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;;; "bytenumb.scm" Byte integer and IEEE floating-point conversions.
; Copyright (C) 2003 Aubrey Jaffer
;
;Permission to copy this software, to modify it, to redistribute it,
;to distribute modified versions, and to use it for any purpose is
;granted, subject to the following restrictions and understandings.
;
;1. Any copy made of this software must include this copyright notice
;in full.
;
;2. I have made no warranty or representation that the operation of
;this software will be error-free, and I am under no obligation to
;provide any services, by way of maintenance, update, or otherwise.
;
;3. In conjunction with products arising from the use of this
;material, there shall be no use of my name in any advertising,
;promotional, or sales literature without prior written consent in
;each case.
(require 'byte)
(require 'logical)
;;@code{(require 'byte-number)}
;;@ftindex byte-number
;;@noindent
;;The multi-byte sequences produced and used by numeric conversion
;;routines are always big-endian. Endianness can be changed during
;;reading and writing bytes using @code{read-bytes} and
;;@code{write-bytes} @xref{Byte, read-bytes}.
;;
;;@noindent
;;The sign of the length argument to bytes/integer conversion
;;procedures determines the signedness of the number.
;;@body
;;Converts the first @code{(abs @var{n})} bytes of big-endian @1 array
;;to an integer. If @2 is negative then the integer coded by the
;;bytes are treated as two's-complement (can be negative).
;;
;;@example
;;(bytes->integer (bytes 0 0 0 15) -4) @result{} 15
;;(bytes->integer (bytes 0 0 0 15) 4) @result{} 15
;;(bytes->integer (bytes 255 255 255 255) -4) @result{} -1
;;(bytes->integer (bytes 255 255 255 255) 4) @result{} 4294967295
;;(bytes->integer (bytes 128 0 0 0) -4) @result{} -2147483648
;;(bytes->integer (bytes 128 0 0 0) 4) @result{} 2147483648
;;@end example
(define (bytes->integer bytes n)
(define cnt (abs n))
(cond ((zero? n) 0)
((and (negative? n) (> (byte-ref bytes 0) 127))
(do ((lng (- 255 (byte-ref bytes 0))
(+ (- 255 (byte-ref bytes idx)) (* 256 lng)))
(idx 1 (+ 1 idx)))
((>= idx cnt) (- -1 lng))))
(else
(do ((lng (byte-ref bytes 0)
(+ (byte-ref bytes idx) (* 256 lng)))
(idx 1 (+ 1 idx)))
((>= idx cnt) lng)))))
;;@body
;;Converts the integer @1 to a byte-array of @code{(abs @var{n})}
;;bytes. If @1 and @2 are both negative, then the bytes in the
;;returned array are coded two's-complement.
;;
;;@example
;;(bytes->list (integer->bytes 15 -4)) @result{} (0 0 0 15)
;;(bytes->list (integer->bytes 15 4)) @result{} (0 0 0 15)
;;(bytes->list (integer->bytes -1 -4)) @result{} (255 255 255 255)
;;(bytes->list (integer->bytes 4294967295 4)) @result{} (255 255 255 255)
;;(bytes->list (integer->bytes -2147483648 -4)) @result{} (128 0 0 0)
;;(bytes->list (integer->bytes 2147483648 4)) @result{} (128 0 0 0)
;;@end example
(define (integer->bytes n len)
(define bytes (make-bytes (abs len)))
(cond ((and (negative? n) (negative? len))
(do ((idx (+ -1 (abs len)) (+ -1 idx))
(res (- -1 n) (quotient res 256)))
((negative? idx) bytes)
(byte-set! bytes idx (- 255 (modulo res 256)))))
(else
(do ((idx (+ -1 (abs len)) (+ -1 idx))
(res n (quotient res 256)))
((negative? idx) bytes)
(byte-set! bytes idx (modulo res 256))))))
;;@body
;;@1 must be a 4-element byte-array. @0 calculates and returns the
;;value of @1 interpreted as a big-endian IEEE 4-byte (32-bit) number.
(define (bytes->ieee-float bytes)
(define zero (or (string->number "0.0") 0))
(define one (or (string->number "1.0") 1))
(define len (bytes-length bytes))
(define S (logbit? 7 (byte-ref bytes 0)))
(define E (+ (ash (logand #x7F (byte-ref bytes 0)) 1)
(ash (logand #x80 (byte-ref bytes 1)) -7)))
(if (not (eqv? 4 len))
(slib:error 'bytes->ieee-float 'wrong 'length len))
(do ((F (byte-ref bytes (+ -1 len))
(+ (byte-ref bytes idx) (/ F 256)))
(idx (+ -2 len) (+ -1 idx)))
((<= idx 1)
(set! F (/ (+ (logand #x7F (byte-ref bytes 1)) (/ F 256)) 128))
(cond ((< 0 E 255) (* (if S (- one) one) (expt 2 (- E 127)) (+ 1 F)))
((zero? E)
(if (zero? F)
(if S (- zero) zero)
(* (if S (- one) one) (expt 2 -126) F)))
;; E must be 255
((not (zero? F)) (/ zero zero))
(else (/ (if S (- one) one) zero))))))
;; S EEEEEEE E FFFFFFF FFFFFFFF FFFFFFFF
;; ========= ========= ======== ========
;; 0 1 8 9 31
;;@example
;;(bytes->ieee-float (bytes 0 0 0 0)) @result{} 0.0
;;(bytes->ieee-float (bytes #x80 0 0 0)) @result{} -0.0
;;(bytes->ieee-float (bytes #x40 0 0 0)) @result{} 2.0
;;(bytes->ieee-float (bytes #x40 #xd0 0 0)) @result{} 6.5
;;(bytes->ieee-float (bytes #xc0 #xd0 0 0)) @result{} -6.5
;;
;;(bytes->ieee-float (bytes 0 #x80 0 0)) @result{} 11.754943508222875e-39
;;(bytes->ieee-float (bytes 0 #x40 0 0)) @result{} 5.877471754111437e-39
;;(bytes->ieee-float (bytes 0 0 0 1)) @result{} 1.401298464324817e-45
;;
;;(bytes->ieee-float (bytes #xff #x80 0 0)) @result{} -inf.0
;;(bytes->ieee-float (bytes #x7f #x80 0 0)) @result{} +inf.0
;;(bytes->ieee-float (bytes #x7f #x80 0 1)) @result{} 0/0
;;@end example
;;@body
;;@1 must be a 8-element byte-array. @0 calculates and returns the
;;value of @1 interpreted as a big-endian IEEE 8-byte (64-bit) number.
(define (bytes->ieee-double bytes)
(define zero (or (string->number "0.0") 0))
(define one (or (string->number "1.0") 1))
(define len (bytes-length bytes))
(define S (logbit? 7 (byte-ref bytes 0)))
(define E (+ (ash (logand #x7F (byte-ref bytes 0)) 4)
(ash (logand #xF0 (byte-ref bytes 1)) -4)))
(if (not (eqv? 8 len))
(slib:error 'bytes->ieee-double 'wrong 'length len))
(do ((F (byte-ref bytes (+ -1 len))
(+ (byte-ref bytes idx) (/ F 256)))
(idx (+ -2 len) (+ -1 idx)))
((<= idx 1)
(set! F (/ (+ (logand #x0F (byte-ref bytes 1)) (/ F 256)) 16))
(cond ((< 0 E 2047) (* (if S (- one) one) (expt 2 (- E 1023)) (+ 1 F)))
((zero? E)
(if (zero? F)
(if S (- zero) zero)
(* (if S (- one) one) (expt 2 -1022) F)))
;; E must be 2047
((not (zero? F)) (/ zero zero))
(else (/ (if S (- one) one) zero))))))
;; S EEEEEEE EEEE FFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF
;; ========= ========= ======== ======== ======== ======== ======== ========
;; 0 1 11 12 63
;;@example
;;(bytes->ieee-double (bytes 0 0 0 0 0 0 0 0)) @result{} 0.0
;;(bytes->ieee-double (bytes #x80 0 0 0 0 0 0 0)) @result{} -0.0
;;(bytes->ieee-double (bytes #x40 0 0 0 0 0 0 0)) @result{} 2.0
;;(bytes->ieee-double (bytes #x40 #x1A 0 0 0 0 0 0)) @result{} 6.5
;;(bytes->ieee-double (bytes #xC0 #x1A 0 0 0 0 0 0)) @result{} -6.5
;;
;;(bytes->ieee-double (bytes 0 8 0 0 0 0 0 0)) @result{} 11.125369292536006e-309
;;(bytes->ieee-double (bytes 0 4 0 0 0 0 0 0)) @result{} 5.562684646268003e-309
;;(bytes->ieee-double (bytes 0 0 0 0 0 0 0 1)) @result{} 4.0e-324
;;
;;(bytes->ieee-double (bytes #xFF #xF0 0 0 0 0 0 0)) @result{} -inf.0
;;(bytes->ieee-double (bytes #x7F #xF0 0 0 0 0 0 0)) @result{} +inf.0
;;(bytes->ieee-double (bytes #x7F #xF8 0 0 0 0 0 0)) @result{} 0/0
;;@end example
;;@args x
;;Returns a 4-element byte-array encoding the IEEE single-precision
;;floating-point of @1.
(define ieee-float->bytes
(let ((zero (or (string->number "0.0") 0))
(exactify (if (provided? 'inexact) inexact->exact identity)))
(lambda (flt)
(define byts (make-bytes 4 0))
(define S (and (real? flt) (negative? (if (zero? flt) (/ flt) flt))))
(define (scale flt scl)
(cond ((zero? scl) (out (/ flt 2) scl))
((zero? flt) (if S (byte-set! byts 0 #x80)) byts)
((or (not (real? flt)) (>= flt 16))
(let ((flt/16 (/ flt 16)))
(cond ((= flt/16 flt)
(byte-set! byts 0 (if S #xFF #x7F))
(byte-set! byts 1 (if (= flt (* zero flt)) #xC0 #x80))
byts)
(else (scale flt/16 (+ scl 4))))))
((>= flt 2) (scale (/ flt 2) (+ scl 1)))
((and (>= scl 4)
(< (* 16 flt) 1)) (scale (* flt 16) (+ scl -4)))
((< flt 1) (scale (* flt 2) (+ scl -1)))
(else (out (+ -1 flt) scl))))
(define (out flt scl)
(do ((flt (* 128 flt) (* 256 (- flt val)))
(val (exactify (floor (* 128 flt)))
(exactify (floor (* 256 (- flt val)))))
(idx 1 (+ 1 idx)))
((> idx 3)
(byte-set! byts 1 (bitwise-if #x80 (ash scl 7) (byte-ref byts 1)))
(byte-set! byts 0 (+ (if S 128 0) (ash scl -1)))
byts)
(byte-set! byts idx val)))
(scale (abs flt) 127))))
;;@example
;;(bytes->list (ieee-float->bytes 0.0)) @result{} (0 0 0 0)
;;(bytes->list (ieee-float->bytes -0.0)) @result{} (128 0 0 0)
;;(bytes->list (ieee-float->bytes 2.0)) @result{} (64 0 0 0)
;;(bytes->list (ieee-float->bytes 6.5)) @result{} (64 208 0 0)
;;(bytes->list (ieee-float->bytes -6.5)) @result{} (192 208 0 0)
;;
;;(bytes->list (ieee-float->bytes 11.754943508222875e-39)) @result{} ( 0 128 0 0)
;;(bytes->list (ieee-float->bytes 5.877471754111438e-39)) @result{} ( 0 64 0 0)
;;(bytes->list (ieee-float->bytes 1.401298464324817e-45)) @result{} ( 0 0 0 1)
;;
;;(bytes->list (ieee-float->bytes -inf.0)) @result{} (255 128 0 0)
;;(bytes->list (ieee-float->bytes +inf.0)) @result{} (127 128 0 0)
;;(bytes->list (ieee-float->bytes 0/0)) @result{} (127 128 0 1)
;;@end example
;;@args x
;;Returns a 8-element byte-array encoding the IEEE double-precision
;;floating-point of @1.
(define ieee-double->bytes
(let ((zero (or (string->number "0.0") 0))
(exactify (if (provided? 'inexact) inexact->exact identity)))
(lambda (flt)
(define byts (make-bytes 8 0))
(define S (and (real? flt) (negative? (if (zero? flt) (/ flt) flt))))
(define (scale flt scl)
(cond ((zero? scl) (out (/ flt 2) scl))
((zero? flt) (if S (byte-set! byts 0 #x80)) byts)
((or (not (real? flt)) (>= flt 16))
(let ((flt/16 (/ flt 16)))
(cond ((= flt/16 flt)
(byte-set! byts 0 (if S #xFF #x7F))
(byte-set! byts 1 (if (= flt (* zero flt)) #xF8 #xF0))
byts)
(else (scale flt/16 (+ scl 4))))))
((>= flt 2) (scale (/ flt 2) (+ scl 1)))
((and (>= scl 4)
(< (* 16 flt) 1)) (scale (* flt 16) (+ scl -4)))
((< flt 1) (scale (* flt 2) (+ scl -1)))
(else (out (+ -1 flt) scl))))
(define (out flt scl)
(do ((flt (* 16 flt) (* 256 (- flt val)))
(val (exactify (floor (* 16 flt)))
(exactify (floor (* 256 (- flt val)))))
(idx 1 (+ 1 idx)))
((> idx 7)
(byte-set! byts 1 (bitwise-if #xF0 (ash scl 4) (byte-ref byts 1)))
(byte-set! byts 0 (+ (if S 128 0) (ash scl -4)))
byts)
(byte-set! byts idx val)))
(scale (abs flt) 1023))))
;;@example
;;(bytes->list (ieee-double->bytes 0.0)) @result{} (0 0 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes -0.0)) @result{} (128 0 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes 2.0)) @result{} (64 0 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes 6.5)) @result{} (64 26 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes -6.5)) @result{} (192 26 0 0 0 0 0 0)
;;
;;(bytes->list (ieee-double->bytes 11.125369292536006e-309))
;; @result{} ( 0 8 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes 5.562684646268003e-309))
;; @result{} ( 0 4 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes 4.0e-324))
;; @result{} ( 0 0 0 0 0 0 0 1)
;;
;;(bytes->list (ieee-double->bytes -inf.0)) @result{} (255 240 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes +inf.0)) @result{} (127 240 0 0 0 0 0 0)
;;(bytes->list (ieee-double->bytes 0/0)) @result{} (127 248 0 0 0 0 0 0)
;;@end example
;;@subsubheading Byte Collation Order
;;
;;@noindent
;;The @code{string<?} ordering of big-endian byte-array
;;representations of fixed and IEEE floating-point numbers agrees with
;;the numerical ordering only when those numbers are non-negative.
;;
;;@noindent
;;Straighforward modification of these formats can extend the
;;byte-collating order to work for their entire ranges. This
;;agreement enables the full range of numbers as keys in
;;@dfn{indexed-sequential-access-method} databases.
;;@body
;;Modifies sign bit of @1 so that @code{string<?} ordering of
;;two's-complement byte-vectors matches numerical order. @0 returns
;;@1 and is its own functional inverse.
(define (integer-byte-collate! byte-vector)
(byte-set! byte-vector 0 (logxor #x80 (byte-ref byte-vector 0)))
byte-vector)
;;@body
;;Returns copy of @1 with sign bit modified so that @code{string<?}
;;ordering of two's-complement byte-vectors matches numerical order.
;;@0 is its own functional inverse.
(define (integer-byte-collate byte-vector)
(integer-byte-collate! (bytes-copy byte-vector)))
;;@body
;;Modifies @1 so that @code{string<?} ordering of IEEE floating-point
;;byte-vectors matches numerical order. @0 returns @1.
(define (IEEE-byte-collate! byte-vector)
(cond ((logtest #x80 (byte-ref byte-vector 0))
(do ((idx (+ -1 (bytes-length byte-vector)) (+ -1 idx)))
((negative? idx))
(byte-set! byte-vector idx
(logxor #xFF (byte-ref byte-vector idx)))))
(else
(byte-set! byte-vector 0 (logxor #x80 (byte-ref byte-vector 0)))))
byte-vector)
;;@body
;;Given @1 modified by @code{IEEE-byte-collate!}, reverses the @1
;;modifications.
(define (IEEE-byte-decollate! byte-vector)
(cond ((not (logtest #x80 (byte-ref byte-vector 0)))
(do ((idx (+ -1 (bytes-length byte-vector)) (+ -1 idx)))
((negative? idx))
(byte-set! byte-vector idx
(logxor #xFF (byte-ref byte-vector idx)))))
(else
(byte-set! byte-vector 0 (logxor #x80 (byte-ref byte-vector 0)))))
byte-vector)
;;@body
;;Returns copy of @1 encoded so that @code{string<?} ordering of IEEE
;;floating-point byte-vectors matches numerical order.
(define (IEEE-byte-collate byte-vector)
(IEEE-byte-collate! (bytes-copy byte-vector)))
;;@body
;;Given @1 returned by @code{IEEE-byte-collate}, reverses the @1
;;modifications.
(define (IEEE-byte-decollate byte-vector)
(IEEE-byte-decollate! (bytes-copy byte-vector)))
|