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ikarus/src/ikarus.numerics.ss

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(library (ikarus flonums)
(export $flonum->exact $flonum-signed-biased-exponent flonum-parts
inexact->exact exact $flonum-rational? $flonum-integer? $flzero?
$flnegative? flpositive? flabs fixnum->flonum
flsin flcos fltan flasin flacos flatan fleven? flodd?
flfloor flceiling flnumerator fldenominator flexp fllog
flinteger? flonum-bytes flnan? flfinite? flinfinite?
flexpt)
(import
(ikarus system $bytevectors)
(ikarus system $fx)
(only (ikarus system $flonums) $fl>=)
(ikarus system $bignums)
(except (ikarus system $flonums) $flonum-signed-biased-exponent
$flonum-rational? $flonum-integer?)
(except (ikarus) inexact->exact exact flpositive? flabs fixnum->flonum
flsin flcos fltan flasin flacos flatan fleven? flodd?
flfloor flceiling flnumerator fldenominator flexp fllog
flexpt flinteger? flonum-parts flonum-bytes flnan? flfinite?
flinfinite?))
(define (flonum-bytes f)
(unless (flonum? f)
(error 'flonum-bytes "~s is not a flonum" f))
(values
($flonum-u8-ref f 0)
($flonum-u8-ref f 1)
($flonum-u8-ref f 2)
($flonum-u8-ref f 3)
($flonum-u8-ref f 4)
($flonum-u8-ref f 5)
($flonum-u8-ref f 6)
($flonum-u8-ref f 7)))
(define (flonum-parts x)
(unless (flonum? x)
(error 'flonum-parts "~s is not a flonum" x))
(let-values ([(b0 b1 b2 b3 b4 b5 b6 b7) (flonum-bytes x)])
(values
(zero? (fxlogand b0 128))
(+ (fxsll (fxlogand b0 127) 4)
(fxsra b1 4))
(+ (+ b7 (fxsll b6 8) (fxsll b5 16))
(* (+ b4
(fxsll b3 8)
(fxsll b2 16)
(fxsll (fxlogand b1 #b1111) 24))
(expt 2 24))))))
(define ($zero-m? f)
(and ($fxzero? ($flonum-u8-ref f 7))
($fxzero? ($flonum-u8-ref f 6))
($fxzero? ($flonum-u8-ref f 5))
($fxzero? ($flonum-u8-ref f 4))
($fxzero? ($flonum-u8-ref f 3))
($fxzero? ($flonum-u8-ref f 2))
($fxzero? ($fxlogand ($flonum-u8-ref f 1) #b1111))))
(define ($flonum-signed-biased-exponent x)
(let ([b0 ($flonum-u8-ref x 0)]
[b1 ($flonum-u8-ref x 1)])
(fxlogor (fxsll b0 4) (fxsra b1 4))))
(define ($flonum-rational? x)
(let ([be (fxlogand ($flonum-signed-biased-exponent x) (sub1 (fxsll 1 11)))])
(fx< be 2047)))
(define ($flonum-integer? x)
(let ([be (fxlogand ($flonum-signed-biased-exponent x) (sub1 (fxsll 1 11)))])
(cond
[(fx= be 2047) ;;; nans and infs
#f]
[(fx>= be 1075) ;;; magnitue large enough
#t]
[(fx= be 0) ;;; denormalized double, only +/-0.0 is integer
(and (fx= ($flonum-u8-ref x 7) 0)
(fx= ($flonum-u8-ref x 6) 0)
(fx= ($flonum-u8-ref x 5) 0)
(fx= ($flonum-u8-ref x 4) 0)
(fx= ($flonum-u8-ref x 3) 0)
(fx= ($flonum-u8-ref x 2) 0)
(fx= ($flonum-u8-ref x 1) 0))]
[(fx< be (fx+ 1075 -52)) ;;; too small to be an integer
#f]
[else
(let ([v ($flonum->exact x)])
(or (fixnum? v) (bignum? v)))])))
(define (flnumerator x)
(unless (flonum? x)
(error 'flnumerator "~s is not a flonum" x))
(cond
[($flonum-integer? x) x]
[($flonum-rational? x)
(exact->inexact (numerator ($flonum->exact x)))]
[else x]))
(define (fldenominator x)
(unless (flonum? x)
(error 'fldenominator "~s is not a flonum" x))
(cond
[($flonum-integer? x) 1.0]
[($flonum-rational? x)
(exact->inexact (denominator ($flonum->exact x)))]
[(flnan? x) x]
[else 1.0]))
(define (fleven? x)
(unless (flonum? x)
(error 'fleven? "~s is not a flonum" x))
(let ([v ($flonum->exact x)])
(cond
[(fixnum? v) ($fx= ($fxlogand v 1) 0)]
[(bignum? v)
(foreign-call "ikrt_even_bn" v)]
[else (error 'fleven? "~s is not an integer flonum" x)])))
(define (flodd? x)
(unless (flonum? x)
(error 'flodd? "~s is not a flonum" x))
(let ([v ($flonum->exact x)])
(cond
[(fixnum? v) ($fx= ($fxlogand v 1) 1)]
[(bignum? v)
(not (foreign-call "ikrt_even_bn" v))]
[else (error 'flodd? "~s is not an integer flonum" x)])))
(define (flinteger? x)
(if (flonum? x)
($flonum-integer? x)
(error 'flinteger? "~s is not a flonum" x)))
(define (flinfinite? x)
(if (flonum? x)
(let ([be (fxlogand ($flonum-signed-biased-exponent x) (sub1 (fxsll 1 11)))])
(and (fx= be 2047) ;;; nans and infs
($zero-m? x)))
(error 'flinfinite? "~s is not a flonum" x)))
(define (flnan? x)
(if (flonum? x)
(let ([be (fxlogand ($flonum-signed-biased-exponent x) (sub1 (fxsll 1 11)))])
(and (fx= be 2047) ;;; nans and infs
(not ($zero-m? x))))
(error 'flnan? "~s is not a flonum" x)))
(define (flfinite? x)
(if (flonum? x)
(let ([be (fxlogand ($flonum-signed-biased-exponent x) (sub1 (fxsll 1 11)))])
(not (fx= be 2047)))
(error 'flfinite? "~s is not a flonum" x)))
(define ($flzero? x)
(let ([be (fxlogand ($flonum-signed-biased-exponent x) (sub1 (fxsll 1 11)))])
(and
(fx= be 0) ;;; denormalized double, only +/-0.0 is integer
(and (fx= ($flonum-u8-ref x 7) 0)
(fx= ($flonum-u8-ref x 6) 0)
(fx= ($flonum-u8-ref x 5) 0)
(fx= ($flonum-u8-ref x 4) 0)
(fx= ($flonum-u8-ref x 3) 0)
(fx= ($flonum-u8-ref x 2) 0)
(fx= ($flonum-u8-ref x 1) 0)))))
(define ($flnegative? x)
(let ([b0 ($flonum-u8-ref x 0)])
(fx> b0 127)))
(define ($flonum->exact x)
(let-values ([(pos? be m) (flonum-parts x)])
(cond
[(<= 1 be 2046) ; normalized flonum
(* (if pos? 1 -1)
(* (+ m (expt 2 52)) (expt 2 (- be 1075))))]
[(= be 0)
(* (if pos? 1 -1)
(* m (expt 2 -1074)))]
[else #f])))
(define (inexact->exact x)
(cond
[(flonum? x)
(or ($flonum->exact x)
(error 'inexact->exact "~s has no real value" x))]
[(or (fixnum? x) (ratnum? x) (bignum? x)) x]
[else
(error 'inexact->exact "~s is not an inexact number" x)]))
(define (exact x)
(cond
[(flonum? x)
(or ($flonum->exact x)
(error 'exact "~s has no real value" x))]
[(or (fixnum? x) (ratnum? x) (bignum? x)) x]
[else
(error 'exact "~s is not an inexact number" x)]))
(define (flpositive? x)
(if (flonum? x)
($fl> x 0.0)
(error 'flpositive? "~s is not a flonum" x)))
(define (flabs x)
(if (flonum? x)
(if ($fl> x 0.0)
($fl* x -1.0)
x)
(error 'flabs "~s is not a flonum" x)))
(define (fixnum->flonum x)
(if (fixnum? x)
($fixnum->flonum x)
(error 'fixnum->flonum "~s is not a fixnum")))
(define (flsin x)
(if (flonum? x)
(foreign-call "ikrt_fl_sin" x)
(error 'flsin "~s is not a flonum" x)))
(define (flcos x)
(if (flonum? x)
(foreign-call "ikrt_fl_cos" x)
(error 'flcos "~s is not a flonum" x)))
(define (fltan x)
(if (flonum? x)
(foreign-call "ikrt_fl_tan" x)
(error 'fltan "~s is not a flonum" x)))
(define (flasin x)
(if (flonum? x)
(foreign-call "ikrt_fl_asin" x)
(error 'flasin "~s is not a flonum" x)))
(define (flacos x)
(if (flonum? x)
(foreign-call "ikrt_fl_acos" x)
(error 'flacos "~s is not a flonum" x)))
(define (flatan x)
(if (flonum? x)
(foreign-call "ikrt_fl_atan" x)
(error 'flatan "~s is not a flonum" x)))
(define (flfloor x)
(define (ratnum-floor x)
(let ([n (numerator x)] [d (denominator x)])
(let ([q (quotient n d)])
(if (>= n 0) q (- q 1)))))
(cond
[(flonum? x)
(let ([e ($flonum->exact x)])
(cond
[(ratnum? e)
(exact->inexact (ratnum-floor e))]
[else x]))]
[else (error 'flfloor "~s is not a flonum" x)]))
(define (flceiling x)
(cond
[(flonum? x)
(let ([e ($flonum->exact x)])
(cond
[(ratnum? e)
(exact->inexact (ceiling e))]
[else x]))]
[else (error 'flceiling "~s is not a flonum" x)]))
(define (flexp x)
(if (flonum? x)
(foreign-call "ikrt_fl_exp" x ($make-flonum))
(error 'flexp "~s is not a flonum" x)))
(define (fllog x)
(if (flonum? x)
(if ($fl>= x 0.0)
(foreign-call "ikrt_fl_log" x)
(error 'fllog "argument ~s should not be negative" x))
(error 'fllog "~s is not a flonum" x)))
(define (flexpt x y)
(if (flonum? x)
(if (flonum? y)
(let ([y^ ($flonum->exact y)])
(cond
[(fixnum? y^) (inexact (expt x y^))]
[(bignum? y^) (inexact (expt x y^))]
[else
(foreign-call "ikrt_flfl_expt" x y ($make-flonum))]))
(error 'flexpt "~s is not a flonum" y))
(error 'fllog "~s is not a flonum" x)))
)
(library (ikarus generic-arithmetic)
(export + - * / zero? = < <= > >= add1 sub1 quotient remainder
modulo even? odd? logand $two-bignums
positive? negative? expt gcd lcm numerator denominator exact-integer-sqrt
quotient+remainder number->string string->number min max
abs truncate fltruncate sra sll
exact->inexact inexact floor ceiling round log fl=? fl<? fl<=? fl>?
fl>=? fl+ fl- fl* fl/ flsqrt flmin flzero? flnegative?
sin cos tan asin acos atan sqrt
flround flmax random)
(import
(ikarus system $fx)
(ikarus system $flonums)
(ikarus system $ratnums)
(ikarus system $bignums)
(ikarus system $chars)
(ikarus system $strings)
(only (ikarus flonums) $flonum->exact $flzero? $flnegative?)
(except (ikarus) + - * / zero? = < <= > >= add1 sub1 quotient
remainder modulo even? odd? quotient+remainder number->string
positive? negative? logand $two-bignums
string->number expt gcd lcm numerator denominator
exact->inexact inexact floor ceiling round log
exact-integer-sqrt min max abs
fl=? fl<? fl<=? fl>? fl>=? fl+ fl- fl* fl/ flsqrt flmin
flzero? flnegative? sra sll
sin cos tan asin acos atan sqrt truncate fltruncate
flround flmax random))
(define ($two-bignums)
(list 1234567890 -1234567890
12345678901234567890
-12345678901234567890
1234567890123456789012345678901234567890
-1234567890123456789012345678901234567890))
; (foreign-call "ikrt_fixnum_to_flonum" x))
(module (bignum->flonum)
; sbe f6 f5 f4 f3 f2 f1 f0
;SEEEEEEE|EEEEmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm|mmmmmmmm
; | | | | | | |
; v0 v1 v2 v3 v4 v5 v6 v7
(define ($flonum pos? e f6 f5 f4 f3 f2 f1 f0)
(let ([be (fx+ e 1075)])
(let ([v ($make-flonum)])
(cond
[(fx< be 2047)
(let ([sbe (if pos? be (fxlogor be (fxsll 1 11)))])
($flonum-set! v 0 (fxsra sbe 4))
($flonum-set! v 1 (fxlogor (fxsll sbe 4) (fxlogand f6 #b1111)))
($flonum-set! v 2 f5)
($flonum-set! v 3 f4)
($flonum-set! v 4 f3)
($flonum-set! v 5 f2)
($flonum-set! v 6 f1)
($flonum-set! v 7 f0))]
[else ;;; inf
(let ([sbe (if pos? 2047 (fxlogor 2047 (fxsll 1 11)))])
($flonum-set! v 0 (fxsra sbe 4))
($flonum-set! v 1 (fxsll sbe 4))
($flonum-set! v 2 0)
($flonum-set! v 3 0)
($flonum-set! v 4 0)
($flonum-set! v 5 0)
($flonum-set! v 6 0)
($flonum-set! v 7 0))])
v)))
(define ($flonum/c0 pos? e f6 f5 f4 f3 f2 f1 f0 c)
(define ($fxeven? x)
(fxzero? (fxlogand x 1)))
(define-syntax cond*
(syntax-rules (else)
[(_ [test conseq] [else val])
(if test conseq val)]
[(_ [test conseq] [var val] rest ...)
(if test conseq (let ([var val]) (cond* rest ...)))]))
(cond*
[($fxeven? c) ($flonum pos? e f6 f5 f4 f3 f2 f1 f0)]
[f0 (fx+ (fxlogand f0 255) 1)]
[(fx< f0 256) ($flonum pos? e f6 f5 f4 f3 f2 f1 f0)]
[f1 (fx+ (fxlogand f1 255) 1)]
[(fx< f1 256) ($flonum pos? e f6 f5 f4 f3 f2 f1 0)]
[f2 (fx+ (fxlogand f2 255) 1)]
[(fx< f2 256) ($flonum pos? e f6 f5 f4 f3 f2 0 0)]
[f3 (fx+ (fxlogand f3 255) 1)]
[(fx< f3 256) ($flonum pos? e f6 f5 f4 f3 0 0 0)]
[f4 (fx+ (fxlogand f4 255) 1)]
[(fx< f4 256) ($flonum pos? e f6 f5 f4 0 0 0 0)]
[f5 (fx+ (fxlogand f5 255) 1)]
[(fx< f5 256) ($flonum pos? e f6 f5 0 0 0 0 0)]
[f6 (fx+ (fxlogand f6 #b1111) 1)]
[(fx< f6 16) ($flonum pos? e f6 0 0 0 0 0 0)]
[else ($flonum pos? (+ e 1) 0 0 0 0 0 0 0)]))
(define ($flonum/aux pos? e b7 b6 b5 b4 b3 b2 b1 b0)
(cond
[(fx>= b7 #x80)
($flonum/c0 pos? (fx+ e 3)
(fxsra b7 3)
(fxlogor (fxsll b7 5) (fxsra b6 3))
(fxlogor (fxsll b6 5) (fxsra b5 3))
(fxlogor (fxsll b5 5) (fxsra b4 3))
(fxlogor (fxsll b4 5) (fxsra b3 3))
(fxlogor (fxsll b3 5) (fxsra b2 3))
(fxlogor (fxsll b2 5) (fxsra b1 3))
(fxsra b1 2))]
[(fx>= b7 #x40)
($flonum/c0 pos? (fx+ e 2)
(fxsra b7 2)
(fxlogor (fxsll b7 6) (fxsra b6 2))
(fxlogor (fxsll b6 6) (fxsra b5 2))
(fxlogor (fxsll b5 6) (fxsra b4 2))
(fxlogor (fxsll b4 6) (fxsra b3 2))
(fxlogor (fxsll b3 6) (fxsra b2 2))
(fxlogor (fxsll b2 6) (fxsra b1 2))
(fxsra b1 1))]
[(fx>= b7 #x20)
($flonum/c0 pos? (fx+ e 1)
(fxsra b7 1)
(fxlogor (fxsll b7 7) (fxsra b6 1))
(fxlogor (fxsll b6 7) (fxsra b5 1))
(fxlogor (fxsll b5 7) (fxsra b4 1))
(fxlogor (fxsll b4 7) (fxsra b3 1))
(fxlogor (fxsll b3 7) (fxsra b2 1))
(fxlogor (fxsll b2 7) (fxsra b1 1))
b1)]
[(fx>= b7 #x10)
($flonum/c0 pos? e b7 b6 b5 b4 b3 b2 b1
(fxsra b0 7))]
[(fx>= b7 #x08)
($flonum/c0 pos? (fx- e 1)
(fxlogor (fxsll b7 1) (fxsra b6 7))
(fxlogor (fxsll b6 1) (fxsra b5 7))
(fxlogor (fxsll b5 1) (fxsra b4 7))
(fxlogor (fxsll b4 1) (fxsra b3 7))
(fxlogor (fxsll b3 1) (fxsra b2 7))
(fxlogor (fxsll b2 1) (fxsra b1 7))
(fxlogor (fxsll b1 1) (fxsra b0 7))
(fxsra b0 6))]
[(fx>= b7 #x04)
($flonum/c0 pos? (fx- e 2)
(fxlogor (fxsll b7 2) (fxsra b6 6))
(fxlogor (fxsll b6 2) (fxsra b5 6))
(fxlogor (fxsll b5 2) (fxsra b4 6))
(fxlogor (fxsll b4 2) (fxsra b3 6))
(fxlogor (fxsll b3 2) (fxsra b2 6))
(fxlogor (fxsll b2 2) (fxsra b1 6))
(fxlogor (fxsll b1 2) (fxsra b0 6))
(fxsra b0 5))]
[(fx>= b7 #x02)
($flonum/c0 pos? (fx- e 3)
(fxlogor (fxsll b7 3) (fxsra b6 5))
(fxlogor (fxsll b6 3) (fxsra b5 5))
(fxlogor (fxsll b5 3) (fxsra b4 5))
(fxlogor (fxsll b4 3) (fxsra b3 5))
(fxlogor (fxsll b3 3) (fxsra b2 5))
(fxlogor (fxsll b2 3) (fxsra b1 5))
(fxlogor (fxsll b1 3) (fxsra b0 5))
(fxsra b0 4))]
[(fx>= b7 #x01)
($flonum/c0 pos? (fx- e 4)
(fxlogor (fxsll b7 4) (fxsra b6 4))
(fxlogor (fxsll b6 4) (fxsra b5 4))
(fxlogor (fxsll b5 4) (fxsra b4 4))
(fxlogor (fxsll b4 4) (fxsra b3 4))
(fxlogor (fxsll b3 4) (fxsra b2 4))
(fxlogor (fxsll b2 4) (fxsra b1 4))
(fxlogor (fxsll b1 4) (fxsra b0 4))
(fxsra b0 3))]
[else (error '$float/aux "invalid b7=~s" b7)]))
(define (bignum->flonum x)
(define (bignum/4->flonum x)
($flonum/aux ($bignum-positive? x) -24
($bignum-byte-ref x 3)
($bignum-byte-ref x 2)
($bignum-byte-ref x 1)
($bignum-byte-ref x 0)
0 0 0 0))
(define (bignum/8->flonum x)
;;; bignum: [b0 b1 b2 b3 b4 b5 b6 b7]
(let ([b0 ($bignum-byte-ref x 0)]
[b1 ($bignum-byte-ref x 1)]
[b2 ($bignum-byte-ref x 2)]
[b3 ($bignum-byte-ref x 3)]
[b4 ($bignum-byte-ref x 4)]
[b5 ($bignum-byte-ref x 5)]
[b6 ($bignum-byte-ref x 6)]
[b7 ($bignum-byte-ref x 7)]
[pos? ($bignum-positive? x)])
(if (fx= b7 0)
(if (fx= b6 0)
(if (fx= b5 0)
(if (fx= b4 0)
(error 'bignum8->flonum "malformed bignum")
($flonum/aux pos? -16 b4 b3 b2 b1 b0 0 0 0))
($flonum/aux pos? -8 b5 b4 b3 b2 b1 b0 0 0))
($flonum/aux pos? 0 b6 b5 b4 b3 b2 b1 b0 0))
($flonum/aux pos? 8 b7 b6 b5 b4 b3 b2 b1 b0))))
(define (bignum/n->flonum x bytes)
(define (aux x b7 bytes)
($flonum/aux ($bignum-positive? x) (+ (* bytes 8) -48)
b7
($bignum-byte-ref x (fx- bytes 1))
($bignum-byte-ref x (fx- bytes 2))
($bignum-byte-ref x (fx- bytes 3))
($bignum-byte-ref x (fx- bytes 4))
($bignum-byte-ref x (fx- bytes 5))
($bignum-byte-ref x (fx- bytes 6))
($bignum-byte-ref x (fx- bytes 7))))
;;; bignum: [b0 b1 b2 b3 ... b_{bytes-1}]
(let* ([bytes (fxsub1 bytes)] [bn ($bignum-byte-ref x bytes)])
(if (fx= bn 0)
(let* ([bytes (fxsub1 bytes)] [bn ($bignum-byte-ref x bytes)])
(if (fx= bn 0)
(let* ([bytes (fxsub1 bytes)] [bn ($bignum-byte-ref x bytes)])
(if (fx= bn 0)
(let* ([bytes (fxsub1 bytes)] [bn ($bignum-byte-ref x bytes)])
(if (fx= bn 0)
(error 'bignum/n->flonum "malformed bignum")
(aux x bn bytes)))
(aux x bn bytes)))
(aux x bn bytes)))
(aux x bn bytes))))
(unless (bignum? x)
(error 'bignum->flonum "~s is not a bignum" x))
(let ([bytes ($bignum-size x)])
(case bytes
[(4) (bignum/4->flonum x)]
[(8) (bignum/8->flonum x)]
[else (bignum/n->flonum x bytes)]))))
(define (ratnum->flonum x)
(let f ([n ($ratnum-n x)] [d ($ratnum-d x)])
(let-values ([(q r) (quotient+remainder n d)])
(if (= q 0)
(/ 1.0 (f d n))
(if (= r 0)
(inexact q)
(+ q (f r d)))))))
(define binary+
(lambda (x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_fxfxplus" x y)]
[(bignum? y)
(foreign-call "ikrt_fxbnplus" x y)]
[(flonum? y)
($fl+ ($fixnum->flonum x) y)]
[(ratnum? y)
($make-ratnum
(+ (* x ($ratnum-d y)) ($ratnum-n y))
($ratnum-d y))]
[else
(error '+ "~s is not a number" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_fxbnplus" y x)]
[(bignum? y)
(foreign-call "ikrt_bnbnplus" x y)]
[(flonum? y)
($fl+ (bignum->flonum x) y)]
[(ratnum? y)
($make-ratnum
(+ (* x ($ratnum-d y)) ($ratnum-n y))
($ratnum-d y))]
[else
(error '+ "~s is not a number" y)])]
[(flonum? x)
(cond
[(fixnum? y)
($fl+ x ($fixnum->flonum y))]
[(bignum? y)
($fl+ x (bignum->flonum y))]
[(flonum? y)
($fl+ x y)]
[(ratnum? y)
($fl+ x (ratnum->flonum y))]
[else
(error '+ "~s is not a number" y)])]
[(ratnum? x)
(cond
[(or (fixnum? y) (bignum? y))
($make-ratnum
(+ (* y ($ratnum-d x)) ($ratnum-n x))
($ratnum-d x))]
[(flonum? y)
($fl+ y (ratnum->flonum x))]
[(ratnum? y)
(let ([n0 ($ratnum-n x)] [n1 ($ratnum-n y)]
[d0 ($ratnum-d x)] [d1 ($ratnum-d y)])
;;; FIXME: inefficient
(/ (+ (* n0 d1) (* n1 d0)) (* d0 d1)))]
[else
(error '+ "~s is not a number" y)])]
[else (error '+ "~s is not a number" x)])))
(define binary-logand
(lambda (x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y) ($fxlogand x y)]
[(bignum? y)
(foreign-call "ikrt_fxbnlogand" x y)]
[else
(error 'logand "~s is not an exact integer" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_fxbnlogand" y x)]
[(bignum? y)
(foreign-call "ikrt_bnbnlogand" x y)]
[else
(error 'logand "~s is not an exact integer" y)])]
[else (error 'logand "~s is not an exact integer" x)])))
(define binary-
(lambda (x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_fxfxminus" x y)]
[(bignum? y)
(foreign-call "ikrt_fxbnminus" x y)]
[(flonum? y)
(if ($fx= x 0)
($fl* y -1.0)
($fl- ($fixnum->flonum x) y))]
[(ratnum? y)
(let ([n ($ratnum-n y)] [d ($ratnum-d y)])
(binary/ (binary- (binary* d x) n) d))]
[else
(error '- "~s is not a number" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_bnfxminus" x y)]
[(bignum? y)
(foreign-call "ikrt_bnbnminus" x y)]
[(flonum? y)
($fl- (bignum->flonum x) y)]
[(ratnum? y)
(let ([n ($ratnum-n y)] [d ($ratnum-d y)])
(binary/ (binary- (binary* d x) n) d))]
[else
(error '- "~s is not a number" y)])]
[(flonum? x)
(cond
[(fixnum? y)
($fl- x ($fixnum->flonum y))]
[(bignum? y)
($fl- x (bignum->flonum y))]
[(flonum? y)
($fl- x y)]
[(ratnum? y)
(let ([n ($ratnum-n y)] [d ($ratnum-d y)])
(binary/ (binary- (binary* d x) n) d))]
[else
(error '- "~s is not a number" y)])]
[(ratnum? x)
(let ([nx ($ratnum-n x)] [dx ($ratnum-d x)])
(cond
[(or (fixnum? y) (bignum? y) (flonum? y))
(binary/ (binary- nx (binary* dx y)) dx)]
[(ratnum? y)
(let ([ny ($ratnum-n y)] [dy ($ratnum-d y)])
(binary/ (binary- (binary* nx dy) (binary* ny dx))
(binary* dx dy)))]
[else
(error '- "~s is not a number" y)]))]
[else (error '- "~s is not a number" x)])))
(define binary*
(lambda (x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_fxfxmult" x y)]
[(bignum? y)
(foreign-call "ikrt_fxbnmult" x y)]
[(flonum? y)
($fl* ($fixnum->flonum x) y)]
[(ratnum? y)
(binary/ (binary* x ($ratnum-n y)) ($ratnum-d y))]
[else
(error '* "~s is not a number" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(foreign-call "ikrt_fxbnmult" y x)]
[(bignum? y)
(foreign-call "ikrt_bnbnmult" x y)]
[(flonum? y)
($fl* (bignum->flonum x) y)]
[(ratnum? y)
(binary/ (binary* x ($ratnum-n y)) ($ratnum-d y))]
[else
(error '* "~s is not a number" y)])]
[(flonum? x)
(cond
[(fixnum? y)
($fl* x ($fixnum->flonum y))]
[(bignum? y)
($fl* x (bignum->flonum y))]
[(flonum? y)
($fl* x y)]
[(ratnum? y)
(binary/ (binary* x ($ratnum-n y)) ($ratnum-d y))]
[else
(error '* "~s is not a number" y)])]
[(ratnum? x)
(if (ratnum? y)
(binary/ (binary* ($ratnum-n x) ($ratnum-n y))
(binary* ($ratnum-d x) ($ratnum-d y)))
(binary* y x))]
[else (error '* "~s is not a number" x)])))
(define +
(case-lambda
[(x y) (binary+ x y)]
[(x y z) (binary+ (binary+ x y) z)]
[(a)
(cond
[(fixnum? a) a]
[(bignum? a) a]
[else (error '+ "~s is not a number" a)])]
[() 0]
[(a b c d . e*)
(let f ([ac (binary+ (binary+ (binary+ a b) c) d)]
[e* e*])
(cond
[(null? e*) ac]
[else (f (binary+ ac (car e*)) (cdr e*))]))]))
(define logand
(case-lambda
[(x y) (binary-logand x y)]
[(x y z) (binary-logand (binary-logand x y) z)]
[(a)
(cond
[(fixnum? a) a]
[(bignum? a) a]
[else (error 'logand "~s is not a number" a)])]
[() -1]
[(a b c d . e*)
(let f ([ac (binary-logand (binary-logand (binary-logand a b) c) d)]
[e* e*])
(cond
[(null? e*) ac]
[else (f (binary-logand ac (car e*)) (cdr e*))]))]))
(define -
(case-lambda
[(x y) (binary- x y)]
[(x y z) (binary- (binary- x y) z)]
[(a) (binary- 0 a)]
[(a b c d . e*)
(let f ([ac (binary- (binary- (binary- a b) c) d)]
[e* e*])
(cond
[(null? e*) ac]
[else (f (binary- ac (car e*)) (cdr e*))]))]))
(define *
(case-lambda
[(x y) (binary* x y)]
[(x y z) (binary* (binary* x y) z)]
[(a)
(cond
[(fixnum? a) a]
[(bignum? a) a]
[else (error '* "~s is not a number" a)])]
[() 1]
[(a b c d . e*)
(let f ([ac (binary* (binary* (binary* a b) c) d)]
[e* e*])
(cond
[(null? e*) ac]
[else (f (binary* ac (car e*)) (cdr e*))]))]))
(define (binary-gcd x y)
(define (gcd x y)
(cond
[($fx= y 0) x]
[else (gcd y (remainder x y))]))
(let ([x (if (< x 0) (- x) x)]
[y (if (< y 0) (- y) y)])
(cond
[(> x y) (gcd x y)]
[(< x y) (gcd y x)]
[else x])))
(define gcd
(case-lambda
[(x y)
(cond
[(or (fixnum? x) (bignum? x))
(cond
[(or (fixnum? y) (bignum? y))
(binary-gcd x y)]
[(number? y)
(error 'gcd "~s is not an exact integer" y)]
[else
(error 'gcd "~s is not a number" y)])]
[(number? x)
(error 'gcd "~s is not an exact integer" x)]
[else
(error 'gcd "~s is not a number" x)])]
[(x)
(cond
[(or (fixnum? x) (bignum? x)) x]
[(number? x)
(error 'gcd "~s is not an exact integer" x)]
[else
(error 'gcd "~s is not a number" x)])]
[() 0]
[(x y z . ls)
(let f ([g (gcd (gcd x y) z)] [ls ls])
(cond
[(null? ls) g]
[else (f (gcd g (car ls)) (cdr ls))]))]))
(define lcm
(case-lambda
[(x y)
(cond
[(or (fixnum? x) (bignum? x))
(cond
[(or (fixnum? y) (bignum? y))
(let ([x (if (< x 0) (- x) x)]
[y (if (< y 0) (- y) y)])
(let ([g (binary-gcd x y)])
(binary* y (quotient x g))))]
[(number? y)
(error 'lcm "~s is not an exact integer" y)]
[else
(error 'lcm "~s is not a number" y)])]
[(number? x)
(error 'lcm "~s is not an exact integer" x)]
[else
(error 'lcm "~s is not a number" x)])]
[(x)
(cond
[(or (fixnum? x) (bignum? x)) x]
[(number? x)
(error 'lcm "~s is not an exact integer" x)]
[else
(error 'lcm "~s is not a number" x)])]
[() 1]
[(x y z . ls)
(let f ([g (lcm (lcm x y) z)] [ls ls])
(cond
[(null? ls) g]
[else (f (lcm g (car ls)) (cdr ls))]))]))
(define binary/ ;;; implements ratnums
(lambda (x y)
(cond
[(flonum? x)
(cond
[(flonum? y) ($fl/ x y)]
[(fixnum? y) ($fl/ x ($fixnum->flonum y))]
[(bignum? y) ($fl/ x (bignum->flonum y))]
[(ratnum? y) ($fl/ x (ratnum->flonum y))]
[else (error '/ "unspported ~s ~s" x y)])]
[(fixnum? x)
(cond
[(flonum? y) ($fl/ ($fixnum->flonum x) y)]
[(fixnum? y)
(cond
[($fx= y 0) (error '/ "division by 0")]
[($fx> y 0)
(if ($fx= y 1)
x
(let ([g (binary-gcd x y)])
(cond
[($fx= g y) (fxquotient x g)]
[($fx= g 1) ($make-ratnum x y)]
[else ($make-ratnum (fxquotient x g) (fxquotient y g))])))]
[else
(if ($fx= y -1)
(binary- 0 x)
(let ([g (binary-gcd x y)])
(cond
[($fx= ($fx- 0 g) y) (binary- 0 (fxquotient x g))]
[($fx= g 1) ($make-ratnum (binary- 0 x) (binary- 0 y))]
[else
($make-ratnum
(binary- 0 (fxquotient x g))
(binary- 0 (fxquotient y g)))])))])]
[(bignum? y)
(let ([g (binary-gcd x y)])
(cond
[(= g y) (quotient x g)] ;;; should not happen
[($bignum-positive? y)
(if ($fx= g 1)
($make-ratnum x y)
($make-ratnum (fxquotient x g) (quotient y g)))]
[else
(if ($fx= g 1)
($make-ratnum (binary- 0 x) (binary- 0 y))
($make-ratnum
(binary- 0 (fxquotient x g))
(binary- 0 (quotient y g))))]))]
[(ratnum? y)
(/ (* x ($ratnum-d y)) ($ratnum-n y))]
[else (error '/ "unsupported ~s ~s" x y)])]
[(bignum? x)
(cond
[(fixnum? y)
(cond
[($fx= y 0) (error '/ "division by 0")]
[($fx> y 0)
(if ($fx= y 1)
x
(let ([g (binary-gcd x y)])
(cond
[($fx= g 1) ($make-ratnum x y)]
[($fx= g y) (quotient x g)]
[else
($make-ratnum (quotient x g) (quotient y g))])))]
[else
(if ($fx= y -1)
(- x)
(let ([g (binary-gcd x y)])
(cond
[(= (- g) y) (- (quotient x g))]
[else
($make-ratnum
(- (quotient x g))
(- (quotient y g)))])))])]
[(bignum? y)
(let ([g (binary-gcd x y)])
(cond
[($fx= g 1) ($make-ratnum x y)]
[($bignum-positive? y)
(if (= g y)
(quotient x g)
($make-ratnum (quotient x g) (quotient y g)))]
[else
(let ([y (binary- 0 y)])
(if (= g y)
(binary- 0 (quotient x g))
($make-ratnum (binary- 0 (quotient x g))
(quotient y g))))]))]
[(flonum? y) ($fl/ (bignum->flonum x) y)]
[(ratnum? y)
(binary/ (binary* x ($ratnum-n y)) ($ratnum-d y))]
[else (error '/ "~s is not a number" y)])]
[(ratnum? x)
(cond
[(ratnum? y)
(binary/
(binary* ($ratnum-n x) ($ratnum-d y))
(binary* ($ratnum-n y) ($ratnum-d x)))]
[else (binary/ 1 (binary/ y x))])]
[else (error '/ "~s is not a number" x)])))
(define /
(case-lambda
[(x y) (binary/ x y)]
[(x)
(cond
[(fixnum? x)
(cond
[($fxzero? x) (error '/ "division by 0")]
[($fx> x 0)
(if ($fx= x 1)
1
($make-ratnum 1 x))]
[else
(if ($fx= x -1)
-1
($make-ratnum -1 (- x)))])]
[(bignum? x)
(if ($bignum-positive? x)
($make-ratnum 1 x)
($make-ratnum -1 (- x)))]
[(flonum? x) (foreign-call "ikrt_fl_invert" x)]
[(ratnum? x)
(let ([n ($ratnum-n x)] [d ($ratnum-d x)])
(cond
[($fx= n 1) d]
[($fx= n -1) (- d)]
[else ($make-ratnum d n)]))]
[else (error '/ "unspported argument ~s" x)])]
[(x y z . rest)
(let f ([a (binary/ x y)] [b z] [ls rest])
(cond
[(null? rest) (binary/ a b)]
[else (f (binary/ a b) (car ls) (cdr ls))]))]))
(define flmax
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
(if ($fl< x y)
y
x)
(error 'flmax "~s is not a flonum" y))
(error 'flmax "~s is not a flonum" x))]
[(x y z . rest)
(let f ([a (flmax x y)] [b z] [ls rest])
(cond
[(null? ls) (flmax a b)]
[else
(f (flmax a b) (car ls) (cdr ls))]))]
[(x)
(if (flonum? x)
x
(error 'flmax "~s is not a number" x))]))
(define max
(case-lambda
[(x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y)
(if ($fx> x y) x y)]
[(bignum? y)
(if (positive-bignum? y) y x)]
[else (error 'max "~s is not a number" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(if (positive-bignum? x) x y)]
[(bignum? y)
(if (bnbn> x y) x y)]
[else (error 'max "~s is not a number" y)])]
[else (error 'max "~s is not a number" x)])]
[(x y z . rest)
(let f ([a (max x y)] [b z] [ls rest])
(cond
[(null? ls) (max a b)]
[else
(f (max a b) (car ls) (cdr ls))]))]
[(x)
(if (number? x)
x
(error 'max "~s is not a number" x))]))
(define min
(case-lambda
[(x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y)
(if ($fx> x y) y x)]
[(bignum? y)
(if (positive-bignum? y) x y)]
[else (error 'min "~s is not a number" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(if (positive-bignum? x) y x)]
[(bignum? y)
(if (bnbn> x y) y x)]
[else (error 'min "~s is not a number" y)])]
[else (error 'min "~s is not a number" x)])]
[(x y z . rest)
(let f ([a (min x y)] [b z] [ls rest])
(cond
[(null? ls) (min a b)]
[else
(f (min a b) (car ls) (cdr ls))]))]
[(x)
(if (number? x)
x
(error 'min "~s is not a number" x))]))
(define (abs x)
(cond
[(fixnum? x)
(if ($fx< x 0) (- x) x)]
[(bignum? x)
(if ($bignum-positive? x) x (- x))]
[(flonum? x)
(if ($flnegative? x)
($fl* x -1.0)
x)]
[(ratnum? x)
(let ([n ($ratnum-n x)])
(if (< n 0)
($make-ratnum (- n) ($ratnum-d x))
x))]
[else (error 'abs "~s is not a number" x)]))
(define flmin
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
(if ($fl< x y) x y)
(error 'flmin "~s is not a flonum" y))
(error 'flmin "~s is not a flonum" x))]
[(x y z . rest)
(let f ([a (flmin x y)] [b z] [ls rest])
(cond
[(null? ls) (flmin a b)]
[else
(f (flmin a b) (car ls) (cdr ls))]))]
[(x)
(if (flonum? x)
x
(error 'flmin "~s is not a flonum" x))]))
(define exact->inexact
(lambda (x)
(cond
[(fixnum? x) ($fixnum->flonum x)]
[(bignum? x) (bignum->flonum x)]
[(ratnum? x) (ratnum->flonum x)]
[else
(error 'exact->inexact
"~s is not an exact number" x)])))
(define inexact
(lambda (x)
(cond
[(fixnum? x) ($fixnum->flonum x)]
[(bignum? x) (bignum->flonum x)]
[(ratnum? x) (ratnum->flonum x)]
[(flonum? x) x]
[else
(error 'inexact "~s is not a number" x)])))
(define positive-bignum?
(lambda (x)
(foreign-call "ikrt_positive_bn" x)))
(define even-bignum?
(lambda (x)
(foreign-call "ikrt_even_bn" x)))
(define ($fxeven? x)
($fxzero? ($fxlogand x 1)))
(define (even? x)
(cond
[(fixnum? x) ($fxeven? x)]
[(bignum? x) (even-bignum? x)]
[else (error 'even? "~s is not an integer" x)]))
(define (odd? x)
(not
(cond
[(fixnum? x) ($fxeven? x)]
[(bignum? x) (even-bignum? x)]
[else (error 'odd? "~s is not an integer" x)])))
(define bignum->string
(lambda (x)
(utf8-bytevector->string
(foreign-call "ikrt_bignum_to_bytevector" x))))
(define ratnum->string
(lambda (x)
(string-append
(number->string ($ratnum-n x))
"/"
(number->string ($ratnum-d x)))))
(define number->string
(lambda (x)
(cond
[(fixnum? x) (fixnum->string x)]
[(bignum? x) (bignum->string x)]
[(flonum? x) (flonum->string x)]
[(ratnum? x) (ratnum->string x)]
[else (error 'number->string "~s is not a number" x)])))
(define modulo
(lambda (n m)
(cond
[(fixnum? n)
(cond
[(fixnum? m) ($fxmodulo n m)]
[else (error 'modulo "unsupported ~s" m)])]
[else (error 'modulo "unsupported ~s" n)])))
(define-syntax mk<
(syntax-rules ()
[(_ name fxfx< fxbn< bnfx< bnbn<
fxfl< flfx< bnfl< flbn< flfl<
fxrt< rtfx< bnrt< rtbn< flrt< rtfl< rtrt<)
(let ()
(define err
(lambda (x) (error 'name "~s is not a number" x)))
(define fxloopt
(lambda (x y ls)
(cond
[(fixnum? y)
(if (null? ls)
(fxfx< x y)
(if (fxfx< x y)
(fxloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(bignum? y)
(if (null? ls)
(fxbn< x y)
(if (fxbn< x y)
(bnloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(flonum? y)
(if (null? ls)
(fxfl< x y)
(if (fxfl< x y)
(flloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(ratnum? y)
(if (null? ls)
(fxrt< x y)
(if (fxrt< x y)
(rtloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[else (err y)])))
(define bnloopt
(lambda (x y ls)
(cond
[(fixnum? y)
(if (null? ls)
(bnfx< x y)
(if (bnfx< x y)
(fxloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(bignum? y)
(if (null? ls)
(bnbn< x y)
(if (bnbn< x y)
(bnloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(flonum? y)
(if (null? ls)
(bnfl< x y)
(if (bnfl< x y)
(flloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(ratnum? y)
(if (null? ls)
(bnrt< x y)
(if (bnrt< x y)
(rtloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[else (err y)])))
(define flloopt
(lambda (x y ls)
(cond
[(fixnum? y)
(if (null? ls)
(flfx< x y)
(if (flfx< x y)
(fxloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(bignum? y)
(if (null? ls)
(flbn< x y)
(if (flbn< x y)
(bnloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(flonum? y)
(if (null? ls)
(flfl< x y)
(if (flfl< x y)
(flloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(ratnum? y)
(if (null? ls)
(flrt< x y)
(if (flrt< x y)
(rtloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[else (err y)])))
(define rtloopt
(lambda (x y ls)
(cond
[(fixnum? y)
(if (null? ls)
(rtfx< x y)
(if (rtfx< x y)
(fxloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(bignum? y)
(if (null? ls)
(rtbn< x y)
(if (rtbn< x y)
(bnloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(flonum? y)
(if (null? ls)
(rtfl< x y)
(if (rtfl< x y)
(flloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[(ratnum? y)
(if (null? ls)
(rtrt< x y)
(if (rtrt< x y)
(rtloopt y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))]
[else (err y)])))
(define loopf
(lambda (x ls)
(cond
[(number? x)
(if (null? ls)
#f
(loopf (car ls) (cdr ls)))]
[else (err x)])))
(define f
(case-lambda
[(x y)
(cond
[(fixnum? x)
(cond
[(fixnum? y) (fxfx< x y)]
[(bignum? y) (fxbn< x y)]
[(flonum? y) (fxfl< x y)]
[(ratnum? y) (fxrt< x y)]
[else (err y)])]
[(bignum? x)
(cond
[(fixnum? y) (bnfx< x y)]
[(bignum? y) (bnbn< x y)]
[(flonum? y) (bnfl< x y)]
[(ratnum? y) (bnrt< x y)]
[else (err y)])]
[(flonum? x)
(cond
[(fixnum? y) (flfx< x y)]
[(bignum? y) (flbn< x y)]
[(flonum? y) (flfl< x y)]
[(ratnum? y) (flrt< x y)]
[else (err y)])]
[(ratnum? x)
(cond
[(fixnum? y) (rtfx< x y)]
[(bignum? y) (rtbn< x y)]
[(flonum? y) (rtfl< x y)]
[(ratnum? y) (rtrt< x y)]
[else (err y)])]
[else (err x)])]
[(x y z) (and (f x y) (f y z))]
[(x) (if (number? x) #t (err x))]
[(x y . ls)
(cond
[(fixnum? x) (fxloopt x y ls)]
[(bignum? x) (bnloopt x y ls)]
[(flonum? x) (flloopt x y ls)]
[(ratnum? x) (rtloopt x y ls)]
[else (err x)])]))
f)]))
(define-syntax false (syntax-rules () [(_ x y) #f]))
(define-syntax bnbncmp
(syntax-rules ()
[(_ x y cmp)
(cmp (foreign-call "ikrt_bnbncomp" x y) 0)]))
(define-syntax bnbn= (syntax-rules () [(_ x y) (bnbncmp x y $fx=)]))
(define-syntax bnbn< (syntax-rules () [(_ x y) (bnbncmp x y $fx<)]))
(define-syntax bnbn> (syntax-rules () [(_ x y) (bnbncmp x y $fx>)]))
(define-syntax bnbn<= (syntax-rules () [(_ x y) (bnbncmp x y $fx<=)]))
(define-syntax bnbn>= (syntax-rules () [(_ x y) (bnbncmp x y $fx>=)]))
(define-syntax fxbn< (syntax-rules () [(_ x y) (positive-bignum? y)]))
(define-syntax bnfx< (syntax-rules () [(_ x y) (not (positive-bignum? x))]))
(define-syntax fxbn> (syntax-rules () [(_ x y) (not (positive-bignum? y))]))
(define-syntax bnfx> (syntax-rules () [(_ x y) (positive-bignum? x)]))
(define-syntax flcmp
(syntax-rules ()
[(_ flfl? flfx? fxfl? flbn? bnfl? fl?)
(begin
(define-syntax flfl?
(syntax-rules () [(_ x y) (fl? x y)]))
(define-syntax flfx?
(syntax-rules () [(_ x y) (fl? x ($fixnum->flonum y))]))
(define-syntax flbn?
(syntax-rules () [(_ x y) (fl? x (bignum->flonum y))]))
(define-syntax fxfl?
(syntax-rules () [(_ x y) (fl? ($fixnum->flonum x) y)]))
(define-syntax bnfl?
(syntax-rules () [(_ x y) (fl? (bignum->flonum x) y)])))]))
;;; #;
;;; (begin
;;; (define-syntax $fl=
;;; (syntax-rules () [(_ x y) (foreign-call "ikrt_fl_equal" x y)]))
;;; (define-syntax $fl<
;;; (syntax-rules () [(_ x y) (foreign-call "ikrt_fl_less" x y)]))
;;; (define-syntax $fl<=
;;; (syntax-rules () [(_ x y) (foreign-call "ikrt_fl_less_or_equal" x y)]))
;;; (define-syntax $fl>
;;; (syntax-rules () [(_ x y) (foreign-call "ikrt_fl_less" y x)]))
;;; (define-syntax $fl>=
;;; (syntax-rules () [(_ x y) (foreign-call "ikrt_fl_less_or_equal" y x)])))
(define-syntax define-flcmp
(syntax-rules ()
[(_ fl<? $fl<)
(define fl<?
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
($fl< x y)
(error 'fl<? "~s is not a flonum" y))
(error 'fl<? "~s is not a flonum" x))]
[(x y z)
(if (flonum? x)
(if (flonum? y)
(if (flonum? z)
(and ($fl< x y) ($fl< y z))
(error 'fl<? "~s is not a flonum" z))
(error 'fl<? "~s is not a flonum" y))
(error 'fl<? "~s is not a flonum" x))]
[(x)
(or (flonum? x)
(error 'fl<? "~s is not a flonum" x))]
[(x y . rest)
(let ()
(define (loopf a ls)
(unless (flonum? a)
(error 'fl<? "~s is not a flonum" a))
(if (null? ls)
#f
(loopf (car ls) (cdr ls))))
(if (flonum? x)
(if (flonum? y)
(if ($fl< x y)
(let f ([x y] [y (car rest)] [ls (cdr rest)])
(if (flonum? y)
(if (null? ls)
($fl< x y)
(if ($fl< x y)
(f y (car ls) (cdr ls))
(loopf (car ls) (cdr ls))))
(error 'fl<? "~s is not a flonum" y)))
(loopf (car rest) (cdr rest)))
(error 'fl<? "~s is not a flonum" y))
(error 'fl<? "~s is not a flonum" x)))]))]))
(define-flcmp fl=? $fl=)
(define-flcmp fl<? $fl<)
(define-flcmp fl<=? $fl<=)
(define-flcmp fl>? $fl>)
(define-flcmp fl>=? $fl>=)
(define fl+
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
($fl+ x y)
(error 'fl+ "~s is not a flonum" y))
(error 'fl+ "~s is not a flonum" x))]
[(x y z)
(fl+ (fl+ x y) z)]
[(x y z q . rest)
(let f ([ac (fl+ (fl+ (fl+ x y) z) q)] [rest rest])
(if (null? rest)
ac
(f (fl+ ac (car rest)) (cdr rest))))]
[(x)
(if (flonum? x)
x
(error 'fl+ "~s is not a flonum" x))]
[() (exact->inexact 0)]))
(define fl-
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
($fl- x y)
(error 'fl- "~s is not a flonum" y))
(error 'fl- "~s is not a flonum" x))]
[(x y z)
(fl- (fl- x y) z)]
[(x y z q . rest)
(let f ([ac (fl- (fl- (fl- x y) z) q)] [rest rest])
(if (null? rest)
ac
(f (fl- ac (car rest)) (cdr rest))))]
[(x)
(if (flonum? x)
($fl* -1.0 x)
(error 'fl+ "~s is not a flonum" x))]))
(define fl*
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
($fl* x y)
(error 'fl* "~s is not a flonum" y))
(error 'fl* "~s is not a flonum" x))]
[(x y z)
(fl* (fl* x y) z)]
[(x y z q . rest)
(let f ([ac (fl* (fl* (fl* x y) z) q)] [rest rest])
(if (null? rest)
ac
(f (fl* ac (car rest)) (cdr rest))))]
[(x)
(if (flonum? x)
x
(error 'fl* "~s is not a flonum" x))]
[() 1.0]))
(define fl/
(case-lambda
[(x y)
(if (flonum? x)
(if (flonum? y)
($fl/ x y)
(error 'fl/ "~s is not a flonum" y))
(error 'fl/ "~s is not a flonum" x))]
[(x y z)
(fl/ (fl/ x y) z)]
[(x y z q . rest)
(let f ([ac (fl/ (fl/ (fl/ x y) z) q)] [rest rest])
(if (null? rest)
ac
(f (fl/ ac (car rest)) (cdr rest))))]
[(x)
(if (flonum? x)
($fl/ 1.0 x)
(error 'fl/ "~s is not a flonum" x))]))
(flcmp flfl= flfx= fxfl= flbn= bnfl= $fl=)
(flcmp flfl< flfx< fxfl< flbn< bnfl< $fl<)
(flcmp flfl> flfx> fxfl> flbn> bnfl> $fl>)
(flcmp flfl<= flfx<= fxfl<= flbn<= bnfl<= $fl<=)
(flcmp flfl>= flfx>= fxfl>= flbn>= bnfl>= $fl>=)
(define-syntax flrt= (syntax-rules () [(_ x y) (= (inexact->exact x) y)]))
(define-syntax rtfl= (syntax-rules () [(_ x y) (= x (inexact->exact y))]))
(define-syntax flrt< (syntax-rules () [(_ x y) (< (inexact->exact x) y)]))
(define-syntax rtfl< (syntax-rules () [(_ x y) (< x (inexact->exact y))]))
(define-syntax flrt<= (syntax-rules () [(_ x y) (<= (inexact->exact x) y)]))
(define-syntax rtfl<= (syntax-rules () [(_ x y) (<= x (inexact->exact y))]))
(define-syntax flrt> (syntax-rules () [(_ x y) (> (inexact->exact x) y)]))
(define-syntax rtfl> (syntax-rules () [(_ x y) (> x (inexact->exact y))]))
(define-syntax flrt>= (syntax-rules () [(_ x y) (>= (inexact->exact x) y)]))
(define-syntax rtfl>= (syntax-rules () [(_ x y) (>= x (inexact->exact y))]))
(define (exrt< x y) (< (* x ($ratnum-d y)) ($ratnum-n y)))
(define (rtex< x y) (< ($ratnum-n x) (* y ($ratnum-d x))))
(define (rtrt< x y) (< (* ($ratnum-n x) ($ratnum-d y)) (* ($ratnum-n y) ($ratnum-d x))))
(define (rtrt<= x y) (<= (* ($ratnum-n x) ($ratnum-d y)) (* ($ratnum-n y) ($ratnum-d x))))
(define (exrt> x y) (> (* x ($ratnum-d y)) ($ratnum-n y)))
(define (rtex> x y) (> ($ratnum-n x) (* y ($ratnum-d x))))
(define (rtrt> x y) (> (* ($ratnum-n x) ($ratnum-d y)) (* ($ratnum-n y) ($ratnum-d x))))
(define (rtrt>= x y) (>= (* ($ratnum-n x) ($ratnum-d y)) (* ($ratnum-n y) ($ratnum-d x))))
(define (rtrt= x y)
(and (= ($ratnum-n x) ($ratnum-n y)) (= ($ratnum-d x) ($ratnum-d y))))
(define =
(mk< = $fx= false false bnbn= fxfl= flfx= bnfl= flbn= flfl=
false false false false flrt= rtfl= rtrt=))
(define <
(mk< < $fx< fxbn< bnfx< bnbn< fxfl< flfx< bnfl< flbn< flfl<
exrt< rtex< exrt< rtex< flrt< rtfl< rtrt<))
(define >
(mk< > $fx> fxbn> bnfx> bnbn> fxfl> flfx> bnfl> flbn> flfl>
exrt> rtex> exrt> rtex> flrt> rtfl> rtrt>))
(define <=
(mk< <= $fx<= fxbn< bnfx< bnbn<= fxfl<= flfx<= bnfl<= flbn<= flfl<=
exrt< rtex< exrt< rtex< flrt<= rtfl<= rtrt<=))
(define >=
(mk< >= $fx>= fxbn> bnfx> bnbn>= fxfl>= flfx>= bnfl>= flbn>= flfl>=
exrt> rtex> exrt> rtex> flrt>= rtfl>= rtrt>=))
(define add1
(lambda (x)
(cond
[(fixnum? x)
(foreign-call "ikrt_fxfxplus" x 1)]
[(bignum? x)
(foreign-call "ikrt_fxbnplus" 1 x)]
[else (error 'add1 "~s is not a number" x)])))
(define sub1
(lambda (x)
(cond
[(fixnum? x)
(foreign-call "ikrt_fxfxplus" x -1)]
[(bignum? x)
(foreign-call "ikrt_fxbnplus" -1 x)]
[else (error 'sub1 "~s is not a number" x)])))
(define zero?
(lambda (x)
(cond
[(fixnum? x) (eq? x 0)]
[(bignum? x) #f]
[(flonum? x)
(or ($fl= x 0.0) ($fl= x -0.0))]
[else (error 'zero? "tag=~s / ~s is not a number"
($fxlogand 255
($fxsll x 2))
($fxlogand x -1)
)])))
(define expt
(lambda (n m)
(define fxexpt
(lambda (n m)
(cond
[($fxzero? m) 1]
[($fxzero? ($fxlogand m 1))
(fxexpt (binary* n n) ($fxsra m 1))]
[else
(binary* n (fxexpt (binary* n n) ($fxsra m 1)))])))
(unless (number? n)
(error 'expt "~s is not a numebr" n))
(cond
[(fixnum? m)
(if ($fx>= m 0)
(fxexpt n m)
(/ 1 (expt n (- m))))]
[(bignum? m)
(cond
[(eq? n 0) 0]
[(eq? n 1) 1]
[(eq? n -1)
(if (positive-bignum? m)
(if (even-bignum? m)
1
-1)
(/ 1 (expt n (- m))))]
[else
(error 'expt "(expt ~s ~s) is too big to compute" n m)])]
[else (error 'expt "~s is not a number" m)])))
(define quotient
(lambda (x y)
(let-values ([(q r) (quotient+remainder x y)])
q)))
(define remainder
(lambda (x y)
(let-values ([(q r) (quotient+remainder x y)])
r)))
(define quotient+remainder
(lambda (x y)
(cond
[(eq? y 0)
(error 'quotient+remainder
"second argument must be non-zero")]
[(fixnum? x)
(cond
[(fixnum? y)
(values (fxquotient x y)
(fxremainder x y))]
[(bignum? y) (values 0 x)]
[(flonum? y)
(let ([v ($flonum->exact y)])
(cond
[(or (fixnum? v) (bignum? v))
(let-values ([(q r) (quotient+remainder x v)])
(values (inexact q) (inexact r)))]
[else
(error 'quotient+remainder "~s is not an integer" y)]))]
[else (error 'quotient+remainder "~s is not a number" y)])]
[(bignum? x)
(cond
[(fixnum? y)
(let ([p (foreign-call "ikrt_bnfxdivrem" x y)])
(values (car p) (cdr p)))]
[(bignum? y)
(let ([p (foreign-call "ikrt_bnbndivrem" x y)])
(values (car p) (cdr p)))]
[(flonum? y)
(let ([v ($flonum->exact y)])
(cond
[(or (fixnum? v) (bignum? v))
(let-values ([(q r) (quotient+remainder x v)])
(values (inexact q) (inexact r)))]
[else
(error 'quotient+remainder "~s is not an integer" y)]))]
[else (error 'quotient+remainder "~s is not a number" y)])]
[(flonum? x)
(let ([v ($flonum->exact x)])
(cond
[(or (fixnum? v) (bignum? v))
(let-values ([(q r) (quotient+remainder v y)])
(values (inexact q) (inexact r)))]
[else (error 'quotient+remainder "~s is not an integer" x)]))]
[else (error 'quotient+remainder "~s is not a number" x)])))
(define positive?
(lambda (x)
(cond
[(fixnum? x) ($fx> x 0)]
[(flonum? x) ($fl> x 0.0)]
[(bignum? x) (positive-bignum? x)]
[(ratnum? x) (positive? ($ratnum-n x))]
[else (error 'positive? "~s is not a number" x)])))
(define negative?
(lambda (x)
(cond
[(fixnum? x) ($fx< x 0)]
[(flonum? x) ($fl< x 0.0)]
[(bignum? x) (not (positive-bignum? x))]
[(ratnum? x) (negative? ($ratnum-n x))]
[else (error 'negative? "~s is not a number" x)])))
(define sin
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_sin" x)]
[(fixnum? x) (foreign-call "ikrt_fx_sin" x)]
[else (error 'sin "unsupported ~s" x)])))
(define cos
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_cos" x)]
[(fixnum? x) (foreign-call "ikrt_fx_cos" x)]
[else (error 'cos "unsupported ~s" x)])))
(define tan
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_tan" x)]
[(fixnum? x) (foreign-call "ikrt_fx_tan" x)]
[else (error 'tan "unsupported ~s" x)])))
(define asin
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_asin" x)]
[(fixnum? x) (foreign-call "ikrt_fx_asin" x)]
[else (error 'asin "unsupported ~s" x)])))
(define acos
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_acos" x)]
[(fixnum? x) (foreign-call "ikrt_fx_acos" x)]
[else (error 'acos "unsupported ~s" x)])))
(define atan
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_atan" x)]
[(fixnum? x) (foreign-call "ikrt_fx_atan" x)]
[else (error 'atan "unsupported ~s" x)])))
(define sqrt
(lambda (x)
(cond
[(flonum? x) (foreign-call "ikrt_fl_sqrt" x)]
[(fixnum? x) (foreign-call "ikrt_fx_sqrt" x)]
[(bignum? x) (error 'sqrt "BUG: bignum sqrt not implemented")]
[(ratnum? x) (/ (sqrt ($ratnum-n x)) (sqrt ($ratnum-d x)))]
[else (error 'sqrt "unsupported ~s" x)])))
(define flsqrt
(lambda (x)
(if (flonum? x)
(foreign-call "ikrt_fl_sqrt" x)
(error 'flsqrt "~s is not a flonum" x))))
(define flzero?
(lambda (x)
(if (flonum? x)
($flzero? x)
(error 'flzero? "~s is not a flonum" x))))
(define flnegative?
(lambda (x)
(if (flonum? x)
($fl< x 0.0)
(error 'flnegative? "~s is not a flonum" x))))
(define exact-integer-sqrt
(lambda (x)
(define who 'exact-integer-sqrt)
(define (fxsqrt x i k)
(let ([j ($fxsra ($fx+ i k) 1)])
(let ([j^2 ($fx* j j)])
(if ($fx> j^2 x)
(fxsqrt x i j)
(if ($fx= i j)
(values j ($fx- x j^2))
(fxsqrt x j k))))))
(define (bnsqrt x i k)
(let ([j (quotient (+ i k) 2)])
(let ([j^2 (* j j)])
(if (> j^2 x)
(bnsqrt x i j)
(if (= i j)
(values j (- x j^2))
(bnsqrt x j k))))))
(cond
[(fixnum? x)
(cond
[($fx< x 0) (error who "invalid argument ~s" x)]
[($fx= x 0) (values 0 0)]
[($fx< x 4) (values 1 ($fx- x 1))]
[($fx< x 9) (values 2 ($fx- x 4))]
[($fx< x 46340) (fxsqrt x 3 ($fxsra x 1))]
[else (fxsqrt x 215 23171)])]
[(bignum? x)
(cond
[($bignum-positive? x)
(bnsqrt x 23170 (quotient x 23170))]
[else (error who "invalid argument ~s" x)])]
[else (error who "invalid argument ~s" x)])))
(define numerator
(lambda (x)
(cond
[(ratnum? x) ($ratnum-n x)]
[(or (fixnum? x) (bignum? x)) x]
[(flonum? x) (flnumerator x)]
[else (error 'numerator "~s is not an exact integer" x)])))
(define denominator
(lambda (x)
(cond
[(ratnum? x) ($ratnum-d x)]
[(or (fixnum? x) (bignum? x)) 1]
[(flonum? x) (fldenominator x)]
[else (error 'denominator "~s is not an exact integer" x)])))
(define (floor x)
(define (ratnum-floor x)
(let ([n (numerator x)] [d (denominator x)])
(let ([q (quotient n d)])
(if (>= n 0) q (- q 1)))))
(cond
[(flonum? x)
(let ([e (or ($flonum->exact x)
(error 'floor "~s has no real value" x))])
(cond
[(ratnum? e)
(exact->inexact (ratnum-floor e))]
[else x]))]
[(ratnum? x) (ratnum-floor x)]
[(or (fixnum? x) (bignum? x)) x]
[else (error 'floor "~s is not a number" x)]))
(define (ceiling x)
(define (ratnum-ceiling x)
(let ([n (numerator x)] [d (denominator x)])
(let ([q (quotient n d)])
(if (< n 0) q (+ q 1)))))
(cond
[(flonum? x)
(let ([e (or ($flonum->exact x)
(error 'ceiling "~s has no real value" x))])
(cond
[(ratnum? e) (exact->inexact (ratnum-ceiling e))]
[else x]))]
[(ratnum? x) (ratnum-ceiling x)]
[(or (fixnum? x) (bignum? x)) x]
[else (error 'ceiling "~s is not a number" x)]))
(define ($ratnum-round x)
(let ([n ($ratnum-n x)] [d ($ratnum-d x)])
(let-values ([(q r) (quotient+remainder n d)])
(let ([r2 (+ r r)])
(if (> n 0)
(cond
[(< r2 d) q]
[(> r2 d) (+ q 1)]
[else
(if (even? q) q (+ q 1))])
(let ([r2 (- r2)])
(cond
[(< r2 d) q]
[(< r2 d) (- q 1)]
[else
(if (even? q) q (- q 1))])))))))
(define ($ratnum-truncate x)
(let ([n ($ratnum-n x)] [d ($ratnum-d x)])
(quotient n d)))
;(define ($flround x)
; (foreign-call "ikrt_fl_round" x ($make-flonum)))
; (let ([e ($flonum->exact x)])
; (cond
; [(not e) x] ;;; infs and nans round to themselves
; [(ratnum? e) (exact->inexact ($ratnum-round e))]
; [else (exact->inexact e)])))
(define (flround x)
(if (flonum? x)
(let ([e ($flonum->exact x)])
(cond
[(ratnum? e) (exact->inexact ($ratnum-round e))]
[else x]))
(error 'flround "~s is not a flonum" x)))
(define (round x)
(cond
[(flonum? x)
(let ([e (or ($flonum->exact x)
(error 'round "~s has no real value" x))])
(cond
[(ratnum? e) (exact->inexact ($ratnum-round e))]
[else x]))]
[(ratnum? x) ($ratnum-round x)]
[(or (fixnum? x) (bignum? x)) x]
[else (error 'round "~s is not a number" x)]))
(define (truncate x)
(cond
[(flonum? x)
(let ([e (or ($flonum->exact x)
(error 'truncate "~s has no real value" x))])
(cond
[(ratnum? e) (exact->inexact ($ratnum-truncate e))]
[else x]))]
[(ratnum? x) ($ratnum-truncate x)]
[(or (fixnum? x) (bignum? x)) x]
[else (error 'truncate "~s is not a number" x)]))
(define (fltruncate x)
(unless (flonum? x)
(error 'fltruncate "~s is not a flonum" x))
(let ([v ($flonum->exact x)])
(cond
[(ratnum? v) (exact->inexact ($ratnum-truncate x))]
[else x])))
(define log
(lambda (x)
(cond
[(fixnum? x)
(cond
[($fx= x 1) 0]
[($fx= x 0) (error 'log "undefined around 0")]
[($fx> x 0) (foreign-call "ikrt_fx_log" x)]
[else (error 'log "negative argument ~s" x)])]
[(flonum? x)
(cond
[(>= x 0) (foreign-call "ikrt_fl_log" x)]
[else (error 'log "negative argument ~s" x)])]
[(bignum? x) (log (exact->inexact x))]
[(ratnum? x) (- (log (numerator x)) (log (denominator x)))]
[else (error 'log "~s is not a number" x)])))
(define string->number
(lambda (x)
(define (convert-char c radix)
(case radix
[(10)
(cond
[(char<=? #\0 c #\9)
(fx- (char->integer c) (char->integer #\0))]
[else #f])]
[(16)
(cond
[(char<=? #\0 c #\9)
(fx- (char->integer c) (char->integer #\0))]
[(char<=? #\a c #\f)
(fx- (char->integer c) (fx- (char->integer #\a) 10))]
[(char<=? #\A c #\F)
(fx- (char->integer c) (fx- (char->integer #\A) 10))]
[else #f])]
[(8)
(cond
[(char<=? #\0 c #\7)
(fx- (char->integer c) (char->integer #\0))]
[else #f])]
[(2)
(case c
[(#\0) 0]
[(#\1) 1]
[else #f])]
[else (error 'convert-char "invalid radix ~s" radix)]))
(define (parse-exponent-start x n i radix)
(define (parse-exponent x n i radix ac)
(cond
[(fx= i n) ac]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-exponent x n (fxadd1 i) radix
(+ d (* ac radix))))]
[else #f]))]))
(define (parse-exponent-sign x n i radix)
(cond
[(fx= i n) #f]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d) (parse-exponent x n (fxadd1 i) radix d))]
[else #f]))]))
(cond
[(fx= i n) #f]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-exponent x n (fxadd1 i) radix d))]
[(char=? c #\+)
(parse-exponent-sign x n (fxadd1 i) radix)]
[(char=? c #\-)
(let ([v (parse-exponent-sign x n (fxadd1 i) radix)])
(and v (- v)))]
[else #f]))]))
(define (parse-decimal x n i pos? radix exact? ac exp)
(cond
[(fx= i n)
(let ([ac (* (if pos? ac (- ac)) (expt radix exp))])
(exact-conv (or exact? 'i) ac))]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-decimal x n (fxadd1 i) pos? radix exact?
(+ (* ac radix) d) (fxsub1 exp)))]
[(memv c '(#\e #\E))
(let ([ex (parse-exponent-start x n (fxadd1 i) radix)])
(and ex
(exact-conv (or exact? 'i)
(* (if pos? ac (- ac)) (expt radix (+ exp ex))))))]
[else #f]))]))
(define (parse-decimal-no-digits x n i pos? radix exact?)
(cond
[(fx= i n) #f]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-decimal x n (fxadd1 i) pos? radix exact? d -1))]
[else #f]))]))
(define (parse-integer x n i pos? radix exact? ac)
(define (parse-denom-start x n i radix)
(define (parse-denom x n i radix ac)
(cond
[(fx= n i) ac]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-denom x n (fxadd1 i) radix
(+ (* radix ac) d)))]
[else #f]))]))
(cond
[(fx= n i) #f]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-denom x n (fxadd1 i) radix d))]
[else #f]))]))
(cond
[(fx= i n)
(let ([ac (exact-conv exact? ac)])
(if pos? ac (- ac)))]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-integer x n (fxadd1 i) pos? radix exact? (+ (* ac radix) d)))]
[(char=? c #\.)
(parse-decimal x n (fxadd1 i) pos? radix exact? ac 0)]
[(char=? c #\/)
(let ([denom (parse-denom-start x n (fxadd1 i) radix)])
(and denom
(not (= denom 0))
(let ([ac (exact-conv exact? ac)])
(/ (if pos? ac (- ac)) denom))))]
[(memv c '(#\e #\E))
(let ([ex (parse-exponent-start x n (fxadd1 i) radix)])
(and ex
(let ([ac (exact-conv (or exact? 'i) ac)])
(* (if pos? ac (- ac)) (expt radix ex)))))]
[else #f]))]))
(define (parse-integer-no-digits x n i pos? radix exact?)
(cond
[(fx= i n) #f]
[else
(let ([c (string-ref x i)])
(cond
[(convert-char c radix) =>
(lambda (d)
(parse-integer x n (fxadd1 i) pos? radix exact? d))]
[(char=? c #\.)
(parse-decimal-no-digits x n (fxadd1 i) pos? radix exact?)]
[else #f]))]))
(define (exact-conv exact? x)
(and x (if (eq? exact? 'i) (exact->inexact x) x)))
(define (start x n i exact? radix?)
(cond
[(fx= i n) #f]
[else
(let ([c (string-ref x i)])
(cond
[(char=? c #\-)
(parse-integer-no-digits x n (fxadd1 i) #f (or radix? 10) exact?)]
[(char=? c #\+)
(parse-integer-no-digits x n (fxadd1 i) #t (or radix? 10) exact?)]
[(char=? c #\#)
(let ([i (fxadd1 i)])
(cond
[(fx= i n) #f]
[else
(let ([c (string-ref x i)])
(case c
[(#\x #\X)
(and (not radix?) (start x n (fxadd1 i) exact? 16))]
[(#\b #\B)
(and (not radix?) (start x n (fxadd1 i) exact? 2))]
[(#\o #\O)
(and (not radix?) (start x n (fxadd1 i) exact? 8))]
[(#\d #\D)
(and (not radix?) (start x n (fxadd1 i) exact? 10))]
[(#\e #\E)
(and (not exact?) (start x n (fxadd1 i) 'e radix?))]
[(#\i #\I)
(and (not exact?) (start x n (fxadd1 i) 'i radix?))]
[else #f]))]))]
[(char=? c #\.)
(parse-decimal-no-digits x n (fxadd1 i) #t (or radix? 10) exact?)]
[(convert-char c (or radix? 10)) =>
(lambda (d)
(parse-integer x n (fxadd1 i) #t (or radix? 10) exact? d))]
[else #f]))]))
;;;
(unless (string? x)
(error 'string->number "~s is not a string" x))
(let ([n (string-length x)])
(cond
[(fx= n (string-length "+xxx.0"))
(cond
[(string=? x "+inf.0") +inf.0]
[(string=? x "-inf.0") -inf.0]
[(string=? x "+nan.0") +nan.0]
[(string=? x "-nan.0") -nan.0]
[else (start x n 0 #f #f)])]
[(fx> n 0) (start x n 0 #f #f)]
[else #f]))))
(define (random n)
(if (fixnum? n)
(if (fx> n 1)
(foreign-call "ikrt_fxrandom" n)
(if (fx= n 1)
0
(error 'random "incorrect argument ~s" n)))
(error 'random "~s is not a fixnum" n)))
(define (sra n m)
(unless (fixnum? m)
(error 'sra "shift amount ~s is not a fixnum"))
(cond
[(fixnum? n)
(cond
[($fx>= m 0) ($fxsra n m)]
[else (error 'sra "offset ~s must be non-negative" m)])]
[(bignum? n)
(cond
[($fx> m 0)
(foreign-call "ikrt_bignum_shift_right" n m)]
[($fx= m 0) n]
[else (error 'sra "offset ~s must be non-negative" m)])]
[else (error 'sra "~s is not an exact integer" n)]))
(define (sll n m)
(unless (fixnum? m)
(error 'sll "shift amount ~s is not a fixnum"))
(cond
[(fixnum? n)
(cond
[($fx> m 0)
(foreign-call "ikrt_fixnum_shift_left" n m)]
[($fx= m 0) n]
[else (error 'sll "offset ~s must be non-negative" m)])]
[(bignum? n)
(cond
[($fx> m 0)
(foreign-call "ikrt_bignum_shift_left" n m)]
[($fx= m 0) n]
[else (error 'sll "offset ~s must be non-negative" m)])]
[else (error 'sll "~s is not an exact integer" n)]))
)
(library (ikarus flonum-conversion)
(export string->flonum flonum->string)
(import
(ikarus system $bytevectors)
(ikarus system $flonums)
(except (ikarus) flonum->string string->flonum ))
(module (flonum->string)
(module (flonum->digits)
(define flonum->digits
(lambda (f e min-e p b B)
;;; flonum v = f * b^e
;;; p = precision (p >= 1)
(let ([round? (even? f)])
(if (>= e 0)
(if (not (= f (expt b (- p 1))))
(let ([be (expt b e)])
(scale (* f be 2) 2 be be 0 B round? f e))
(let* ([be (expt b e)] [be1 (* be b)])
(scale (* f be1 2) (* b 2) be1 be 0 B round? f e)))
(if (or (= e min-e) (not (= f (expt b (- p 1)))))
(scale (* f 2) (* (expt b (- e)) 2) 1 1 0 B round? f e)
(scale (* f b 2) (* (expt b (- 1 e)) 2) b 1 0 B round? f e))))))
(define (len n)
(let f ([n n] [i 0])
(cond
[(zero? n) i]
[else (f (quotient n 2) (+ i 1))])))
(define scale
(lambda (r s m+ m- k B round? f e)
(let ([est (inexact->exact
(ceiling
(- (* (+ e (len f) -1) (invlog2of B))
1e-10)))])
(if (>= est 0)
(fixup r (* s (exptt B est)) m+ m- est B round?)
(let ([scale (exptt B (- est))])
(fixup (* r scale) s (* m+ scale) (* m- scale) est B round?))))))
(define fixup
(lambda (r s m+ m- k B round?)
(if ((if round? >= >) (+ r m+) s) ; too low?
(values (+ k 1) (generate r s m+ m- B round?))
(values k (generate (* r B) s (* m+ B) (* m- B) B round?)))))
(define (chr x)
(vector-ref '#(#\0 #\1 #\2 #\3 #\4 #\5 #\6 #\7 #\8 #\9) x))
(define generate
(lambda (r s m+ m- B round?)
(let-values ([(q r) (quotient+remainder r s)])
(let ([tc1 ((if round? <= <) r m-)]
[tc2 ((if round? >= >) (+ r m+) s)])
(if (not tc1)
(if (not tc2)
(cons (chr q) (generate (* r B) s (* m+ B) (* m- B) B round?))
(list (chr (+ q 1))))
(if (not tc2)
(list (chr q))
(if (< (* r 2) s)
(list (chr q))
(list (chr (+ q 1))))))))))
(define invlog2of
(let ([table (make-vector 37)]
[log2 (log 2)])
(do ([B 2 (+ B 1)])
((= B 37))
(vector-set! table B (/ log2 (log B))))
(lambda (B)
(if (<= 2 B 36)
(vector-ref table B)
(/ log2 (log B))))))
(define exptt
(let ([table (make-vector 326)])
(do ([k 0 (+ k 1)] [v 1 (* v 10)])
((= k 326))
(vector-set! table k v))
(lambda (B k)
(if (and (= B 10) (<= 0 k 325))
(vector-ref table k)
(expt B k))))))
(define (format-flonum pos? expt digits)
(define (next x)
(if (null? x)
(values #\0 '())
(values (car x) (cdr x))))
(define (format-flonum-no-expt expt d0 d*)
(cond
[(= expt 1)
(cons d0 (if (null? d*) '(#\. #\0) (cons #\. d*)))]
[else
(cons d0
(let-values ([(d0 d*) (next d*)])
(format-flonum-no-expt (- expt 1) d0 d*)))]))
(define (format-flonum-no-expt/neg expt d*)
(cond
[(= expt 0) d*]
[else (cons #\0 (format-flonum-no-expt/neg (+ expt 1) d*))]))
(define (sign pos? ls)
(if pos?
(list->string ls)
(list->string (cons #\- ls))))
(let ([d0 (car digits)] [d* (cdr digits)])
(cond
[(null? d*)
(if (char=? d0 #\0)
(if pos? "0.0" "-0.0")
(if (= expt 1)
(if pos?
(string d0 #\. #\0)
(string #\- d0 #\. #\0))
(if (= expt 0)
(if pos?
(string #\0 #\. d0)
(string #\- #\0 #\. d0))
(string-append
(if pos? "" "-")
(string d0) "e" (fixnum->string (- expt 1))))))]
[(and (null? d*) (char=? d0 #\0)) (if pos? "0.0" "-0.0")]
[(<= 1 expt 9)
(sign pos? (format-flonum-no-expt expt d0 d*))]
[(<= -3 expt 0)
(sign pos? (cons* #\0 #\. (format-flonum-no-expt/neg expt digits)))]
[else
(string-append
(if pos? "" "-")
(string d0) "." (list->string d*)
"e" (fixnum->string (- expt 1)))])))
(define (flo->string pos? m e p)
; (printf "compo: ~s ~s ~s\n" m e p)
(let-values ([(expt digits) (flonum->digits m e 10 p 2 10)])
(format-flonum pos? expt digits)))
(define (flonum->string x)
(let-values ([(pos? be m) (flonum-parts x)])
(cond
[(<= 1 be 2046) ; normalized flonum
(flo->string pos? (+ m (expt 2 52)) (- be 1075) 53)]
[(= be 0)
(flo->string pos? m -1074 52)]
[(= be 2047)
(if (= m 0)
(if pos? "+inf.0" "-inf.0")
;;; Gee! nans have no sign!
"+nan.0")]
[else (error 'flonum->string "cannot happen")]))))
;;;
(define (string->flonum x)
(cond
[(string? x)
(foreign-call "ikrt_bytevector_to_flonum"
(string->utf8-bytevector x))]
[else
(error 'string->flonum "~s is not a string" x)])) )
(library (ikarus rationalize)
(export rationalize)
(import
(except (ikarus) rationalize))
(define (rationalize x eps)
(define who 'rationalize)
(define (simplest x y)
(cond
[(< y x) (simplest y x)]
[(= x y) x]
[(> x 0)
(let ([n (numerator x)] [d (denominator x)]
[n^ (numerator y)] [d^ (denominator y)])
(simplest^ n d n^ d^))]
[(< y 0)
(let ([n (numerator x)] [d (denominator x)]
[n^ (numerator y)] [d^ (denominator y)])
(- (simplest^ (- n^) d^ (- n) d)))]
[else 1]))
(define (simplest^ n d n^ d^)
(let-values ([(q r) (quotient+remainder n d)])
(if (= r 0)
q
(let-values ([(q^ r^) (quotient+remainder n^ d^)])
(if (= q q^)
(let ([v (simplest^ d^ r^ d r)])
(let ([n^^ (numerator v)] [d^^ (denominator v)])
(/ (+ (* q n^^) d^^) n^^)))
(+ q 1))))))
(define (go x eps)
(simplest (- x eps) (+ x eps)))
(cond
[(flonum? x)
(if (flfinite? x)
(cond
[(flonum? eps)
(if (flfinite? eps) (go x eps) +nan.0)]
[(or (fixnum? eps) (bignum? eps) (ratnum? eps))
(go x eps)]
[else (error who "~s is not a number" eps)])
(cond
[(flonum? eps)
(if (flfinite? eps) x +nan.0)]
[(or (fixnum? eps) (bignum? eps) (ratnum? eps))
x]
[else (error who "~s is not a number" eps)]))]
[(or (fixnum? x) (bignum? x) (ratnum? x))
(cond
[(flonum? eps)
(if (flfinite? eps) (go x eps) +nan.0)]
[(or (fixnum? eps) (bignum? eps) (ratnum? eps))
(go x eps)]
[else (error who "~s is not a number" eps)])]
[else (error who "~s is not a number" x)])))
(library (ikarus r6rs-fu div/mod)
(export div mod div-and-mod div0 mod0 div0-and-mod0)
(import
(except (ikarus)
div mod div-and-mod div0 mod0 div0-and-mod0))
(define (div-and-mod x y)
(define who 'div-and-mod)
(unless (integer? x)
(error who "~s is not an integer" x))
(unless (and (integer? y) (not (= y 0)))
(error who "~s is not an integer" y))
(if (> x 0)
(quotient+remainder x y)
(if (> y 0)
(let-values ([(q r) (quotient+remainder (- x y) y)])
(values q (+ r y)))
(let-values ([(q r) (quotient+remainder (+ x y) y)])
(values q (- r y))))))
(define (div x y)
(let-values ([(n m) (div-and-mod x y)])
n))
(define (mod x y)
(let-values ([(n m) (div-and-mod x y)])
m))
(define (div0-and-mod0 x y)
(define who 'div0-and-mod0)
(unless (integer? x)
(error who "~s is not an integer" x))
(unless (and (integer? y) (not (= y 0)))
(error who "~s is not an integer" y))
(let-values ([(d m) (div-and-mod x y)])
(if (> y 0)
(if (< m (/ y 2))
(values d m)
(values (+ d 1) (- m y)))
(if (> m (/ y -2))
(values (- d 1) (+ m y))
(values d m)))))
(define (div0 x y)
(let-values ([(n m) (div0-and-mod0 x y)])
n))
(define (mod0 x y)
(let-values ([(n m) (div0-and-mod0 x y)])
m)))
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