From 82ba818ff456bcd6d56a06226e3f27e98fbb55c3 Mon Sep 17 00:00:00 2001
From: Craig Jennings <c@cjennings.net>
Date: Thu, 14 Aug 2025 22:58:58 -0500
Subject: removing all downloaded devdocs files

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-    <h1 id="firstHeading" class="firstHeading">pow, powf, powl</h1>            <table class="t-dcl-begin"> <tr class="t-dsc-header"> <th> Defined in header <code>&lt;math.h&gt;</code> </th> <th> </th> <th> </th> </tr> <tr class="t-dcl t-since-c99"> <td> <pre data-language="c">float powf( float base, float exponent );</pre>
-</td> <td> (1) </td> <td> <span class="t-mark-rev t-since-c99">(since C99)</span> </td> </tr> <tr class="t-dcl"> <td> <pre data-language="c">double pow( double base, double exponent );</pre>
-</td> <td> (2) </td> <td class="t-dcl-nopad"> </td> </tr> <tr class="t-dcl t-since-c99"> <td> <pre data-language="c">long double powl( long double base, long double exponent );</pre>
-</td> <td> (3) </td> <td> <span class="t-mark-rev t-since-c99">(since C99)</span> </td> </tr> <tr class="t-dsc-header"> <th> Defined in header <code>&lt;tgmath.h&gt;</code> </th> <th> </th> <th> </th> </tr> <tr class="t-dcl t-since-c99"> <td> <pre data-language="c">#define pow( base, exponent )</pre>
-</td> <td> (4) </td> <td> <span class="t-mark-rev t-since-c99">(since C99)</span> </td> </tr>  </table> <div class="t-li1">
-<span class="t-li">1-3)</span> Computes the value of <code>base</code> raised to the power <code>exponent</code>.</div> <div class="t-li1">
-<span class="t-li">4)</span> Type-generic macro: If any argument has type <code>long double</code>, <code>powl</code> is called. Otherwise, if any argument has integer type or has type <code>double</code>, <code>pow</code> is called. Otherwise, <code>powf</code> is called. If at least one argument is complex or imaginary, then the macro invokes the corresponding complex function (<code><a href="http://en.cppreference.com/w/c/numeric/complex/cpow"><span class="kw775">cpowf</span></a></code>, <code><a href="http://en.cppreference.com/w/c/numeric/complex/cpow"><span class="kw774">cpow</span></a></code>, <code><a href="http://en.cppreference.com/w/c/numeric/complex/cpow"><span class="kw776">cpowl</span></a></code>).</div>  <h3 id="Parameters"> Parameters</h3> <table class="t-par-begin"> <tr class="t-par"> <td> base </td> <td> - </td> <td> base as floating point value </td>
-</tr> <tr class="t-par"> <td> exponent </td> <td> - </td> <td> exponent as floating point value </td>
-</tr>
-</table> <h3 id="Return_value"> Return value</h3> <p>If no errors occur, <code>base</code> raised to the power of <code>exponent</code> (base<sup class="t-su">exponent</sup>) is returned.</p>
-<p>If a domain error occurs, an implementation-defined value is returned (NaN where supported).</p>
-<p>If a pole error or a range error due to overflow occurs, <code><a href="huge_val" title="c/numeric/math/HUGE VAL">±HUGE_VAL</a></code>, <code>±HUGE_VALF</code>, or <code>±HUGE_VALL</code> is returned.</p>
-<p>If a range error occurs due to underflow, the correct result (after rounding) is returned.</p>
-<h3 id="Error_handling"> Error handling</h3> <p>Errors are reported as specified in <a href="math_errhandling" title="c/numeric/math/math errhandling"><code>math_errhandling</code></a>.</p>
-<p>If <code>base</code> is finite and negative and <code>exponent</code> is finite and non-integer, a domain error occurs and a range error may occur.</p>
-<p>If <code>base</code> is zero and <code>exponent</code> is zero, a domain error may occur.</p>
-<p>If <code>base</code> is zero and <code>exponent</code> is negative, a domain error or a pole error may occur.</p>
-<p>If the implementation supports IEEE floating-point arithmetic (IEC 60559),</p>
-<ul>
-<li> <code>pow(+0, exponent)</code>, where <code>exponent</code> is a negative odd integer, returns <code>+∞</code> and raises <code><a href="../fenv/fe_exceptions" title="c/numeric/fenv/FE exceptions">FE_DIVBYZERO</a></code> </li>
-<li> <code>pow(-0, exponent)</code>, where <code>exponent</code> is a negative odd integer, returns <code>-∞</code> and raises <code><a href="../fenv/fe_exceptions" title="c/numeric/fenv/FE exceptions">FE_DIVBYZERO</a></code> </li>
-<li> <code>pow(±0, exponent)</code>, where <code>exponent</code> is negative, finite, and is an even integer or a non-integer, returns +∞ and raises <code><a href="../fenv/fe_exceptions" title="c/numeric/fenv/FE exceptions">FE_DIVBYZERO</a></code> </li>
-<li> <code>pow(±0, -∞)</code> returns +∞ <span class="t-rev-inl t-until-c23"><span>and may raise <code><a href="../fenv/fe_exceptions" title="c/numeric/fenv/FE exceptions">FE_DIVBYZERO</a></code></span><span><span class="t-mark-rev t-until-c23">(until C23)</span></span></span> </li>
-<li> <code>pow(+0, exponent)</code>, where <code>exponent</code> is a positive odd integer, returns +0 </li>
-<li> <code>pow(-0, exponent)</code>, where <code>exponent</code> is a positive odd integer, returns -0 </li>
-<li> <code>pow(±0, exponent)</code>, where <code>exponent</code> is positive non-integer or a positive even integer, returns +0 </li>
-<li> <code>pow(-1, ±∞)</code> returns <code>1</code> </li>
-<li> <code>pow(+1, exponent)</code> returns <code>1</code> for any <code>exponent</code>, even when <code>exponent</code> is <code>NaN</code> </li>
-<li> <code>pow(base, ±0)</code> returns <code>1</code> for any <code>base</code>, even when <code>base</code> is <code>NaN</code> </li>
-<li> <code>pow(base, exponent)</code> returns <code>NaN</code> and raises <code><a href="../fenv/fe_exceptions" title="c/numeric/fenv/FE exceptions">FE_INVALID</a></code> if <code>base</code> is finite and negative and <code>exponent</code> is finite and non-integer. </li>
-<li> <code>pow(base, -∞)</code> returns +∞ for any <code>|base|&lt;1</code> </li>
-<li> <code>pow(base, -∞)</code> returns +0 for any <code>|base|&gt;1</code> </li>
-<li> <code>pow(base, +∞)</code> returns +0 for any <code>|base|&lt;1</code> </li>
-<li> <code>pow(base, +∞)</code> returns +∞ for any <code>|base|&gt;1</code> </li>
-<li> <code>pow(-∞, exponent)</code> returns -0 if <code>exponent</code> is a negative odd integer </li>
-<li> <code>pow(-∞, exponent)</code> returns +0 if <code>exponent</code> is a negative non-integer or negative even integer </li>
-<li> <code>pow(-∞, exponent)</code> returns -∞ if <code>exponent</code> is a positive odd integer </li>
-<li> <code>pow(-∞, exponent)</code> returns +∞ if <code>exponent</code> is a positive non-integer or positive even integer </li>
-<li> <code>pow(+∞, exponent)</code> returns +0 for any negative <code>exponent</code> </li>
-<li> <code>pow(+∞, exponent)</code> returns +∞ for any positive <code>exponent</code> </li>
-<li> except where specified above, if any argument is NaN, NaN is returned </li>
-</ul> <h3 id="Notes"> Notes</h3> <p>Although <code>pow</code> cannot be used to obtain a root of a negative number, <code><a href="cbrt" title="c/numeric/math/cbrt">cbrt</a></code> is provided for the common case where <code>exponent</code> is 1/3.</p>
-<h3 id="Example"> Example</h3> <div class="t-example"> <div class="c source-c"><pre data-language="c">#include &lt;stdio.h&gt;
-#include &lt;math.h&gt;
-#include &lt;errno.h&gt;
-#include &lt;fenv.h&gt;
- 
-#pragma STDC FENV_ACCESS ON
-int main(void)
-{
-    // typical usage
-    printf("pow(2, 10) = %f\n", pow(2,10));
-    printf("pow(2, 0.5) = %f\n", pow(2,0.5));
-    printf("pow(-2, -3) = %f\n", pow(-2,-3));
-    // special values
-    printf("pow(-1, NAN) = %f\n", pow(-1,NAN));
-    printf("pow(+1, NAN) = %f\n", pow(+1,NAN));
-    printf("pow(INFINITY, 2) = %f\n", pow(INFINITY, 2));
-    printf("pow(INFINITY, -1) = %f\n", pow(INFINITY, -1));
-    // error handling 
-    errno = 0; feclearexcept(FE_ALL_EXCEPT);
-    printf("pow(-1, 1/3) = %f\n", pow(-1, 1.0/3));
-    if(errno == EDOM)         perror("    errno == EDOM");
-    if(fetestexcept(FE_INVALID)) puts("    FE_INVALID raised");
- 
-    feclearexcept(FE_ALL_EXCEPT);
-    printf("pow(-0, -3) = %f\n", pow(-0.0, -3));
-    if(fetestexcept(FE_DIVBYZERO)) puts("    FE_DIVBYZERO raised");
-}</pre></div> <p>Possible output:</p>
-<div class="text source-text"><pre data-language="c">pow(2, 10) = 1024.000000
-pow(2, 0.5) = 1.414214
-pow(-2, -3) = -0.125000
-pow(-1, NAN) = nan
-pow(+1, NAN) = 1.000000
-pow(INFINITY, 2) = inf
-pow(INFINITY, -1) = 0.000000
-pow(-1, 1/3) = -nan
-    errno == EDOM: Numerical argument out of domain
-    FE_INVALID raised
-pow(-0, -3) = -inf
-    FE_DIVBYZERO raised</pre></div> </div> <h3 id="References"> References</h3>  <ul>
-<li> C23 standard (ISO/IEC 9899:2023): </li>
-<ul>
-<li> 7.12.7.5 The pow functions </li>
-<li> 7.27 Type-generic math &lt;tgmath.h&gt; </li>
-<li> F.10.4.5 The pow functions (p: 524-525) </li>
-</ul>
-<li> C17 standard (ISO/IEC 9899:2018): </li>
-<ul>
-<li> 7.12.7.4 The pow functions (p: 248-249) </li>
-<li> 7.25 Type-generic math &lt;tgmath.h&gt; (p: 373-375) </li>
-<li> F.10.4.4 The pow functions (p: 524-525) </li>
-</ul>
-<li> C11 standard (ISO/IEC 9899:2011): </li>
-<ul>
-<li> 7.12.7.4 The pow functions (p: 248-249) </li>
-<li> 7.25 Type-generic math &lt;tgmath.h&gt; (p: 373-375) </li>
-<li> F.10.4.4 The pow functions (p: 524-525) </li>
-</ul>
-<li> C99 standard (ISO/IEC 9899:1999): </li>
-<ul>
-<li> 7.12.7.4 The pow functions (p: 229) </li>
-<li> 7.22 Type-generic math &lt;tgmath.h&gt; (p: 335-337) </li>
-<li> F.9.4.4 The pow functions (p: 461) </li>
-</ul>
-<li> C89/C90 standard (ISO/IEC 9899:1990): </li>
-<ul><li> 4.5.5.1 The pow function </li></ul>
-</ul>                           <h3 id="See_also"> See also</h3> <table class="t-dsc-begin"> <tr class="t-dsc"> <td> <div><a href="sqrt" title="c/numeric/math/sqrt"> <span class="t-lines"><span>sqrt</span><span>sqrtf</span><span>sqrtl</span></span></a></div>
-<div><span class="t-lines"><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span></span></div> </td> <td> computes square root (\(\small{\sqrt{x} }\)<span class="t-mrad"><span>√</span><span>x</span></span>) <br> <span class="t-mark">(function)</span>  </td>
-</tr> <tr class="t-dsc"> <td> <div><a href="cbrt" title="c/numeric/math/cbrt"> <span class="t-lines"><span>cbrt</span><span>cbrtf</span><span>cbrtl</span></span></a></div>
-<div><span class="t-lines"><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span></span></div> </td> <td> computes cube root (\(\small{\sqrt[3]{x} }\)<span class="t-mrad"><span>3</span><span>√</span><span>x</span></span>) <br> <span class="t-mark">(function)</span>  </td>
-</tr> <tr class="t-dsc"> <td> <div><a href="hypot" title="c/numeric/math/hypot"> <span class="t-lines"><span>hypot</span><span>hypotf</span><span>hypotl</span></span></a></div>
-<div><span class="t-lines"><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span></span></div> </td> <td> computes square root of the sum of the squares of two given numbers (\(\scriptsize{\sqrt{x^2+y^2} }\)<span class="t-mrad"><span>√</span><span>x<sup class="t-su">2</sup>+y<sup class="t-su">2</sup></span></span>) <br> <span class="t-mark">(function)</span>  </td>
-</tr> <tr class="t-dsc"> <td> <div><a href="../complex/cpow" title="c/numeric/complex/cpow"> <span class="t-lines"><span>cpow</span><span>cpowf</span><span>cpowl</span></span></a></div>
-<div><span class="t-lines"><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span><span><span class="t-mark-rev t-since-c99">(C99)</span></span></span></div> </td> <td> computes the complex power function <br> <span class="t-mark">(function)</span>  </td>
-</tr> <tr class="t-dsc"> <td colspan="2"> <span><a href="https://en.cppreference.com/w/cpp/numeric/math/pow" title="cpp/numeric/math/pow">C++ documentation</a></span> for <code>pow</code> </td>
-</tr> </table>           <div class="_attribution">
-  <p class="_attribution-p">
-    &copy; cppreference.com<br>Licensed under the Creative Commons Attribution-ShareAlike Unported License v3.0.<br>
-    <a href="https://en.cppreference.com/w/c/numeric/math/pow" class="_attribution-link">https://en.cppreference.com/w/c/numeric/math/pow</a>
-  </p>
-</div>
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Defined in header `<math.h>`
float powf( float base, float exponent ); -	(1)	(since C99)
double pow( double base, double exponent ); -	(2)
long double powl( long double base, long double exponent ); -	(3)	(since C99)
Defined in header `<tgmath.h>`
#define pow( base, exponent ) -	(4)	(since C99)
base	-	base as floating point value
exponent	-	exponent as floating point value
sqrtsqrtfsqrtl - (C99)(C99)	computes square root (\(\small{\sqrt{x} }\)√x) (function)
cbrtcbrtfcbrtl - (C99)(C99)(C99)	computes cube root (\(\small{\sqrt[3]{x} }\)3√x) (function)
hypothypotfhypotl - (C99)(C99)(C99)	computes square root of the sum of the squares of two given numbers (\(\scriptsize{\sqrt{x^2+y^2} }\)√x²+y²) (function)
cpowcpowfcpowl - (C99)(C99)(C99)	computes the complex power function (function)
C++ documentation for `pow`