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+# Shellmath
+Introducing decimal arithmetic libraries for the Bash shell, because
+they said it couldn't be done... and because:
+
+.
+
+![image info](./image.png)
+
+## Quick-start guide
+Download this project and source the file `shellmath.sh` into your shell script,
+then fire away at the shellmath API!
+
+The ___basic___ API looks like this:
+```
+    _shellmath_add        arg1   arg2  [...]  argN
+    _shellmath_subtract   arg1   arg2               # means arg1 - arg2
+    _shellmath_multiply   arg1   arg2  [...]  argN
+    _shellmath_divide     arg1   arg2               # means arg1 / arg2
+```
+
+The ___extended___ API introduces one more function:
+```
+    _shellmath_getReturnValue   arg
+```
+
+This function optimizes away the need for ___$(___ subshelling ___)___ in order to capture `shellmath`'s output.
+To use this feature, just be sure to set `__shellmath_isOptimized=1` at the top
+of your script. (You can find an example in `faster_e_demo.sh`.)
+
+Operands to the _shellmath_ functions can be integers or decimal
+numbers presented in either standard or scientific notation:
+```
+    _shellmath_add   1.009   4.223e-2
+    _shellmath_getReturnValue   sum
+    echo "The sum is $sum"
+```
+Addition and multiplication are of arbitrary arity; try this on for size:
+```
+    _shellmath_multiply  1  2  3  4  5  6
+    _shellmath_getReturnValue   sixFactorial
+    echo "6 factorial is $sixFactorial"
+```
+Subtraction and division, OTOH, are exclusively binary operations. 
+
+## The demos
+For a gentle introduction to `shellmath` run the demo `slower_e_demo.sh` 
+with a small whole-number argument, say 15:
+```
+$ slower_e_demo.sh 15
+e = 2.7182818284589936
+```
+
+This script uses a few `shellmath` API calls to calculate *e*, the mathematical
+constant also known as [Euler's number](https://oeis.org/A001113). The argument 
+*15* tells the script to evaluate the *15th-degree* Maclaurin polynomial for *e*.
+(That's the Taylor polynomial centered at 0.) Take a look inside the script to
+see how it uses the `shellmath` APIs.
+
+There is another demo script very much like this one but *different*, and the
+sensitive user can *feel* the difference. Try the following, but don't blink 
+or you'll miss it ;)
+```
+$ faster_e_demo.sh 15
+e = 2.7182818284589936
+```
+
+Did you feel the difference? Try the `-t` option with both scripts; this will produce
+timing statistics. Here are my results
+when running from my minGW64 command prompt on Windows 10 with an Intel i3 Core CPU:
+```
+$ for n in {1..5}; do faster_e_demo.sh -t 15 2>&1; done | awk '/^real/ {print $2}'
+0m0.055s
+0m0.051s
+0m0.056s
+0m0.054s
+0m0.054s
+
+$ for n in {1..5}; do slower_e_demo.sh -t 15 2>&1; done | awk '/^real/ {print $2}'
+0m0.498s
+0m0.594s
+0m0.536s
+0m0.511s
+0m0.580s
+```
+
+(When sizing up these timings, do keep in mind that ___we are timing the
+calculation of e from its Maclaurin polynomial. Every invocation of either
+script is exercising the shellmath arithmetic subroutines 31 times.___)
+
+The comment header in `faster_e_demo.sh` explains the optimization and shows
+how to put this faster version to work for you.
+
+## Runtime efficiency competitive with awk and bc
+The file `timingData.txt` captures the results of some timing experiments that compare 
+`shellmath` against the GNU versions of the calculators `awk` and `bc`. The experiments
+exercised each of the arithmetic operations and captured the results in a shell variable.
+The result summary below shows that `shellmath` is competitive with `awk` and runs faster
+than `bc` in these experiments. (One commenter noted that the differences in execution speed
+can be partially explained by the fact that `shellmath` and `awk` use finite precision 
+whereas `bc` uses arbitrary precision. Another factor in these measurements is the need to 
+subshell 'awk' and 'bc' to capture their results, whereas 'shellmath' writes directly to
+the shell's global memory.)
+
+Here are the run times of `shellmath` as a percentage of the `awk` and `bc` equivalents:
+```
+                    versus awk    versus bc
+   Addition:          82.2%         40.6%
+   Subtraction:       95.9%         50.5%
+   Multiplication:   135.9%         73.3%
+   Division:          80.3%         43.2%
+```
+
+Astute observers will note the experiments provide approximations to the sum, difference, 
+product, and quotient of *pi* and *e*. Unfortunately I did not gain insight as to which 
+of these values, if any, are
+[transcendental](https://en.wikipedia.org/wiki/Transcendental_number#Possible_transcendental_numbers).
+
+You can find a deeper discussion of shellmath's runtime efficiency
+[here](https://github.com/clarity20/shellmath/wiki/Shellmath-and-runtime-efficiency).
+
+## Background
+The Bash shell does not have built-in operators for decimal arithmetic, making it
+something of an oddity among well-known, widely-used programming languages. For the most part,
+practitioners in need of powerful computational building blocks have naturally opted
+for *other* languages and tools. Their widespread availability has diverted attention
+from the possibility of *implementing* decimal arithmetic in Bash and it's easy to assume
+that this ***cannot*** be done:
+
++ From the indispensable _Bash FAQ_ (on _Greg's Wiki_): [How can I calculate with floating point numbers?](http://mywiki.wooledge.org/BashFAQ/022)  
+  *"For most operations... an external program must be used."*
++ From Mendel Cooper's wonderful and encyclopedic _Advanced Bash Scripting Guide_:  
+  [Bash does not understand floating point arithmetic. Use bc instead.](https://tldp.org/LDP/abs/html/ops.html#NOFLOATINGPOINT)
++ From a community discussion on Stack Overflow, _How do I use floating point division in bash?_  
+  The user's [preferred answer](https://stackoverflow.com/questions/12722095/how-do-i-use-floating-point-division-in-bash#12722107)
+  is a good example of _prevailing thought_ on this subject.
+
+Meanwhile, 
+
++ Bash maintainer (BDFL?) Chet Ramey sounds a (brighter?) note in [The Bash Reference Guide, Section 6.5](https://tiswww.case.edu/php/chet/bash/bashref.html#Shell-Arithmetic)
+  by emphasizing what the built-in arithmetic operators ***can*** do.
+
+But finally, a glimmer of hope:
+
++ A [diamond-in-the-rough](http://stackoverflow.com/a/24431665/3776858) buried elsewhere
+  on Stack Overflow.  
+  This down-and-dirty milestone computes the decimal quotient of two integer arguments. At a casual
+  glance, it seems to have drawn inspiration from the [Euclidean algorithm](https://mathworld.wolfram.com/EuclideanAlgorithm.html)
+  for computing GCDs, an entirely different approach than `shellmath`'s.
+
+Please try `shellmath` on for size and draw your own conclusions!
+
+## How it works
+`shellmath` splits decimal numbers into their integer and fractional parts,
+performs the appropriate integer operations on the parts, and recombines the results.
+(In the spirit of Bash, numerical overflow is silently ignored.)
+
+Because if we can get carrying, borrowing, place value, and the distributive
+law right, then the sky's the limit! As they say--erm, as they ___said___ in Rome,
+
+        Ad astra per aspera.
+
+## And now...
+You can run your floating-point calculations directly in Bash!
+
+## Please see also:
+[A short discussion on arbitrary precision and shellmath](https://github.com/clarity20/shellmath/wiki/Shellmath-and-arbitrary-precision-arithmetic)