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<!-- Created by texi2html 1.56k from cln.texi on 4 May 2000 -->
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<TITLE>CLN, a Class Library for Numbers - 3. Ordinary number types</TITLE>
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<BODY>
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Go to the <A HREF="cln_1.html">first</A>, <A HREF="cln_2.html">previous</A>, <A HREF="cln_4.html">next</A>, <A HREF="cln_13.html">last</A> section, <A HREF="cln_toc.html">table of contents</A>.
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<P><HR><P>
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<H1><A NAME="SEC10" HREF="cln_toc.html#TOC10">3. Ordinary number types</A></H1>
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<P>
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CLN implements the following class hierarchy:
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<PRE>
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Number
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cl_number
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<cl_number.h>
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Real or complex number
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cl_N
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<cl_complex.h>
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Real number
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cl_R
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<cl_real.h>
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+-------------------+-------------------+
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Rational number Floating-point number
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cl_RA cl_F
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<cl_rational.h> <cl_float.h>
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| +-------------+-------------+-------------+
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Integer | | | |
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cl_I Short-Float Single-Float Double-Float Long-Float
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<cl_integer.h> cl_SF cl_FF cl_DF cl_LF
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<cl_sfloat.h> <cl_ffloat.h> <cl_dfloat.h> <cl_lfloat.h>
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</PRE>
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<P>
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<A NAME="IDX6"></A>
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<A NAME="IDX7"></A>
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The base class <CODE>cl_number</CODE> is an abstract base class.
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It is not useful to declare a variable of this type except if you want
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to completely disable compile-time type checking and use run-time type
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checking instead.
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<P>
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<A NAME="IDX8"></A>
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<A NAME="IDX9"></A>
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<A NAME="IDX10"></A>
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The class <CODE>cl_N</CODE> comprises real and complex numbers. There is
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no special class for complex numbers since complex numbers with imaginary
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part <CODE>0</CODE> are automatically converted to real numbers.
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<P>
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<A NAME="IDX11"></A>
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The class <CODE>cl_R</CODE> comprises real numbers of different kinds. It is an
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abstract class.
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<P>
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<A NAME="IDX12"></A>
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<A NAME="IDX13"></A>
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<A NAME="IDX14"></A>
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The class <CODE>cl_RA</CODE> comprises exact real numbers: rational numbers, including
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integers. There is no special class for non-integral rational numbers
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since rational numbers with denominator <CODE>1</CODE> are automatically converted
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to integers.
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<P>
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<A NAME="IDX15"></A>
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The class <CODE>cl_F</CODE> implements floating-point approximations to real numbers.
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It is an abstract class.
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<H2><A NAME="SEC11" HREF="cln_toc.html#TOC11">3.1 Exact numbers</A></H2>
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<P>
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<A NAME="IDX16"></A>
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<P>
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Some numbers are represented as exact numbers: there is no loss of information
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when such a number is converted from its mathematical value to its internal
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representation. On exact numbers, the elementary operations (<CODE>+</CODE>,
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<CODE>-</CODE>, <CODE>*</CODE>, <CODE>/</CODE>, comparisons, ...) compute the completely
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correct result.
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<P>
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In CLN, the exact numbers are:
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<UL>
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<LI>
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rational numbers (including integers),
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<LI>
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complex numbers whose real and imaginary parts are both rational numbers.
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</UL>
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<P>
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Rational numbers are always normalized to the form
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<CODE><VAR>numerator</VAR>/<VAR>denominator</VAR></CODE> where the numerator and denominator
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are coprime integers and the denominator is positive. If the resulting
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denominator is <CODE>1</CODE>, the rational number is converted to an integer.
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<P>
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Small integers (typically in the range <CODE>-2^30</CODE>...<CODE>2^30-1</CODE>,
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for 32-bit machines) are especially efficient, because they consume no heap
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allocation. Otherwise the distinction between these immediate integers
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(called "fixnums") and heap allocated integers (called "bignums")
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is completely transparent.
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<H2><A NAME="SEC12" HREF="cln_toc.html#TOC12">3.2 Floating-point numbers</A></H2>
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<P>
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<A NAME="IDX17"></A>
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<P>
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Not all real numbers can be represented exactly. (There is an easy mathematical
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proof for this: Only a countable set of numbers can be stored exactly in
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a computer, even if one assumes that it has unlimited storage. But there
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are uncountably many real numbers.) So some approximation is needed.
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CLN implements ordinary floating-point numbers, with mantissa and exponent.
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<P>
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<A NAME="IDX18"></A>
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The elementary operations (<CODE>+</CODE>, <CODE>-</CODE>, <CODE>*</CODE>, <CODE>/</CODE>, ...)
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only return approximate results. For example, the value of the expression
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<CODE>(cl_F) 0.3 + (cl_F) 0.4</CODE> prints as <SAMP>`0.70000005'</SAMP>, not as
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<SAMP>`0.7'</SAMP>. Rounding errors like this one are inevitable when computing
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with floating-point numbers.
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<P>
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Nevertheless, CLN rounds the floating-point results of the operations <CODE>+</CODE>,
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<CODE>-</CODE>, <CODE>*</CODE>, <CODE>/</CODE>, <CODE>sqrt</CODE> according to the "round-to-even"
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rule: It first computes the exact mathematical result and then returns the
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floating-point number which is nearest to this. If two floating-point numbers
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are equally distant from the ideal result, the one with a <CODE>0</CODE> in its least
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significant mantissa bit is chosen.
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<P>
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Similarly, testing floating point numbers for equality <SAMP>`x == y'</SAMP>
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is gambling with random errors. Better check for <SAMP>`abs(x - y) < epsilon'</SAMP>
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for some well-chosen <CODE>epsilon</CODE>.
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<P>
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Floating point numbers come in four flavors:
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<UL>
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<LI>
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<A NAME="IDX19"></A>
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Short floats, type <CODE>cl_SF</CODE>.
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They have 1 sign bit, 8 exponent bits (including the exponent's sign),
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and 17 mantissa bits (including the "hidden" bit).
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They don't consume heap allocation.
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<LI>
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<A NAME="IDX20"></A>
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Single floats, type <CODE>cl_FF</CODE>.
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They have 1 sign bit, 8 exponent bits (including the exponent's sign),
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and 24 mantissa bits (including the "hidden" bit).
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In CLN, they are represented as IEEE single-precision floating point numbers.
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This corresponds closely to the C/C++ type <SAMP>`float'</SAMP>.
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<LI>
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<A NAME="IDX21"></A>
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Double floats, type <CODE>cl_DF</CODE>.
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They have 1 sign bit, 11 exponent bits (including the exponent's sign),
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and 53 mantissa bits (including the "hidden" bit).
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In CLN, they are represented as IEEE double-precision floating point numbers.
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This corresponds closely to the C/C++ type <SAMP>`double'</SAMP>.
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<LI>
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<A NAME="IDX22"></A>
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Long floats, type <CODE>cl_LF</CODE>.
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They have 1 sign bit, 32 exponent bits (including the exponent's sign),
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and n mantissa bits (including the "hidden" bit), where n >= 64.
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The precision of a long float is unlimited, but once created, a long float
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has a fixed precision. (No "lazy recomputation".)
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</UL>
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<P>
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Of course, computations with long floats are more expensive than those
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with smaller floating-point formats.
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<P>
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CLN does not implement features like NaNs, denormalized numbers and
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gradual underflow. If the exponent range of some floating-point type
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is too limited for your application, choose another floating-point type
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with larger exponent range.
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<P>
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<A NAME="IDX23"></A>
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As a user of CLN, you can forget about the differences between the
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four floating-point types and just declare all your floating-point
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variables as being of type <CODE>cl_F</CODE>. This has the advantage that
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when you change the precision of some computation (say, from <CODE>cl_DF</CODE>
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to <CODE>cl_LF</CODE>), you don't have to change the code, only the precision
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of the initial values. Also, many transcendental functions have been
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declared as returning a <CODE>cl_F</CODE> when the argument is a <CODE>cl_F</CODE>,
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but such declarations are missing for the types <CODE>cl_SF</CODE>, <CODE>cl_FF</CODE>,
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<CODE>cl_DF</CODE>, <CODE>cl_LF</CODE>. (Such declarations would be wrong if
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the floating point contagion rule happened to change in the future.)
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<H2><A NAME="SEC13" HREF="cln_toc.html#TOC13">3.3 Complex numbers</A></H2>
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<P>
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<A NAME="IDX24"></A>
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<P>
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Complex numbers, as implemented by the class <CODE>cl_N</CODE>, have a real
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part and an imaginary part, both real numbers. A complex number whose
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imaginary part is the exact number <CODE>0</CODE> is automatically converted
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to a real number.
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<P>
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Complex numbers can arise from real numbers alone, for example
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through application of <CODE>sqrt</CODE> or transcendental functions.
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<H2><A NAME="SEC14" HREF="cln_toc.html#TOC14">3.4 Conversions</A></H2>
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<P>
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<A NAME="IDX25"></A>
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<P>
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Conversions from any class to any its superclasses ("base classes" in
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C++ terminology) is done automatically.
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<P>
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Conversions from the C built-in types <SAMP>`long'</SAMP> and <SAMP>`unsigned long'</SAMP>
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are provided for the classes <CODE>cl_I</CODE>, <CODE>cl_RA</CODE>, <CODE>cl_R</CODE>,
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<CODE>cl_N</CODE> and <CODE>cl_number</CODE>.
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<P>
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Conversions from the C built-in types <SAMP>`int'</SAMP> and <SAMP>`unsigned int'</SAMP>
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are provided for the classes <CODE>cl_I</CODE>, <CODE>cl_RA</CODE>, <CODE>cl_R</CODE>,
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<CODE>cl_N</CODE> and <CODE>cl_number</CODE>. However, these conversions emphasize
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efficiency. Their range is therefore limited:
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<UL>
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<LI>
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The conversion from <SAMP>`int'</SAMP> works only if the argument is < 2^29 and > -2^29.
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<LI>
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The conversion from <SAMP>`unsigned int'</SAMP> works only if the argument is < 2^29.
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</UL>
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<P>
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In a declaration like <SAMP>`cl_I x = 10;'</SAMP> the C++ compiler is able to
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do the conversion of <CODE>10</CODE> from <SAMP>`int'</SAMP> to <SAMP>`cl_I'</SAMP> at compile time
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already. On the other hand, code like <SAMP>`cl_I x = 1000000000;'</SAMP> is
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in error.
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So, if you want to be sure that an <SAMP>`int'</SAMP> whose magnitude is not guaranteed
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to be < 2^29 is correctly converted to a <SAMP>`cl_I'</SAMP>, first convert it to a
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<SAMP>`long'</SAMP>. Similarly, if a large <SAMP>`unsigned int'</SAMP> is to be converted to a
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<SAMP>`cl_I'</SAMP>, first convert it to an <SAMP>`unsigned long'</SAMP>.
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<P>
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Conversions from the C built-in type <SAMP>`float'</SAMP> are provided for the classes
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<CODE>cl_FF</CODE>, <CODE>cl_F</CODE>, <CODE>cl_R</CODE>, <CODE>cl_N</CODE> and <CODE>cl_number</CODE>.
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<P>
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Conversions from the C built-in type <SAMP>`double'</SAMP> are provided for the classes
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<CODE>cl_DF</CODE>, <CODE>cl_F</CODE>, <CODE>cl_R</CODE>, <CODE>cl_N</CODE> and <CODE>cl_number</CODE>.
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<P>
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Conversions from <SAMP>`const char *'</SAMP> are provided for the classes
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<CODE>cl_I</CODE>, <CODE>cl_RA</CODE>,
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<CODE>cl_SF</CODE>, <CODE>cl_FF</CODE>, <CODE>cl_DF</CODE>, <CODE>cl_LF</CODE>, <CODE>cl_F</CODE>,
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<CODE>cl_R</CODE>, <CODE>cl_N</CODE>.
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The easiest way to specify a value which is outside of the range of the
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C++ built-in types is therefore to specify it as a string, like this:
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<A NAME="IDX26"></A>
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<PRE>
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cl_I order_of_rubiks_cube_group = "43252003274489856000";
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</PRE>
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<P>
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Note that this conversion is done at runtime, not at compile-time.
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<P>
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Conversions from <CODE>cl_I</CODE> to the C built-in types <SAMP>`int'</SAMP>,
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<SAMP>`unsigned int'</SAMP>, <SAMP>`long'</SAMP>, <SAMP>`unsigned long'</SAMP> are provided through
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the functions
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<DL COMPACT>
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<DT><CODE>int cl_I_to_int (const cl_I& x)</CODE>
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<DD>
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<A NAME="IDX27"></A>
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<DT><CODE>unsigned int cl_I_to_uint (const cl_I& x)</CODE>
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<DD>
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<A NAME="IDX28"></A>
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<DT><CODE>long cl_I_to_long (const cl_I& x)</CODE>
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<DD>
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<A NAME="IDX29"></A>
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<DT><CODE>unsigned long cl_I_to_ulong (const cl_I& x)</CODE>
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<DD>
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<A NAME="IDX30"></A>
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Returns <CODE>x</CODE> as element of the C type <VAR>ctype</VAR>. If <CODE>x</CODE> is not
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representable in the range of <VAR>ctype</VAR>, a runtime error occurs.
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</DL>
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<P>
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Conversions from the classes <CODE>cl_I</CODE>, <CODE>cl_RA</CODE>,
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<CODE>cl_SF</CODE>, <CODE>cl_FF</CODE>, <CODE>cl_DF</CODE>, <CODE>cl_LF</CODE>, <CODE>cl_F</CODE> and
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<CODE>cl_R</CODE>
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to the C built-in types <SAMP>`float'</SAMP> and <SAMP>`double'</SAMP> are provided through
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the functions
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<DL COMPACT>
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<DT><CODE>float cl_float_approx (const <VAR>type</VAR>& x)</CODE>
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<DD>
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<A NAME="IDX31"></A>
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<DT><CODE>double cl_double_approx (const <VAR>type</VAR>& x)</CODE>
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<DD>
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<A NAME="IDX32"></A>
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Returns an approximation of <CODE>x</CODE> of C type <VAR>ctype</VAR>.
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If <CODE>abs(x)</CODE> is too close to 0 (underflow), 0 is returned.
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If <CODE>abs(x)</CODE> is too large (overflow), an IEEE infinity is returned.
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</DL>
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<P>
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Conversions from any class to any of its subclasses ("derived classes" in
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C++ terminology) are not provided. Instead, you can assert and check
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that a value belongs to a certain subclass, and return it as element of that
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class, using the <SAMP>`As'</SAMP> and <SAMP>`The'</SAMP> macros.
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<A NAME="IDX33"></A>
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<CODE>As(<VAR>type</VAR>)(<VAR>value</VAR>)</CODE> checks that <VAR>value</VAR> belongs to
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<VAR>type</VAR> and returns it as such.
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<A NAME="IDX34"></A>
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<CODE>The(<VAR>type</VAR>)(<VAR>value</VAR>)</CODE> assumes that <VAR>value</VAR> belongs to
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<VAR>type</VAR> and returns it as such. It is your responsibility to ensure
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that this assumption is valid.
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Example:
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<PRE>
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cl_I x = ...;
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if (!(x >= 0)) abort();
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cl_I ten_x = The(cl_I)(expt(10,x)); // If x >= 0, 10^x is an integer.
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// In general, it would be a rational number.
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</PRE>
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<P><HR><P>
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Go to the <A HREF="cln_1.html">first</A>, <A HREF="cln_2.html">previous</A>, <A HREF="cln_4.html">next</A>, <A HREF="cln_13.html">last</A> section, <A HREF="cln_toc.html">table of contents</A>.
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</BODY>
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</HTML>
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