ikarus/benchmarks.larceny/prefix/prefix-larceny.scm

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;INSERTCODE
;------------------------------------------------------------------------------
(error-handler
(lambda l
(display "bench DIED!") (newline) (exit 118)))
(define (run-bench name count ok? run)
(let loop ((i 0) (result (list 'undefined)))
(if (< i count)
(loop (+ i 1) (run))
result)))
(define (run-benchmark name count ok? run-maker . args)
(newline)
(let* ((run (apply run-maker args))
(result (time (run-bench name count ok? run))))
(if (not (ok? result))
(begin
(display "*** wrong result ***")
(newline)
(display "*** got: ")
(write result)
(newline))))
(exit 0))
(define (fatal-error . args)
(apply error #f args))
(define (call-with-output-file/truncate filename proc)
(call-with-output-file filename proc))
; Bitwise operations on exact integers.
; From the draft reference implementation of R6RS generic arithmetic.
(define (bitwise-or i j)
(if (and (exact? i)
(integer? i)
(exact? j)
(integer? j))
(cond ((or (= i -1) (= j -1))
-1)
((= i 0)
j)
((= j 0)
i)
(else
(let* ((i0 (if (odd? i) 1 0))
(j0 (if (odd? j) 1 0))
(i1 (- i i0))
(j1 (- j j0))
(i/2 (quotient i1 2))
(j/2 (quotient j1 2))
(hi (* 2 (bitwise-or i/2 j/2)))
(lo (if (= 0 (+ i0 j0)) 0 1)))
(+ hi lo))))
(error "illegal argument to bitwise-or" i j)))
(define (bitwise-and i j)
(if (and (exact? i)
(integer? i)
(exact? j)
(integer? j))
(cond ((or (= i 0) (= j 0))
0)
((= i -1)
j)
((= j -1)
i)
(else
(let* ((i0 (if (odd? i) 1 0))
(j0 (if (odd? j) 1 0))
(i1 (- i i0))
(j1 (- j j0))
(i/2 (quotient i1 2))
(j/2 (quotient j1 2))
(hi (* 2 (bitwise-and i/2 j/2)))
(lo (* i0 j0)))
(+ hi lo))))
(error "illegal argument to bitwise-and" i j)))
(define (bitwise-not i)
(if (and (exact? i)
(integer? i))
(cond ((= i -1)
0)
((= i 0)
-1)
(else
(let* ((i0 (if (odd? i) 1 0))
(i1 (- i i0))
(i/2 (quotient i1 2))
(hi (* 2 (bitwise-not i/2)))
(lo (- 1 i0)))
(+ hi lo))))
(error "illegal argument to bitwise-not" i j)))
;------------------------------------------------------------------------------
; Macros...
(if-fixflo
(begin
; Specialize fixnum and flonum arithmetic.
(define-syntax FLOATvector-const
(syntax-rules ()
((FLOATvector-const x ...) '#(x ...))))
(define-syntax FLOATvector?
(syntax-rules ()
((FLOATvector? x) (vector? x))))
(define-syntax FLOATvector
(syntax-rules ()
((FLOATvector x ...) (vector x ...))))
(define-syntax FLOATmake-vector
(syntax-rules ()
((FLOATmake-vector n) (make-vector n 0.0))
((FLOATmake-vector n init) (make-vector n init))))
(define-syntax FLOATvector-ref
(syntax-rules ()
((FLOATvector-ref v i) (vector-ref v i))))
(define-syntax FLOATvector-set!
(syntax-rules ()
((FLOATvector-set! v i x) (vector-set! v i x))))
(define-syntax FLOATvector-length
(syntax-rules ()
((FLOATvector-length v) (vector-length v))))
(define-syntax nuc-const
(syntax-rules ()
((FLOATnuc-const x ...) '#(x ...))))
(define-syntax FLOAT+
(syntax-rules ()
((FLOAT+ x ...) (fl+ x ...))))
(define-syntax FLOAT-
(syntax-rules ()
((FLOAT- x ...) (fl- x ...))))
(define-syntax FLOAT*
(syntax-rules ()
((FLOAT* x ...) (fl* x ...))))
(define-syntax FLOAT/
(syntax-rules ()
((FLOAT/ x ...) (/ x ...)))) ; FIXME
(define-syntax FLOAT=
(syntax-rules ()
((FLOAT= x y) (fl= x y))))
(define-syntax FLOAT<
(syntax-rules ()
((FLOAT< x y) (fl< x y))))
(define-syntax FLOAT<=
(syntax-rules ()
((FLOAT<= x y) (fl<= x y))))
(define-syntax FLOAT>
(syntax-rules ()
((FLOAT> x y) (fl> x y))))
(define-syntax FLOAT>=
(syntax-rules ()
((FLOAT>= x y) (fl>= x y))))
(define-syntax FLOATnegative?
(syntax-rules ()
((FLOATnegative? x) (fl< x 0.0))))
(define-syntax FLOATpositive?
(syntax-rules ()
((FLOATpositive? x) (fl< 0.0 x))))
(define-syntax FLOATzero?
(syntax-rules ()
((FLOATzero? x) (fl= 0.0 x))))
(define-syntax FLOATabs
(syntax-rules ()
((FLOATabs x) (abs x)))) ; FIXME
(define-syntax FLOATsin
(syntax-rules ()
((FLOATsin x) (sin x)))) ; FIXME
(define-syntax FLOATcos
(syntax-rules ()
((FLOATcos x) (cos x)))) ; FIXME
(define-syntax FLOATatan
(syntax-rules ()
((FLOATatan x) (atan x)))) ; FIXME
(define-syntax FLOATsqrt
(syntax-rules ()
((FLOATsqrt x) (sqrt x)))) ; FIXME
(define-syntax FLOATmin
(syntax-rules ()
((FLOATmin x y) (min x y)))) ; FIXME
(define-syntax FLOATmax
(syntax-rules ()
((FLOATmax x y) (max x y)))) ; FIXME
(define-syntax FLOATround
(syntax-rules ()
((FLOATround x) (round x)))) ; FIXME
(define-syntax FLOATinexact->exact
(syntax-rules ()
((FLOATinexact->exact x) (inexact->exact x))))
(define (GENERIC+ x y) (+ x y))
(define (GENERIC- x y) (- x y))
(define (GENERIC* x y) (* x y))
(define (GENERIC/ x y) (/ x y))
(define (GENERICquotient x y) (quotient x y))
(define (GENERICremainder x y) (remainder x y))
(define (GENERICmodulo x y) (modulo x y))
(define (GENERIC= x y) (= x y))
(define (GENERIC< x y) (< x y))
(define (GENERIC<= x y) (<= x y))
(define (GENERIC> x y) (> x y))
(define (GENERIC>= x y) (>= x y))
(define (GENERICexpt x y) (expt x y))
(define-syntax +
(syntax-rules ()
((+ x ...) (fx+ x ...))))
(define-syntax -
(syntax-rules ()
((- x ...) (fx- x ...))))
(define-syntax *
(syntax-rules ()
((* x ...) (fx* x ...))))
;(define-syntax quotient
; (syntax-rules ()
; ((quotient x ...) (quotient x ...)))) ; FIXME
;(define-syntax modulo
; (syntax-rules ()
; ((modulo x ...) (modulo x ...)))) ; FIXME
;(define-syntax remainder
; (syntax-rules ()
; ((remainder x ...) (remainder x ...)))) ; FIXME
(define-syntax =
(syntax-rules ()
((= x y) (fx= x y))))
(define-syntax <
(syntax-rules ()
((< x y) (fx< x y))))
(define-syntax <=
(syntax-rules ()
((<= x y) (fx<= x y))))
(define-syntax >
(syntax-rules ()
((> x y) (fx> x y))))
(define-syntax >=
(syntax-rules ()
((>= x y) (fx>= x y))))
(define-syntax negative?
(syntax-rules ()
((negative? x) (fxnegative? x))))
(define-syntax positive?
(syntax-rules ()
((positive? x) (fxpositive? x))))
(define-syntax zero?
(syntax-rules ()
((zero? x) (fxzero? x))))
;(define-syntax odd?
; (syntax-rules ()
; ((odd? x) (odd? x)))) ; FIXME
;(define-syntax even?
; (syntax-rules ()
; ((even? x) (even? x)))) ; FIXME
(define-syntax bitwise-or
(syntax-rules ()
((bitwise-or x y) (fxlogior x y))))
(define-syntax bitwise-and
(syntax-rules ()
((bitwise-and x y) (fxlogand x y))))
(define-syntax bitwise-not
(syntax-rules ()
((bitwise-not x) (fxlognot x))))
)
(begin
; Don't specialize fixnum and flonum arithmetic.
(define-syntax FLOATvector-const
(syntax-rules ()
((FLOATvector-const x ...) '#(x ...))))
(define-syntax FLOATvector?
(syntax-rules ()
((FLOATvector? x) (vector? x))))
(define-syntax FLOATvector
(syntax-rules ()
((FLOATvector x ...) (vector x ...))))
(define-syntax FLOATmake-vector
(syntax-rules ()
((FLOATmake-vector n) (make-vector n 0.0))
((FLOATmake-vector n init) (make-vector n init))))
(define-syntax FLOATvector-ref
(syntax-rules ()
((FLOATvector-ref v i) (vector-ref v i))))
(define-syntax FLOATvector-set!
(syntax-rules ()
((FLOATvector-set! v i x) (vector-set! v i x))))
(define-syntax FLOATvector-length
(syntax-rules ()
((FLOATvector-length v) (vector-length v))))
(define-syntax nuc-const
(syntax-rules ()
((FLOATnuc-const x ...) '#(x ...))))
(define-syntax FLOAT+
(syntax-rules ()
((FLOAT+ x ...) (+ x ...))))
(define-syntax FLOAT-
(syntax-rules ()
((FLOAT- x ...) (- x ...))))
(define-syntax FLOAT*
(syntax-rules ()
((FLOAT* x ...) (* x ...))))
(define-syntax FLOAT/
(syntax-rules ()
((FLOAT/ x ...) (/ x ...))))
(define-syntax FLOAT=
(syntax-rules ()
((FLOAT= x y) (= x y))))
(define-syntax FLOAT<
(syntax-rules ()
((FLOAT< x y) (< x y))))
(define-syntax FLOAT<=
(syntax-rules ()
((FLOAT<= x y) (<= x y))))
(define-syntax FLOAT>
(syntax-rules ()
((FLOAT> x y) (> x y))))
(define-syntax FLOAT>=
(syntax-rules ()
((FLOAT>= x y) (>= x y))))
(define-syntax FLOATnegative?
(syntax-rules ()
((FLOATnegative? x) (negative? x))))
(define-syntax FLOATpositive?
(syntax-rules ()
((FLOATpositive? x) (positive? x))))
(define-syntax FLOATzero?
(syntax-rules ()
((FLOATzero? x) (zero? x))))
(define-syntax FLOATabs
(syntax-rules ()
((FLOATabs x) (abs x))))
(define-syntax FLOATsin
(syntax-rules ()
((FLOATsin x) (sin x))))
(define-syntax FLOATcos
(syntax-rules ()
((FLOATcos x) (cos x))))
(define-syntax FLOATatan
(syntax-rules ()
((FLOATatan x) (atan x))))
(define-syntax FLOATsqrt
(syntax-rules ()
((FLOATsqrt x) (sqrt x))))
(define-syntax FLOATmin
(syntax-rules ()
((FLOATmin x y) (min x y))))
(define-syntax FLOATmax
(syntax-rules ()
((FLOATmax x y) (max x y))))
(define-syntax FLOATround
(syntax-rules ()
((FLOATround x) (round x))))
(define-syntax FLOATinexact->exact
(syntax-rules ()
((FLOATinexact->exact x) (inexact->exact x))))
; Generic arithmetic.
(define-syntax GENERIC+
(syntax-rules ()
((GENERIC+ x ...) (+ x ...))))
(define-syntax GENERIC-
(syntax-rules ()
((GENERIC- x ...) (- x ...))))
(define-syntax GENERIC*
(syntax-rules ()
((GENERIC* x ...) (* x ...))))
(define-syntax GENERIC/
(syntax-rules ()
((GENERIC/ x ...) (/ x ...))))
(define-syntax GENERICquotient
(syntax-rules ()
((GENERICquotient x y) (quotient x y))))
(define-syntax GENERICremainder
(syntax-rules ()
((GENERICremainder x y) (remainder x y))))
(define-syntax GENERICmodulo
(syntax-rules ()
((GENERICmodulo x y) (modulo x y))))
(define-syntax GENERIC=
(syntax-rules ()
((GENERIC= x y) (= x y))))
(define-syntax GENERIC<
(syntax-rules ()
((GENERIC< x y) (< x y))))
(define-syntax GENERIC<=
(syntax-rules ()
((GENERIC<= x y) (<= x y))))
(define-syntax GENERIC>
(syntax-rules ()
((GENERIC> x y) (> x y))))
(define-syntax GENERIC>=
(syntax-rules ()
((GENERIC>= x y) (>= x y))))
(define-syntax GENERICexpt
(syntax-rules ()
((GENERICexpt x y) (expt x y))))
)
)
;------------------------------------------------------------------------------