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- <div class="section" id="representing-dimensions">
- <h1><a class="toc-backref" href="./dimensional-analysis.html#id42" name="representing-dimensions">Representing Dimensions</a></h1>
- <p>An international standard called <em>Système
- International d'Unites</em> (SI), breaks every quantity down into a
- combination of the dimensions <em>mass</em>, <em>length</em> (or <em>position</em>),
- <em>time</em>, <em>charge</em>, <em>temperature</em>, <em>intensity</em>, and <em>angle</em>. To be
- reasonably general, our system would have to be able to
- represent seven or more fundamental dimensions. It also needs
- the ability to represent composite dimensions that, like <em>force</em>,
- are built through multiplication or division of the fundamental
- ones.</p>
- <p>In general, a composite dimension is the product of powers of
- fundamental dimensions. <a class="footnote-reference" href="#divisor" id="id6" name="id6">[1]</a> If we were going to represent
- these powers for manipulation at runtime, we could use an array of
- seven <tt class="literal"><span class="pre">int</span></tt>s, with each position in the array holding the power
- of a different fundamental dimension:</p>
- <pre class="literal-block">
- typedef int dimension[7]; // m l t ...
- dimension const mass = {1, 0, 0, 0, 0, 0, 0};
- dimension const length = {0, 1, 0, 0, 0, 0, 0};
- dimension const time = {0, 0, 1, 0, 0, 0, 0};
- ...
- </pre>
- <table class="footnote" frame="void" id="divisor" rules="none">
- <colgroup><col class="label" /><col /></colgroup>
- <tbody valign="top">
- <tr><td class="label"><a class="fn-backref" href="#id6" name="divisor">[1]</a></td><td>Divisors just contribute negative exponents, since
- 1/<em>x</em> = <em>x</em><sup>-1</sup>.</td></tr>
- </tbody>
- </table>
- <p>In that representation, force would be:</p>
- <pre class="literal-block">
- dimension const force = {1, 1, -2, 0, 0, 0, 0};
- </pre>
- <!-- @compile(2) -->
- <!-- @litre_translator.line_offset -= 7 -->
- <p>that is, <em>mlt</em><sup>-2</sup>. However, if we want to get dimensions into the
- type system, these arrays won't do the trick: they're all
- the same type! Instead, we need types that <em>themselves</em> represent
- sequences of numbers, so that two masses have the same type and a
- mass is a different type from a length.</p>
- <p>Fortunately, the MPL provides us with a collection of <strong>type
- sequences</strong>. For example, we can build a sequence of the built-in
- signed integral types this way:</p>
- <pre class="literal-block">
- #include <boost/mpl/vector.hpp>
- typedef boost::mpl::vector<
- signed char, short, int, long> signed_types;
- </pre>
- <p>How can we use a type sequence to represent numbers? Just as
- numerical metafunctions pass and return wrapper <em>types</em> having a
- nested <tt class="literal"><span class="pre">::value</span></tt>, so numerical sequences are really sequences of
- wrapper types (another example of polymorphism). To make this sort
- of thing easier, MPL supplies the <tt class="literal"><span class="pre">int_<N></span></tt> class template, which
- presents its integral argument as a nested <tt class="literal"><span class="pre">::value</span></tt>:</p>
- <pre class="literal-block">
- #include <boost/mpl/int.hpp>
- namespace mpl = boost::mpl; // namespace alias
- static int const five = mpl::int_<5>::value;
- </pre>
- <div class="sidebar">
- <p class="sidebar-title first">Namespace Aliases</p>
- <div class="line-block">
- <div class="line"><tt class="literal"><span class="pre">namespace</span></tt> <em>alias</em> <tt class="literal"><span class="pre">=</span></tt> <em>namespace-name</em><tt class="literal"><span class="pre">;</span></tt></div>
- </div>
- <p>declares <em>alias</em> to be a synonym for <em>namespace-name</em>. Many
- examples in this book will use <tt class="literal"><span class="pre">mpl::</span></tt> to indicate
- <tt class="literal"><span class="pre">boost::mpl::</span></tt>, but will omit the alias that makes it legal
- C++.</p>
- </div>
- <!-- @ignore() # nonsense isn't worth testing
- prefix +=['''
- #include <boost/mpl/int.hpp>
- #include <boost/mpl/vector.hpp>
- '''] -->
- <p>In fact, the library contains a whole suite of integral constant
- wrappers such as <tt class="literal"><span class="pre">long_</span></tt> and <tt class="literal"><span class="pre">bool_</span></tt>, each one wrapping a
- different type of integral constant within a class template.</p>
- <p>Now we can build our fundamental dimensions:</p>
- <pre class="literal-block">
- typedef mpl::vector<
- mpl::int_<1>, mpl::int_<0>, mpl::int_<0>, mpl::int_<0>
- , mpl::int_<0>, mpl::int_<0>, mpl::int_<0>
- > mass;
- typedef mpl::vector<
- mpl::int_<0>, mpl::int_<1>, mpl::int_<0>, mpl::int_<0>
- , mpl::int_<0>, mpl::int_<0>, mpl::int_<0>
- > length;
- ...
- </pre>
- <!-- @ # We explained about the implicit namespace alias above
- prefix.append("""
- namespace boost{namespace mpl {}}
- namespace mpl = boost::mpl;
- """)
- compile('all') -->
- <p>Whew! That's going to get tiring pretty quickly. Worse, it's hard
- to read and verify: The essential information, the powers of each
- fundamental dimension, is buried in repetitive syntactic "noise."
- Accordingly, MPL supplies <strong>integral sequence wrappers</strong> that allow
- us to write:</p>
- <pre class="literal-block">
- #include <boost/mpl/vector_c.hpp>
- typedef mpl::vector_c<int,1,0,0,0,0,0,0> mass;
- typedef mpl::vector_c<int,0,1,0,0,0,0,0> length; // or position
- typedef mpl::vector_c<int,0,0,1,0,0,0,0> time;
- typedef mpl::vector_c<int,0,0,0,1,0,0,0> charge;
- typedef mpl::vector_c<int,0,0,0,0,1,0,0> temperature;
- typedef mpl::vector_c<int,0,0,0,0,0,1,0> intensity;
- typedef mpl::vector_c<int,0,0,0,0,0,0,1> angle;
- </pre>
- <p>Even though they have different types, you can think of these
- <tt class="literal"><span class="pre">mpl::vector_c</span></tt> specializations as being equivalent to the more
- verbose versions above that use <tt class="literal"><span class="pre">mpl::vector</span></tt>.</p>
- <p>If we want, we can also define a few composite dimensions:</p>
- <pre class="literal-block">
- // base dimension: m l t ...
- typedef mpl::vector_c<int,0,1,-1,0,0,0,0> velocity; // l/t
- typedef mpl::vector_c<int,0,1,-2,0,0,0,0> acceleration; // l/(t<sup>2</sup>)
- typedef mpl::vector_c<int,1,1,-1,0,0,0,0> momentum; // ml/t
- typedef mpl::vector_c<int,1,1,-2,0,0,0,0> force; // ml/(t<sup>2</sup>)
- </pre>
- <p>And, incidentally, the dimensions of scalars (like pi) can be
- described as:</p>
- <pre class="literal-block">
- typedef mpl::vector_c<int,0,0,0,0,0,0,0> scalar;
- </pre>
- <!-- @stack[0].replace('hpp>', 'hpp>\nnamespace {')
- stack[0].append('}')
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