1;; Copyright 2010 the V8 project authors. All rights reserved.
2;; Redistribution and use in source and binary forms, with or without
3;; modification, are permitted provided that the following conditions are
4;; met:
5;;
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8;;     * Redistributions in binary form must reproduce the above
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15;;
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20;; OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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22;; LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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27
28;; This is a Scheme script for the Bigloo compiler. Bigloo must be compiled with
29;; support for bignums. The compilation of the script can be done as follows:
30;;   bigloo -static-bigloo -o generate-ten-powers generate-ten-powers.scm
31;;
32;; Generate approximations of 10^k.
33
34(module gen-ten-powers
35   (static (class Cached-Fast
36	      v::bignum
37	      e::bint
38	      exact?::bool))
39   (main my-main))
40
41
42;;----------------bignum shifts -----------------------------------------------
43(define (bit-lshbx::bignum x::bignum by::bint)
44   (if ( by 0)
45       #z0
46       (*bx x (exptbx #z2 (fixnum->bignum by)))))
47
48(define (bit-rshbx::bignum x::bignum by::bint)
49   (if ( by 0)
50       #z0
51       (/bx x (exptbx #z2 (fixnum->bignum by)))))
52
53;;----------------the actual power generation -------------------------------
54
55;; e should be an indication. it might be too small.
56(define (round-n-cut n e nb-bits)
57   (define max-container (- (bit-lshbx #z1 nb-bits) 1))
58   (define (round n)
59      (case *round*
60	 ((down) n)
61	 ((up)
62	  (+bx n
63	       ;; with the -1 it will only round up if the cut off part is
64	       ;; non-zero
65	       (-bx (bit-lshbx #z1
66			       (-fx (+fx e nb-bits) 1))
67		    #z1)))
68	 ((round)
69	  (+bx n
70	       (bit-lshbx #z1
71			  (-fx (+fx e nb-bits) 2))))))
72   (let* ((shift (-fx (+fx e nb-bits) 1))
73	  (cut (bit-rshbx (round n) shift))
74	  (exact? (=bx n (bit-lshbx cut shift))))
75      (if (<=bx cut max-container)
76	  (values cut e exact?)
77	  (round-n-cut n (+fx e 1) nb-bits))))
78
79(define (rounded-/bx x y)
80   (case *round*
81      ((down)  (/bx x y))
82      ((up)    (+bx (/bx x y) #z1))
83      ((round) (let ((tmp (/bx (*bx #z2 x) y)))
84		  (if (zerobx? (remainderbx tmp #z2))
85		      (/bx tmp #z2)
86		      (+bx (/bx tmp #z2) #z1))))))
87
88(define (generate-powers from to mantissa-size)
89   (let* ((nb-bits mantissa-size)
90	  (offset (- from))
91	  (nb-elements (+ (- from) to 1))
92	  (vec (make-vector nb-elements))
93	  (max-container (- (bit-lshbx #z1 nb-bits) 1)))
94      ;; the negative ones. 10^-1, 10^-2, etc.
95      ;; We already know, that we can't be exact, so exact? will always be #f.
96      ;; Basically we will have a ten^i that we will *10 at each iteration. We
97      ;; want to create the matissa of 1/ten^i. However the mantissa must be
98      ;; normalized (start with a 1). -> we have to shift the number.
99      ;; We shift by multiplying with two^e. -> We encode two^e*(1/ten^i) ==
100      ;;  two^e/ten^i.
101      (let loop ((i 1)
102		 (ten^i #z10)
103		 (two^e #z1)
104		 (e 0))
105	 (unless (< (- i) from)
106	    (if (>bx (/bx (*bx #z2 two^e) ten^i) max-container)
107		;; another shift would make the number too big. We are
108		;; hence normalized now.
109		(begin
110		   (vector-set! vec (-fx offset i)
111				(instantiate::Cached-Fast
112				   (v (rounded-/bx two^e ten^i))
113				   (e (negfx e))
114				   (exact? #f)))
115		   (loop (+fx i 1) (*bx ten^i #z10) two^e e))
116		(loop i ten^i (bit-lshbx two^e 1) (+fx e 1)))))
117      ;; the positive ones 10^0, 10^1, etc.
118      ;; start with 1.0. mantissa: 10...0 (1 followed by nb-bits-1 bits)
119      ;;      -> e = -(nb-bits-1)
120      ;; exact? is true when the container can still hold the complete 10^i
121      (let loop ((i 0)
122		 (n (bit-lshbx #z1 (-fx nb-bits 1)))
123		 (e (-fx 1 nb-bits)))
124	 (when (<= i to)
125	    (receive (cut e exact?)
126	       (round-n-cut n e nb-bits)
127	       (vector-set! vec (+fx i offset)
128			    (instantiate::Cached-Fast
129			       (v cut)
130			       (e e)
131			       (exact? exact?)))
132	       (loop (+fx i 1) (*bx n #z10) e))))
133      vec))
134
135(define (print-c powers from to struct-type
136		 cache-name max-distance-name offset-name macro64)
137   (define (display-power power k)
138      (with-access::Cached-Fast power (v e exact?)
139	 (let ((tmp-p (open-output-string)))
140	    ;; really hackish way of getting the digits
141	    (display (format "~x" v) tmp-p)
142	    (let ((str (close-output-port tmp-p)))
143	       (printf "  {~a(0x~a, ~a), ~a, ~a},\n"
144		       macro64
145		       (substring str 0 8)
146		       (substring str 8 16)
147		       e
148		       k)))))
149   (define (print-powers-reduced n)
150      (print "static const " struct-type " " cache-name
151	     "(" n ")"
152	     "[] = {")
153      (let loop ((i 0)
154		 (nb-elements 0)
155		 (last-e 0)
156		 (max-distance 0))
157	 (cond
158	    ((>= i (vector-length powers))
159	     (print "  };")
160	     (print "static const int " max-distance-name "(" n ") = "
161		 max-distance ";")
162	     (print "// nb elements (" n "): " nb-elements))
163	    (else
164	     (let* ((power (vector-ref powers i))
165		    (e (Cached-Fast-e power)))
166	     (display-power power (+ i from))
167	     (loop (+ i n)
168		   (+ nb-elements 1)
169		   e
170		   (cond
171		      ((=fx i 0) max-distance)
172		      ((> (- e last-e) max-distance) (- e last-e))
173		      (else max-distance))))))))
174   (print "// Copyright 2010 the V8 project authors. All rights reserved.")
175   (print "// ------------ GENERATED FILE ----------------")
176   (print "// command used:")
177   (print "// "
178	  (apply string-append (map (lambda (str)
179				       (string-append " " str))
180				    *main-args*))
181	  "  // NOLINT")
182   (print)
183   (print
184    "// This file is intended to be included inside another .h or .cc files\n"
185    "// with the following defines set:\n"
186    "//  GRISU_CACHE_STRUCT: should expand to the name of a struct that will\n"
187    "//   hold the cached powers of ten. Each entry will hold a 64-bit\n"
188    "//   significand, a 16-bit signed binary exponent, and a 16-bit\n"
189    "//   signed decimal exponent. Each entry will be constructed as follows:\n"
190    "//      { significand, binary_exponent, decimal_exponent }.\n"
191    "//  GRISU_CACHE_NAME(i): generates the name for the different caches.\n"
192    "//   The parameter i will be a number in the range 1-20. A cache will\n"
193    "//   hold every i'th element of a full cache. GRISU_CACHE_NAME(1) will\n"
194    "//   thus hold all elements. The higher i the fewer elements it has.\n"
195    "//   Ideally the user should only reference one cache and let the\n"
196    "//   compiler remove the unused ones.\n"
197    "//  GRISU_CACHE_MAX_DISTANCE(i): generates the name for the maximum\n"
198    "//   binary exponent distance between all elements of a given cache.\n"
199    "//  GRISU_CACHE_OFFSET: is used as variable name for the decimal\n"
200    "//   exponent offset. It is equal to -cache[0].decimal_exponent.\n"
201    "//  GRISU_UINT64_C: used to construct 64-bit values in a platform\n"
202    "//   independent way. In order to encode 0x123456789ABCDEF0 the macro\n"
203    "//   will be invoked as follows: GRISU_UINT64_C(0x12345678,9ABCDEF0).\n")
204   (print)
205   (print-powers-reduced 1)
206   (print-powers-reduced 2)
207   (print-powers-reduced 3)
208   (print-powers-reduced 4)
209   (print-powers-reduced 5)
210   (print-powers-reduced 6)
211   (print-powers-reduced 7)
212   (print-powers-reduced 8)
213   (print-powers-reduced 9)
214   (print-powers-reduced 10)
215   (print-powers-reduced 11)
216   (print-powers-reduced 12)
217   (print-powers-reduced 13)
218   (print-powers-reduced 14)
219   (print-powers-reduced 15)
220   (print-powers-reduced 16)
221   (print-powers-reduced 17)
222   (print-powers-reduced 18)
223   (print-powers-reduced 19)
224   (print-powers-reduced 20)
225   (print "static const int GRISU_CACHE_OFFSET = " (- from) ";"))
226
227;;----------------main --------------------------------------------------------
228(define *main-args* #f)
229(define *mantissa-size* #f)
230(define *dest* #f)
231(define *round* #f)
232(define *from* #f)
233(define *to* #f)
234
235(define (my-main args)
236   (set! *main-args* args)
237   (args-parse (cdr args)
238      (section "Help")
239      (("?") (args-parse-usage #f))
240      ((("-h" "--help") (help "?, -h, --help" "This help message"))
241       (args-parse-usage #f))
242      (section "Misc")
243      (("-o" ?file (help "The output file"))
244       (set! *dest* file))
245      (("--mantissa-size" ?size (help "Container-size in bits"))
246       (set! *mantissa-size* (string->number size)))
247      (("--round" ?direction (help "Round bignums (down, round or up)"))
248       (set! *round* (string->symbol direction)))
249      (("--from" ?from (help "start at 10^from"))
250       (set! *from* (string->number from)))
251      (("--to" ?to (help "go up to 10^to"))
252       (set! *to* (string->number to)))
253      (else
254       (print "Illegal argument `" else "'. Usage:")
255       (args-parse-usage #f)))
256   (when (not *from*)
257      (error "generate-ten-powers"
258	     "Missing from"
259	     #f))
260   (when (not *to*)
261      (error "generate-ten-powers"
262	     "Missing to"
263	     #f))
264   (when (not *mantissa-size*)
265      (error "generate-ten-powers"
266	     "Missing mantissa size"
267	     #f))
268   (when (not (memv *round* '(up down round)))
269      (error "generate-ten-powers"
270	     "Missing round-method"
271	     *round*))
272
273   (let ((dividers (generate-powers *from* *to* *mantissa-size*))
274	 (p (if (not *dest*)
275		(current-output-port)
276		(open-output-file *dest*))))
277      (unwind-protect
278	 (with-output-to-port p
279	    (lambda ()
280	       (print-c dividers *from* *to*
281			"GRISU_CACHE_STRUCT" "GRISU_CACHE_NAME"
282			"GRISU_CACHE_MAX_DISTANCE" "GRISU_CACHE_OFFSET"
283			"GRISU_UINT64_C"
284			)))
285	 (if *dest*
286	     (close-output-port p)))))
287