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## Numbers

This egg provides support for the full numeric tower. It adds support for:

- Integers larger than
`most-positive-fixnum`and smaller than`most-negative-fixnum`through bignums, instead of the default behaviour of falling back to inexact flonums. - Rational numbers (fractions), instead of falling back to inexact flonums.
- Complex numbers.

All of these are supported by exporting different versions of the standard numerical procedures. Be sure to import the `numbers` module after the `scheme` module, or to hide the standard numerical procedures from `scheme`. These number types are also supported as read-time literals, but only after loading the extension and only in the interpreter (but see below for limited compile-time support).

This egg also adds a handful of extra procedures. See below.

## Interface

This extension provides support for large exact integers, exact rational and complex numbers.

The following standard procedures are redefined:

+ - * / = > < >= <= abs max min eqv? equal? exp expt log sin cos tan atan asin acos sqrt quotient modulo remainder exact? inexact? exact->inexact inexact->exact positive? negative? even? odd? zero? number? complex? real? rational? integer? gcd lcm truncate ceiling floor round number->string string->number numerator denominator rationalize magnitude angle real-part imag-part

The `log` procedure is extended to allow a second argument specifying the logarithm base, as per R7RS.

The following standard procedures are provided:

make-rectangular make-polar

The following non-standard extended procedures are redefined:

add1 sub1 signum bitwise-and bitwise-ior bitwise-xor bitwise-not arithmetic-shift randomize random finite?

Additionally the following procedures are available:

*[procedure]*

`(infinite? Z)`

Is the number `Z` `+inf.0` or `-inf.0`, or a complex number containing either infinity as its real or imaginary part?

From R6RS and R7RS.

**Note**: This is **not** the inverse of `finite?`, since it produces `#f` on `nan.0` (or complex numbers containing `nan.0`), while `finite?` also returns `#f` in that case.

*[procedure]*

`(nan? Z)`

Is the object `Z` a real representing `nan.0`?

From R6RS and R7RS.

*[procedure]*

`(exact Z)`

*[procedure]*

`(inexact Z)`

Convert `Z` to an exact or an inexact number, respectively. These are just the R6RS and R7RS names for `inexact->exact` and `exact->inexact`.

*[procedure]*

`(exact-integer-sqrt K)`

Returns two values `s` and `r`, where `s^2 + r = K` and `K < (s+1)^2`. In other words, `s` is the closest square root we can find that's equal to or smaller than `K`, and `r` is the rest if `K` isn't a neat square of two numbers.

This procedure is compatible with the R7RS specification.

*[procedure]*

`(exact-integer-nth-root K N)`

Like `exact-integer-sqrt`, but with any base value. Calculates `\sqrt[N]{K`}, the `N`th root of `K` and returns two values `s` and `r` where `s^N + r = K` and `K < (s+1)^N`.

*[procedure]*

`(exact-integer? X)`

Is `X` an exact integer?

*[procedure]*

`(quotient&remainder A B)`

Return the quotient *and* the remainder of A divided by B.

This is especially useful for bignums, since both numbers are derived simultaneously. This saves performing the division algorithm twice.

This name is deprecated in favor of its more "regular" alias from R7RS, `truncate/`.

*[procedure]*

`(quotient&modulo A B)`

Like `quotient&remainder`, except return the modulo instead of remainder.

This procedure has been deprecated.

*[procedure]*

`(floor/ A B)`

*[procedure]*

`(floor-quotient A B)`

*[procedure]*

`(floor-remainder A B)`

*[procedure]*

`(truncate/ A B)`

*[procedure]*

`(truncate-quotient A B)`

*[procedure]*

`(truncate-remainder A B)`

These procedures are from R7RS.

The `floor/` and `truncate/` versions return two values, the quotient and remainder after division. The `-quotient` and `-remainder procedures` simply return only the corresponding value of the "full" computation.

The difference is in how the values are derived for negative values.

If both values are desired, the two-value versions are recommended, as they perform the computation only once.

All the procedures compute a quotient `q` and remainder `r` such that `A = nq + r`. The remainder is determined by the choice for `q`, through the relation `r = A - nq`. The `floor` procedures compute `q = floor(A/B)` and the `truncate` procedures compute `q = truncate(A/B)`.

See Riastradh proposal for Division operators in Scheme for a full explanation of the intricacies of these procedures.

*[procedure]*

`(conj Z)`

Returns the conjugate of the complex number Z.

*[procedure]*

`(bignum? X)`

Is X an extended-precision integer?

*[procedure]*

`(ratnum? X)`

Is X a ratio?

*[procedure]*

`(cplxnum? X)`

Is X a complex?

*[procedure]*

`(rectnum? X)`

Is X an exact-complex? (Treats an integer-floatingpoint as "exact".)

*[procedure]*

`(compnum? X)`

Is X an inexact-complex?

*[procedure]*

`(cflonum? X)`

Is X a floatingpoint-complex or a floatingpoint?

*[procedure]*

`(cintnum? X)`

Is X an integer-complex or an integer?

*[procedure]*

`(integer-length X)`

From SRFI-60; get the number of bits required to represent the integer `X` in 2s complement notation.

## Example

(define(fac n) (if(zero? n) 1 (* n (fac (- n 1))) ) ) (fac 100) ; => 9332621544394415268169923885626670049071596826438162146859296389 5217599993229915608941463976156518286253697920827223758251185210 916864000000000000000000000000

## Compiled code

Starting with version 2.8, extended number literals can be used in compiled code. To make this work, compile your code with:

csc -X numbers-syntax foo.scm

**IMPORTANT**: This only works when the code will be run on exactly the same platform as the Scheme compiler ran on. Cross-compilation and compiling to C and compiling that on the target platform is *not supported*. (You will get an error message when you try to do it anyway)

## Bugs and limitations

- Extended number literals can not be used portably in compiled code (use
`string->number`for maximum portability). - For best results, use Chicken 4.7.4 or later. Extended numbers syntax isn't reliably supported by the reader of earlier Chicken versions (here as well, use
`string->number`for maximum portability).

## About this egg

### Author

The code for complex arithmetic was mostly taken from Thomas Chust's complex egg.

### Maintainer

The CHICKEN Team

### Version history

- 2.9
- Fix a few compiler warnings. R7RS support: Add support for a 2nd "base" argument to the
`log`procedure, export`exact`and`inexact`aliases for`exact->inexact`and`inexact->exact`. Add`floor/`,`floor-quotient`,`floor-remainder`,`truncate/`,`truncate-quotient`and`truncate-remainder`. - 2.8.2
- Add CL-compatible support for complex numbers to
`signum`(#953), and support`numerator`and`denominator`on flonums (as per RnRS) (#1016) [Thanks to John Cowan] - 2.8.1
- Remove long-deprecated and undocumented
`numbers:`-prefixed variants of`+`,`-`, etc. Fix compilation on 4.8.1, which failed due to invalid +inf/-inf literals. Remove`(declare (disable-interrupts))`, which should make numbers play better with threaded code. - 2.8
- Correct handling of exactness prefix (requires recent Chicken to work, at least 4.7.4). Division by inexact zero is no longer considered an error, but returns NaN or +Inf/-Inf.
`inexact->exact`raises an error on NaN instead of returning 0 (reported by Felix Winkelmann). Fix`log`so it doesn't erroneously fail on complex numbers. Generalize`asin`and`acos`so they can return complex numbers. Fix`<=`and`>=`so they work when given a`nan`argument in rest position. Various fixes for code that expected inexact numbers so it calls`exact->inexact`before. Add types database for scrutinizer (Only in Chicken 4.7.4 and later). - 2.7
- Fix several bugs (
`expt`,`integer?`,`rational?`,`<=`,`>=`,`eqv?`,`-`) found by importing the number tests from Gauche and writing an extensive test for number syntax edge cases. Complete rewrite of number parser (it should fully conform to the R7RS superset of R5RS number syntax now). Dropped dependency on the regex egg. Improved precision of`exact->inexact`so it can handle more extreme numbers. Provide the`nan?`,`finite?`and`infinite?`predicates and`integer-length`procedure. - 2.6.1
- Fix
`string->number`so it raises an exception instead of crashing when passed a negative, zero or too large base (reported by Peter Hendrickson). Update test scripts so they exit with nonzero status in case of failed tests (reported by Mario Goulart) - 2.6
- Fix expt and log so they work for numbers which produce complex results.
- 2.5
- Fix expt so it doesn't use flonums and loses precision in case of bignums
- 2.4
- Added regex to dependency list
- 2.3
- Added regex requirement to make it work in Chicken 4.6.2+
- 2.2
- Fixed ratnum normalization in case of negative divisors
- 2.1
- Changed
`quotient`,`remainder`and`quotient&remainder`semantics so they accept fractional flonums to match Chicken's implementation of`quotient`and`remainder`. This also affects`modulo`and`quotient&modulo`. - 2.0
- Removed dependency on GMP, replacing it by the Scheme48 numbers code. Improved performance by integrating with GC. Added benchmarks and more tests. Converted testsuite to use the test egg instead of testeez. [by Peter Bex]
- 1.82
- removed dependency on easyffi (Thanks to Peter Bex)
- 1.81
- fixed dependencies
- 1.809
- Fix for
`(expt <number> <ratio>)`, would fail [Bug noted by John Cowan] - 1.808
- Fix for 1.0+1i not treated as a rectnum or compnum [Bug noted by John Cowan] Added 'cintnum?' & 'cplxnum?' [kon lovett]
- 1.806
- Fix for equal? when given keywords as args [Bug noted by papasi] [elf]
- 1.804
- Using more accurate exact->inexact conversion for rationals [Alex Shinn]
- 1.803
- fixed bug in fixnum bitwise operations [Thanks to Jeremy Sydik]
- 1.802
- not quite complete support for static linking
- 1.801
- Fixed a bug in
`angle`[zb, mario] - 1.8
- Single-argument
`+`and`*`didn't check argument type [Thanks to Stephen Gilardi] - 1.701
- Bugfix for compiler macros, undefined symbol [Kon Lovett]
- 1.7
- Added compiler macros for
`bitwise-...`operations - 1.6
- Compiler macros now work without -X numbers
- 1.5
- Added support for speculative inlining of fixnum ops
- 1.4
- Fixed bug in ratnum/bignum division [Thanks to Ivan Shmakov]
- 1.3
- Fixing round for rational numbers [Alex Shinn]
- 1.2
- Added
`bignum? ratnum? cflonum? rectnum? compnum?`[Kon Lovett] - 1.1
- Uses easyffi properly [reported by John Cowan]
- 1.0
- Fix for fixnum/rational comparison [by Zbigniew]
- 0.999
`rational?`always returned false for flonums- 0.998
- Added some missing definitions to numbers.scm [found by Kon Lovett]
- 0.997
- Fixed memory leak in some bitwise operations [found by Dan Muresan]
- 0.996
- Fixed a bug in
`expt`[Daishi Kato] - 0.995
`round`rounds to even (as specified by R5RS) [Thanks to Benedikt Rosenau]- 0.994
- Reimplemented
`=`in C - 0.993
- Fixed
`equal?`which didn't handle extended numbers nested in other data - 0.992
- Slight performance tuning for
`expt`[Again by Daishi] - 0.991
- Fixed bug in fixnum/bignum subtraction [Thanks to Daishi Kato and Alex Shinn]
- 0.99
- Speed improvements for
`expt`by Daishi Kato - 0.98
- Added
`random`and`randomize`[Suggested by Daishi Kato] - 0.97
- bignum/fixnum subtraction used wrong argument order [Thanks to Kon Lovett]
- 0.96
- Several bug fixes by Alex Shinn;
`signum`is exactness preserving - 0.95
- Alex Shinn contributed a working version of
`expt` - 0.94
- Yet another bug-fix by Michal
- 0.93
- Several bug-fixes by Michal Janeczek
- 0.92
- exactness handling of
`expt`is slightly better but still not perfect. - 0.91
- Fixed bug in
`integer?` - 0.9
- (beta)

### License

Copyright (c) 2008-2013 The CHICKEN Team Copyright (c) 2000-2007, Felix L. Winkelmann Copyright (c) 1993-2008 Richard Kelsey and Jonathan Rees Copyright 1986,1987,1988,1989,1990,1991 Massachusetts Institute of Technology Copyright 1992,1993,1994,2004 Massachusetts Institute of Technology All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. The name of the authors may not be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.