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1 // Copyright 2009 The Go Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style
3 // license that can be found in the LICENSE file.
5 // Multiprecision decimal numbers.
6 // For floating-point formatting only; not general purpose.
7 // Only operations are assign and (binary) left/right shift.
8 // Can do binary floating point in multiprecision decimal precisely
9 // because 2 divides 10; cannot do decimal floating point
10 // in multiprecision binary precisely.
12 package strconv
20 }
26 }
29 }
38 // zeros fill space between decimal point and digits
40 w++
42 w++
47 // decimal point in middle of digits
50 w++
54 // zeros fill space between digits and decimal point
57 }
59 }
64 }
66 }
68 // trim trailing zeros from number.
69 // (They are meaningless; the decimal point is tracked
70 // independent of the number of digits.)
74 }
77 }
78 }
80 // Assign v to a.
84 // Write reversed decimal in buf.
90 n++
91 v = v1
92 }
94 // Reverse again to produce forward decimal in a.d.
99 }
102 }
104 // Maximum shift that we can do in one pass without overflow.
105 // A uint has 32 or 64 bits, and we have to be able to accommodate 9<<k.
109 // Binary shift right (/ 2) by k bits. k <= maxShift to avoid overflow.
114 // Pick up enough leading digits to cover first shift.
119 // a == 0; shouldn't get here, but handle anyway.
121 return
122 }
125 r++
126 }
127 break
128 }
131 }
136 // Pick up a digit, put down a digit.
140 n &= mask
142 w++
144 }
146 // Put down extra digits.
149 n &= mask
152 w++
155 }
157 }
161 }
163 // Cheat sheet for left shift: table indexed by shift count giving
164 // number of new digits that will be introduced by that shift.
165 //
166 // For example, leftcheats[4] = {2, "625"}. That means that
167 // if we are shifting by 4 (multiplying by 16), it will add 2 digits
168 // when the string prefix is "625" through "999", and one fewer digit
169 // if the string prefix is "000" through "624".
170 //
171 // Credit for this trick goes to Ken.
176 }
179 // Leading digits of 1/2^i = 5^i.
180 // 5^23 is not an exact 64-bit floating point number,
181 // so have to use bc for the math.
182 // Go up to 60 to be large enough for 32bit and 64bit platforms.
183 /*
184 seq 60 | sed 's/^/5^/' | bc |
185 awk 'BEGIN{ print "\t{ 0, \"\" }," }
186 {
187 log2 = log(2)/log(10)
188 printf("\t{ %d, \"%s\" },\t// * %d\n",
189 int(log2*NR+1), $0, 2**NR)
190 }'
191 */
253 }
255 // Is the leading prefix of b lexicographically less than s?
260 }
263 }
264 }
266 }
268 // Binary shift left (* 2) by k bits. k <= maxShift to avoid overflow.
272 delta--
273 }
278 // Pick up a digit, put down a digit.
284 w--
289 }
290 n = quo
291 }
293 // Put down extra digits.
297 w--
302 }
303 n = quo
304 }
309 }
312 }
314 // Binary shift left (k > 0) or right (k < 0).
318 // nothing to do: a == 0
322 k -= maxShift
323 }
328 k += maxShift
329 }
331 }
332 }
334 // If we chop a at nd digits, should we round up?
338 }
340 // if we truncated, a little higher than what's recorded - always round up
343 }
345 }
346 // not halfway - digit tells all
348 }
350 // Round a to nd digits (or fewer).
351 // If nd is zero, it means we're rounding
352 // just to the left of the digits, as in
353 // 0.09 -> 0.1.
356 return
357 }
362 }
363 }
365 // Round a down to nd digits (or fewer).
368 return
369 }
372 }
374 // Round a up to nd digits (or fewer).
377 return
378 }
380 // round up
386 return
387 }
388 }
390 // Number is all 9s.
391 // Change to single 1 with adjusted decimal point.
395 }
397 // Extract integer part, rounded appropriately.
398 // No guarantees about overflow.
402 }
407 }
410 }
412 n++
413 }
414 return n
415 }