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* ext/bigdecimal/bigdecimal.c: fix rounding algorithms for half-down
and half-even. This change is based on the patch created by Matthew Willson, the reporter of this bug. [Bug #3803] [ruby-core:32136] * test/bigdecimal/test_bigdecimal.rb: add tests for above changes. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@29293 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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3 changed files with 130 additions and 53 deletions
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@ -1,3 +1,11 @@
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Sun Sep 19 05:14:35 2010 Kenta Murata <mrkn@mrkn.jp>
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* ext/bigdecimal/bigdecimal.c: fix rounding algorithms for half-down
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and half-even. This change is based on the patch created by Matthew
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Willson, the reporter of this bug. [Bug #3803] [ruby-core:32136]
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* test/bigdecimal/test_bigdecimal.rb: add tests for above changes.
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Sat Sep 18 20:09:51 2010 Tanaka Akira <akr@fsij.org>
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* ext/pathname/pathname.c (path_each_entry): Pathname#each_entry
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@ -308,9 +308,9 @@ BigDecimal_load(VALUE self, VALUE str)
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*
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* ROUND_UP:: round away from zero
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* ROUND_DOWN:: round towards zero (truncate)
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* ROUND_HALF_UP:: round up if the appropriate digit >= 5, otherwise truncate (default)
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* ROUND_HALF_DOWN:: round up if the appropriate digit >= 6, otherwise truncate
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* ROUND_HALF_EVEN:: round towards the even neighbor (Banker's rounding)
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* ROUND_HALF_UP:: round towards the nearest neighbor, unless both neighbors are equidistant, in which case round away from zero. (default)
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* ROUND_HALF_DOWN:: round towards the nearest neighbor, unless both neighbors are equidistant, in which case round towards zero.
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* ROUND_HALF_EVEN:: round towards the nearest neighbor, unless both neighbors are equidistant, in which case round towards the even neighbor (Banker's rounding)
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* ROUND_CEILING:: round towards positive infinity (ceil)
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* ROUND_FLOOR:: round towards negative infinity (floor)
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*
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@ -4559,8 +4559,9 @@ VpMidRound(Real *y, unsigned short f, ssize_t nf)
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*/
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{
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/* fracf: any positive digit under rounding position? */
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/* fracf_1further: any positive digits under one further than the rounding position? */
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/* exptoadd: number of digits needed to compensate negative nf */
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int fracf;
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int fracf, fracf_1further;
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ssize_t n,i,ix,ioffset, exptoadd;
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BDIGIT v, shifter;
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BDIGIT div;
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@ -4573,62 +4574,111 @@ VpMidRound(Real *y, unsigned short f, ssize_t nf)
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VpSetZero(y,VpGetSign(y)); /* truncate everything */
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return 0;
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}
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exptoadd = -nf;
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nf = 0;
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exptoadd = -nf;
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nf = 0;
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}
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/* ix: x->fraq[ix] contains round position */
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ix = nf / (ssize_t)BASE_FIG;
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if ((size_t)ix >= y->Prec) return 0; /* rounding position too right(small). */
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ioffset = nf - ix*(ssize_t)BASE_FIG;
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v = y->frac[ix];
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/* drop digits after pointed digit */
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ioffset = nf - ix*(ssize_t)BASE_FIG;
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n = (ssize_t)BASE_FIG - ioffset - 1;
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for (shifter=1,i=0; i<n; ++i) shifter *= 10;
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/* so the representation used (in y->frac) is an array of BDIGIT, where
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each BDIGIT contains a value between 0 and BASE-1, consisting of BASE_FIG
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decimal places.
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(that numbers of decimal places are typed as ssize_t is somewhat confusing)
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nf is now position (in decimal places) of the digit from the start of
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the array.
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ix is the position (in BDIGITS) of the BDIGIT containing the decimal digit,
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from the start of the array.
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v is the value of this BDIGIT
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ioffset is the number of extra decimal places along of this decimal digit
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within v.
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n is the number of decimal digits remaining within v after this decimal digit
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shifter is 10**n,
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v % shifter are the remaining digits within v
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v % (shifter * 10) are the digit together with the remaining digits within v
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v / shifter are the digit's predecessors together with the digit
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div = v / shifter / 10 is just the digit's precessors
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(v / shifter) - div*10 is just the digit, which is what v ends up being reassigned to.
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*/
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fracf = (v % (shifter * 10) > 0);
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fracf_1further = ((v % shifter) > 0);
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v /= shifter;
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div = v / 10;
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v = v - div*10;
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if (fracf == 0) {
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for (i=ix+1; (size_t)i < y->Prec; i++) {
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if (y->frac[i] % BASE) {
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fracf = 1;
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break;
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}
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}
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/* now v is just the digit required.
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now fracf is whether the digit or any of the remaining digits within v are non-zero
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now fracf_1further is whether any of the remaining digits within v are non-zero
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*/
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/* now check all the remaining BDIGITS for zero-ness a whole BDIGIT at a time.
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if we spot any non-zeroness, that means that we foudn a positive digit under
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rounding position, and we also found a positive digit under one further than
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the rounding position, so both searches (to see if any such non-zero digit exists)
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can stop */
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for (i=ix+1; (size_t)i < y->Prec; i++) {
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if (y->frac[i] % BASE) {
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fracf = fracf_1further = 1;
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break;
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}
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}
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/* now fracf = does any positive digit exist under the rounding position?
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now fracf_1further = does any positive digit exist under one further than the
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rounding position?
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now v = the first digit under the rounding position */
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/* drop digits after pointed digit */
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memset(y->frac+ix+1, 0, (y->Prec - (ix+1)) * sizeof(BDIGIT));
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switch(f) {
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case VP_ROUND_DOWN: /* Truncate */
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break;
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case VP_ROUND_UP: /* Roundup */
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if (fracf) ++div;
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break;
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case VP_ROUND_HALF_UP: /* Round half up */
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break;
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case VP_ROUND_HALF_UP:
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if (v>=5) ++div;
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break;
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case VP_ROUND_HALF_DOWN: /* Round half down */
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if (v>=6) ++div;
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case VP_ROUND_HALF_DOWN:
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if (v > 5 || (v == 5 && fracf_1further)) ++div;
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break;
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case VP_ROUND_CEIL: /* ceil */
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case VP_ROUND_CEIL:
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if (fracf && (VpGetSign(y)>0)) ++div;
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break;
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case VP_ROUND_FLOOR: /* floor */
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case VP_ROUND_FLOOR:
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if (fracf && (VpGetSign(y)<0)) ++div;
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break;
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case VP_ROUND_HALF_EVEN: /* Banker's rounding */
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if (v>5) ++div;
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else if (v==5) {
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if ((size_t)i == (BASE_FIG-1)) {
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if (ix && (y->frac[ix-1]%2)) ++div;
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}
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if (v > 5) ++div;
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else if (v == 5) {
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if (fracf_1further) {
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++div;
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}
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else {
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if (div%2) ++div;
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}
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}
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break;
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if (ioffset == 0) {
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/* v is the first decimal digit of its BDIGIT;
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need to grab the previous BDIGIT if present
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to check for evenness of the previous decimal
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digit (which is same as that of the BDIGIT since
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base 10 has a factor of 2) */
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if (ix && (y->frac[ix-1] % 2)) ++div;
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}
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else {
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if (div % 2) ++div;
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}
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}
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}
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break;
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}
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for (i=0; i<=n; ++i) div *= 10;
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if (div>=BASE) {
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@ -4694,6 +4744,8 @@ VpLimitRound(Real *c, size_t ixDigit)
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return VpLeftRound(c, (int)VpGetRoundMode(), (ssize_t)ix);
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}
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/* If I understand correctly, this is only ever used to round off the final decimal
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digit of precision */
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static void
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VpInternalRound(Real *c, size_t ixDigit, BDIGIT vPrev, BDIGIT v)
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{
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unsigned short const rounding_mode = VpGetRoundMode();
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if(VpLimitRound(c,ixDigit)) return;
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if(!v) return;
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if (VpLimitRound(c, ixDigit)) return;
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if (!v) return;
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v /= BASE1;
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switch (rounding_mode) {
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case VP_ROUND_DOWN:
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break;
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break;
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case VP_ROUND_UP:
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if(v) f = 1;
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break;
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if (v) f = 1;
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break;
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case VP_ROUND_HALF_UP:
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if(v >= 5) f = 1;
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break;
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if (v >= 5) f = 1;
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break;
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case VP_ROUND_HALF_DOWN:
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if(v >= 6) f = 1;
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break;
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case VP_ROUND_CEIL: /* ceil */
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if(v && (VpGetSign(c)>0)) f = 1;
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break;
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case VP_ROUND_FLOOR: /* floor */
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if(v && (VpGetSign(c)<0)) f = 1;
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break;
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/* this is ok - because this is the last digit of precision,
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the case where v == 5 and some further digits are nonzero
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will never occur */
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if (v >= 6) f = 1;
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break;
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case VP_ROUND_CEIL:
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if (v && (VpGetSign(c) > 0)) f = 1;
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break;
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case VP_ROUND_FLOOR:
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if (v && (VpGetSign(c) < 0)) f = 1;
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break;
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case VP_ROUND_HALF_EVEN: /* Banker's rounding */
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if(v>5) f = 1;
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else if(v==5 && vPrev%2) f = 1;
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break;
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/* as per VP_ROUND_HALF_DOWN, because this is the last digit of precision,
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there is no case to worry about where v == 5 and some further digits are nonzero */
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if (v > 5) f = 1;
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else if (v == 5 && vPrev % 2) f = 1;
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break;
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}
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if(f) {
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VpRdup(c,ixDigit); /* round up */
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VpNmlz(c);
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if (f) {
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VpRdup(c, ixDigit);
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VpNmlz(c);
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}
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}
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@ -612,6 +612,18 @@ class TestBigDecimal < Test::Unit::TestCase
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assert_equal(3, x.round(0, BigDecimal::ROUND_CEILING))
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assert_equal(2, x.round(0, BigDecimal::ROUND_FLOOR))
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assert_raise(TypeError) { x.round(0, 256) }
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15.times do |n|
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x = BigDecimal.new("5#{'0'*n}1")
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assert_equal(10**(n+2), x.round(-(n+2), BigDecimal::ROUND_HALF_DOWN))
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assert_equal(10**(n+2), x.round(-(n+2), BigDecimal::ROUND_HALF_EVEN))
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x = BigDecimal.new("0.5#{'0'*n}1")
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assert_equal(1, x.round(0, BigDecimal::ROUND_HALF_DOWN))
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assert_equal(1, x.round(0, BigDecimal::ROUND_HALF_EVEN))
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x = BigDecimal.new("-0.5#{'0'*n}1")
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assert_equal(-1, x.round(0, BigDecimal::ROUND_HALF_DOWN))
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assert_equal(-1, x.round(0, BigDecimal::ROUND_HALF_EVEN))
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end
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end
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def test_truncate
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