</span><span class="p">)</span>
<span class="gp">...</span>
<span class="gp">&gt;&gt;&gt; </span><span class="k">while</span> <span class="n">heap</span><span class="p">:</span>
<span class="gp">... </span>    <span class="k">print</span> <span class="n">heappop</span><span class="p">(</span><span class="n">heap</span><span class="p">)[</span><span class="mi">1</span><span class="p">]</span>
<span class="go">J</span>
<span class="go">O</span>
<span class="go">H</span>
<span class="go">N</span>
</pre></div>
</div>
<p>The module also offers three general purpose functions based on heaps.</p>
<dl class="function">
<dt id="heapq.merge">
<tt class="descclassname">heapq.</tt><tt class="descname">merge</tt><big>(</big><em>*iterables</em><big>)</big><a class="headerlink" href="#heapq.merge" title="Permalink to this definition">¶</a></dt>
<dd><p>Merge multiple sorted inputs into a single sorted output (for example, merge
timestamped entries from multiple log files).  Returns an <a class="reference external" href="../glossary.html#term-iterator"><em class="xref">iterator</em></a>
over the sorted values.</p>
<p>Similar to <tt class="docutils literal"><span class="pre">sorted(itertools.chain(*iterables))</span></tt> but returns an iterable, does
not pull the data into memory all at once, and assumes that each of the input
streams is already sorted (smallest to largest).</p>
<p class="versionadded">
<span class="versionmodified">New in version 2.6.</span></p>
</dd></dl>

<dl class="function">
<dt id="heapq.nlargest">
<tt class="descclassname">heapq.</tt><tt class="descname">nlargest</tt><big>(</big><em>n</em>, <em>iterable</em><span class="optional">[</span>, <em>key</em><span class="optional">]</span><big>)</big><a class="headerlink" href="#heapq.nlargest" title="Permalink to this definition">¶</a></dt>
<dd><p>Return a list with the <em>n</em> largest elements from the dataset defined by
<em>iterable</em>.  <em>key</em>, if provided, specifies a function of one argument that is
used to extract a comparison key from each element in the iterable:
<tt class="docutils literal"><span class="pre">key=str.lower</span></tt> Equivalent to:  <tt class="docutils literal"><span class="pre">sorted(iterable,</span> <span class="pre">key=key,</span>
<span class="pre">reverse=True)[:n]</span></tt></p>
<p class="versionadded">
<span class="versionmodified">New in version 2.4.</span></p>
<p class="versionchanged">
<span class="versionmodified">Changed in version 2.5: </span>Added the optional <em>key</em> argument.</p>
</dd></dl>

<dl class="function">
<dt id="heapq.nsmallest">
<tt class="descclassname">heapq.</tt><tt class="descname">nsmallest</tt><big>(</big><em>n</em>, <em>iterable</em><span class="optional">[</span>, <em>key</em><span class="optional">]</span><big>)</big><a class="headerlink" href="#heapq.nsmallest" title="Permalink to this definition">¶</a></dt>
<dd><p>Return a list with the <em>n</em> smallest elements from the dataset defined by
<em>iterable</em>.  <em>key</em>, if provided, specifies a function of one argument that is
used to extract a comparison key from each element in the iterable:
<tt class="docutils literal"><span class="pre">key=str.lower</span></tt> Equivalent to:  <tt class="docutils literal"><span class="pre">sorted(iterable,</span> <span class="pre">key=key)[:n]</span></tt></p>
<p class="versionadded">
<span class="versionmodified">New in version 2.4.</span></p>
<p class="versionchanged">
<span class="versionmodified">Changed in version 2.5: </span>Added the optional <em>key</em> argument.</p>
</dd></dl>

<p>The latter two functions perform best for smaller values of <em>n</em>.  For larger
values, it is more efficient to use the <a title="sorted" class="reference external" href="functions.html#sorted"><tt class="xref docutils literal"><span class="pre">sorted()</span></tt></a> function.  Also, when
<tt class="docutils literal"><span class="pre">n==1</span></tt>, it is more efficient to use the built-in <a title="min" class="reference external" href="functions.html#min"><tt class="xref docutils literal"><span class="pre">min()</span></tt></a> and <a title="max" class="reference external" href="functions.html#max"><tt class="xref docutils literal"><span class="pre">max()</span></tt></a>
functions.</p>
<div class="section" id="theory">
<h2>8.4.1. Theory<a class="headerlink" href="#theory" title="Permalink to this headline">¶</a></h2>
<p>(This explanation is due to François Pinard.  The Python code for this module
was contributed by Kevin O&#8217;Connor.)</p>
<p>Heaps are arrays for which <tt class="docutils literal"><span class="pre">a[k]</span> <span class="pre">&lt;=</span> <span class="pre">a[2*k+1]</span></tt> and <tt class="docutils literal"><span class="pre">a[k]</span> <span class="pre">&lt;=</span> <span class="pre">a[2*k+2]</span></tt> for all
<em>k</em>, counting elements from 0.  For the sake of comparison, non-existing
elements are considered to be infinite.  The interesting property of a heap is
that <tt class="docutils literal"><span class="pre">a[0]</span></tt> is always its smallest element.</p>
<p>The strange invariant above is meant to be an efficient memory representation
for a tournament.  The numbers below are <em>k</em>, not <tt class="docutils literal"><span class="pre">a[k]</span></tt>:</p>
<div class="highlight-python"><pre>                               0

              1                                 2

      3               4                5               6

  7       8       9       10      11      12      13      14

15 16   17 18   19 20   21 22   23 24   25 26   27 28   29 30</pre>
</div>
<p>In the tree above, each cell <em>k</em> is topping <tt class="docutils literal"><span class="pre">2*k+1</span></tt> and <tt class="docutils literal"><span class="pre">2*k+2</span></tt>. In an usual
binary tournament we see in sports, each cell is the winner over the two cells
it tops, and we can trace the winner down the tree to see all opponents s/he
had.  However, in many computer applications of such tournaments, we do not need
to trace the history of a winner. To be more memory efficient, when a winner is
promoted, we try to replace it by something else at a lower level, and the rule
becomes that a cell and the two cells it tops contain three different items, but
the top cell &#8220;wins&#8221; over the two topped cells.</p>
<p>If this heap invariant is protected at all time, index 0 is clearly the overall
winner.  The simplest algorithmic way to remove it and find the &#8220;next&#8221; winner is
to move some loser (let&#8217;s say cell 30 in the diagram above) into the 0 position,
and then percolate this new 0 down the tree, exchanging values, until the
invariant is re-established. This is clearly logarithmic on the total number of
items in the tree. By iterating over all items, you get an O(n log n) sort.</p>
<p>A nice feature of this sort is that you can efficiently insert new items while
the sort is going on, provided that the inserted items are not &#8220;better&#8221; than the
last 0&#8217;th element you extracted.  This is especially useful in simulation
contexts, where the tree holds all incoming events, and the &#8220;win&#8221; condition
means the smallest scheduled time.  When an event schedule other events for
execution, they are scheduled into the future, so they can easily go into the
heap.  So, a heap is a good structure for implementing schedulers (this is what
I used for my MIDI sequencer :-).</p>
<p>Various structures for implementing schedulers have been extensively studied,
and heaps are good for this, as they are reasonably speedy, the speed is almost
constant, and the worst case is not much different than the average case.
However, there are other representations which are more efficient overall, yet
the worst cases might be terrible.</p>
<p>Heaps are also very useful in big disk sorts.  You most probably all know that a
big sort implies producing &#8220;runs&#8221; (which are pre-sorted sequences, which size is
usually related to the amount of CPU memory), followed by a merging passes for
these runs, which merging is often very cleverly organised <a class="footnote-reference" href="#id2" id="id1">[1]</a>. It is very
important that the initial sort produces the longest runs possible.  Tournaments
are a good way to that.  If, using all the memory available to hold a
tournament, you replace and percolate items that happen to fit the current run,
you&#8217;ll produce runs which are twice the size of the memory for random input, and
much better for input fuzzily ordered.</p>
<p>Moreover, if you output the 0&#8217;th item on disk and get an input which may not fit
in the current tournament (because the value &#8220;wins&#8221; over the last output value),
it cannot fit in the heap, so the size of the heap decreases.  The freed memory
could be cleverly reused immediately for progressively building a second heap,
which grows at exactly the same rate the first heap is melting.  When the first
heap completely vanishes, you switch heaps and start a new run.  Clever and
quite effective!</p>
<p>In a word, heaps are useful memory structures to know.  I use them in a few
applications, and I think it is good to keep a &#8216;heap&#8217; module around. :-)</p>
<p class="rubric">Footnotes</p>
<table class="docutils footnote" frame="void" id="id2" rules="none">
<colgroup><col class="label" /><col /></colgroup>
<tbody valign="top">
<tr><td class="label"><a class="fn-backref" href="#id1">[1]</a></td><td>The disk balancing algorithms which are current, nowadays, are more annoying
than clever, and this is a consequence of the seeking capabilities of the disks.
On devices which cannot seek, like big tape drives, the story was quite
different, and one had to be very clever to ensure (far in advance) that each
tape movement will be the most effective possible (that is, will best
participate at &#8220;progressing&#8221; the merge).  Some tapes were even able to read
backwards, and this was also used to avoid the rewinding time. Believe me, real
good tape sorts were quite spectacular to watch! From all times, sorting has
always been a Great Art! :-)</td></tr>
</tbody>
</table>
</div>
</div>


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            <ul>
<li><a class="reference external" href="#">8.4. <tt class="docutils literal"><span class="pre">heapq</span></tt> &#8212; Heap queue algorithm</a><ul>
<li><a class="reference external" href="#theory">8.4.1. Theory</a></li>
</ul>
</li>
</ul>

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