Ruby 1.9.3p327(2012-11-10revision37606)
range.c
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00001 /**********************************************************************
00002 
00003   range.c -
00004 
00005   $Author: tarui $
00006   created at: Thu Aug 19 17:46:47 JST 1993
00007 
00008   Copyright (C) 1993-2007 Yukihiro Matsumoto
00009 
00010 **********************************************************************/
00011 
00012 #include "ruby/ruby.h"
00013 #include "ruby/encoding.h"
00014 #include "internal.h"
00015 
00016 VALUE rb_cRange;
00017 static ID id_cmp, id_succ, id_beg, id_end, id_excl;
00018 
00019 #define RANGE_BEG(r) (RSTRUCT(r)->as.ary[0])
00020 #define RANGE_END(r) (RSTRUCT(r)->as.ary[1])
00021 #define RANGE_EXCL(r) (RSTRUCT(r)->as.ary[2])
00022 
00023 #define EXCL(r) RTEST(RANGE_EXCL(r))
00024 #define SET_EXCL(r,v) (RSTRUCT(r)->as.ary[2] = (v) ? Qtrue : Qfalse)
00025 
00026 static VALUE
00027 range_failed(void)
00028 {
00029     rb_raise(rb_eArgError, "bad value for range");
00030     return Qnil;                /* dummy */
00031 }
00032 
00033 static VALUE
00034 range_check(VALUE *args)
00035 {
00036     return rb_funcall(args[0], id_cmp, 1, args[1]);
00037 }
00038 
00039 static void
00040 range_init(VALUE range, VALUE beg, VALUE end, int exclude_end)
00041 {
00042     VALUE args[2];
00043 
00044     args[0] = beg;
00045     args[1] = end;
00046 
00047     if (!FIXNUM_P(beg) || !FIXNUM_P(end)) {
00048         VALUE v;
00049 
00050         v = rb_rescue(range_check, (VALUE)args, range_failed, 0);
00051         if (NIL_P(v))
00052             range_failed();
00053     }
00054 
00055     SET_EXCL(range, exclude_end);
00056     RSTRUCT(range)->as.ary[0] = beg;
00057     RSTRUCT(range)->as.ary[1] = end;
00058 }
00059 
00060 VALUE
00061 rb_range_new(VALUE beg, VALUE end, int exclude_end)
00062 {
00063     VALUE range = rb_obj_alloc(rb_cRange);
00064 
00065     range_init(range, beg, end, exclude_end);
00066     return range;
00067 }
00068 
00069 /*
00070  *  call-seq:
00071  *     Range.new(start, end, exclusive=false)    -> range
00072  *
00073  *  Constructs a range using the given <i>start</i> and <i>end</i>. If the third
00074  *  parameter is omitted or is <code>false</code>, the <i>range</i> will include
00075  *  the end object; otherwise, it will be excluded.
00076  */
00077 
00078 static VALUE
00079 range_initialize(int argc, VALUE *argv, VALUE range)
00080 {
00081     VALUE beg, end, flags;
00082 
00083     rb_scan_args(argc, argv, "21", &beg, &end, &flags);
00084     /* Ranges are immutable, so that they should be initialized only once. */
00085     if (RANGE_EXCL(range) != Qnil) {
00086         rb_name_error(rb_intern("initialize"), "`initialize' called twice");
00087     }
00088     range_init(range, beg, end, RTEST(flags));
00089     return Qnil;
00090 }
00091 
00092 #define range_initialize_copy rb_struct_init_copy /* :nodoc: */
00093 
00094 /*
00095  *  call-seq:
00096  *     rng.exclude_end?    -> true or false
00097  *
00098  *  Returns <code>true</code> if <i>rng</i> excludes its end value.
00099  */
00100 
00101 static VALUE
00102 range_exclude_end_p(VALUE range)
00103 {
00104     return EXCL(range) ? Qtrue : Qfalse;
00105 }
00106 
00107 static VALUE
00108 recursive_equal(VALUE range, VALUE obj, int recur)
00109 {
00110     if (recur) return Qtrue; /* Subtle! */
00111     if (!rb_equal(RANGE_BEG(range), RANGE_BEG(obj)))
00112         return Qfalse;
00113     if (!rb_equal(RANGE_END(range), RANGE_END(obj)))
00114         return Qfalse;
00115 
00116     if (EXCL(range) != EXCL(obj))
00117         return Qfalse;
00118     return Qtrue;
00119 }
00120 
00121 
00122 /*
00123  *  call-seq:
00124  *     rng == obj    -> true or false
00125  *
00126  *  Returns <code>true</code> only if <i>obj</i> is a Range, has equivalent
00127  *  beginning and end items (by comparing them with <code>==</code>), and has
00128  *  the same <code>exclude_end?</code> setting as <i>rng</i>.
00129  *
00130  *    (0..2) == (0..2)            #=> true
00131  *    (0..2) == Range.new(0,2)    #=> true
00132  *    (0..2) == (0...2)           #=> false
00133  *
00134  */
00135 
00136 static VALUE
00137 range_eq(VALUE range, VALUE obj)
00138 {
00139     if (range == obj)
00140         return Qtrue;
00141     if (!rb_obj_is_kind_of(obj, rb_cRange))
00142         return Qfalse;
00143 
00144     return rb_exec_recursive_paired(recursive_equal, range, obj, obj);
00145 }
00146 
00147 static int
00148 r_lt(VALUE a, VALUE b)
00149 {
00150     VALUE r = rb_funcall(a, id_cmp, 1, b);
00151 
00152     if (NIL_P(r))
00153         return (int)Qfalse;
00154     if (rb_cmpint(r, a, b) < 0)
00155         return (int)Qtrue;
00156     return (int)Qfalse;
00157 }
00158 
00159 static int
00160 r_le(VALUE a, VALUE b)
00161 {
00162     int c;
00163     VALUE r = rb_funcall(a, id_cmp, 1, b);
00164 
00165     if (NIL_P(r))
00166         return (int)Qfalse;
00167     c = rb_cmpint(r, a, b);
00168     if (c == 0)
00169         return (int)INT2FIX(0);
00170     if (c < 0)
00171         return (int)Qtrue;
00172     return (int)Qfalse;
00173 }
00174 
00175 
00176 static VALUE
00177 recursive_eql(VALUE range, VALUE obj, int recur)
00178 {
00179     if (recur) return Qtrue; /* Subtle! */
00180     if (!rb_eql(RANGE_BEG(range), RANGE_BEG(obj)))
00181         return Qfalse;
00182     if (!rb_eql(RANGE_END(range), RANGE_END(obj)))
00183         return Qfalse;
00184 
00185     if (EXCL(range) != EXCL(obj))
00186         return Qfalse;
00187     return Qtrue;
00188 }
00189 
00190 /*
00191  *  call-seq:
00192  *     rng.eql?(obj)    -> true or false
00193  *
00194  *  Returns <code>true</code> only if <i>obj</i> is a Range, has equivalent
00195  *  beginning and end items (by comparing them with #eql?), and has the same
00196  *  #exclude_end? setting as <i>rng</i>.
00197  *
00198  *    (0..2).eql?(0..2)            #=> true
00199  *    (0..2).eql?(Range.new(0,2))  #=> true
00200  *    (0..2).eql?(0...2)           #=> false
00201  *
00202  */
00203 
00204 static VALUE
00205 range_eql(VALUE range, VALUE obj)
00206 {
00207     if (range == obj)
00208         return Qtrue;
00209     if (!rb_obj_is_kind_of(obj, rb_cRange))
00210         return Qfalse;
00211     return rb_exec_recursive_paired(recursive_eql, range, obj, obj);
00212 }
00213 
00214 static VALUE
00215 recursive_hash(VALUE range, VALUE dummy, int recur)
00216 {
00217     st_index_t hash = EXCL(range);
00218     VALUE v;
00219 
00220     hash = rb_hash_start(hash);
00221     if (!recur) {
00222         v = rb_hash(RANGE_BEG(range));
00223         hash = rb_hash_uint(hash, NUM2LONG(v));
00224         v = rb_hash(RANGE_END(range));
00225         hash = rb_hash_uint(hash, NUM2LONG(v));
00226     }
00227     hash = rb_hash_uint(hash, EXCL(range) << 24);
00228     hash = rb_hash_end(hash);
00229 
00230     return LONG2FIX(hash);
00231 }
00232 
00233 /*
00234  * call-seq:
00235  *   rng.hash    -> fixnum
00236  *
00237  * Generate a hash value such that two ranges with the same start and
00238  * end points, and the same value for the "exclude end" flag, generate
00239  * the same hash value.
00240  */
00241 
00242 static VALUE
00243 range_hash(VALUE range)
00244 {
00245     return rb_exec_recursive_outer(recursive_hash, range, 0);
00246 }
00247 
00248 static void
00249 range_each_func(VALUE range, VALUE (*func) (VALUE, void *), void *arg)
00250 {
00251     int c;
00252     VALUE b = RANGE_BEG(range);
00253     VALUE e = RANGE_END(range);
00254     VALUE v = b;
00255 
00256     if (EXCL(range)) {
00257         while (r_lt(v, e)) {
00258             (*func) (v, arg);
00259             v = rb_funcall(v, id_succ, 0, 0);
00260         }
00261     }
00262     else {
00263         while ((c = r_le(v, e)) != Qfalse) {
00264             (*func) (v, arg);
00265             if (c == (int)INT2FIX(0))
00266                 break;
00267             v = rb_funcall(v, id_succ, 0, 0);
00268         }
00269     }
00270 }
00271 
00272 static VALUE
00273 sym_step_i(VALUE i, void *arg)
00274 {
00275     VALUE *iter = arg;
00276 
00277     if (FIXNUM_P(iter[0])) {
00278         iter[0] -= INT2FIX(1) & ~FIXNUM_FLAG;
00279     }
00280     else {
00281         iter[0] = rb_funcall(iter[0], '-', 1, INT2FIX(1));
00282     }
00283     if (iter[0] == INT2FIX(0)) {
00284         rb_yield(rb_str_intern(i));
00285         iter[0] = iter[1];
00286     }
00287     return Qnil;
00288 }
00289 
00290 static VALUE
00291 step_i(VALUE i, void *arg)
00292 {
00293     VALUE *iter = arg;
00294 
00295     if (FIXNUM_P(iter[0])) {
00296         iter[0] -= INT2FIX(1) & ~FIXNUM_FLAG;
00297     }
00298     else {
00299         iter[0] = rb_funcall(iter[0], '-', 1, INT2FIX(1));
00300     }
00301     if (iter[0] == INT2FIX(0)) {
00302         rb_yield(i);
00303         iter[0] = iter[1];
00304     }
00305     return Qnil;
00306 }
00307 
00308 static int
00309 discrete_object_p(VALUE obj)
00310 {
00311     if (rb_obj_is_kind_of(obj, rb_cTime)) return FALSE; /* until Time#succ removed */
00312     return rb_respond_to(obj, id_succ);
00313 }
00314 
00315 
00316 /*
00317  *  call-seq:
00318  *     rng.step(n=1) {| obj | block }    -> rng
00319  *     rng.step(n=1)                     -> an_enumerator
00320  *
00321  *  Iterates over <i>rng</i>, passing each <i>n</i>th element to the block. If
00322  *  the range contains numbers, <i>n</i> is added for each iteration.  Otherwise
00323  *  <code>step</code> invokes <code>succ</code> to iterate through range
00324  *  elements. The following code uses class <code>Xs</code>, which is defined
00325  *  in the class-level documentation.
00326  *
00327  *  If no block is given, an enumerator is returned instead.
00328  *
00329  *     range = Xs.new(1)..Xs.new(10)
00330  *     range.step(2) {|x| puts x}
00331  *     range.step(3) {|x| puts x}
00332  *
00333  *  <em>produces:</em>
00334  *
00335  *      1 x
00336  *      3 xxx
00337  *      5 xxxxx
00338  *      7 xxxxxxx
00339  *      9 xxxxxxxxx
00340  *      1 x
00341  *      4 xxxx
00342  *      7 xxxxxxx
00343  *     10 xxxxxxxxxx
00344  */
00345 
00346 
00347 static VALUE
00348 range_step(int argc, VALUE *argv, VALUE range)
00349 {
00350     VALUE b, e, step, tmp;
00351 
00352     RETURN_ENUMERATOR(range, argc, argv);
00353 
00354     b = RANGE_BEG(range);
00355     e = RANGE_END(range);
00356     if (argc == 0) {
00357         step = INT2FIX(1);
00358     }
00359     else {
00360         rb_scan_args(argc, argv, "01", &step);
00361         if (!rb_obj_is_kind_of(step, rb_cNumeric)) {
00362             step = rb_to_int(step);
00363         }
00364         if (rb_funcall(step, '<', 1, INT2FIX(0))) {
00365             rb_raise(rb_eArgError, "step can't be negative");
00366         }
00367         else if (!rb_funcall(step, '>', 1, INT2FIX(0))) {
00368             rb_raise(rb_eArgError, "step can't be 0");
00369         }
00370     }
00371 
00372     if (FIXNUM_P(b) && FIXNUM_P(e) && FIXNUM_P(step)) { /* fixnums are special */
00373         long end = FIX2LONG(e);
00374         long i, unit = FIX2LONG(step);
00375 
00376         if (!EXCL(range))
00377             end += 1;
00378         i = FIX2LONG(b);
00379         while (i < end) {
00380             rb_yield(LONG2NUM(i));
00381             if (i + unit < i) break;
00382             i += unit;
00383         }
00384 
00385     }
00386     else if (SYMBOL_P(b) && SYMBOL_P(e)) { /* symbols are special */
00387         VALUE args[2], iter[2];
00388 
00389         args[0] = rb_sym_to_s(e);
00390         args[1] = EXCL(range) ? Qtrue : Qfalse;
00391         iter[0] = INT2FIX(1);
00392         iter[1] = step;
00393         rb_block_call(rb_sym_to_s(b), rb_intern("upto"), 2, args, sym_step_i, (VALUE)iter);
00394     }
00395     else if (ruby_float_step(b, e, step, EXCL(range))) {
00396         /* done */
00397     }
00398     else if (rb_obj_is_kind_of(b, rb_cNumeric) ||
00399              !NIL_P(rb_check_to_integer(b, "to_int")) ||
00400              !NIL_P(rb_check_to_integer(e, "to_int"))) {
00401         ID op = EXCL(range) ? '<' : rb_intern("<=");
00402         VALUE v = b;
00403         int i = 0;
00404 
00405         while (RTEST(rb_funcall(v, op, 1, e))) {
00406             rb_yield(v);
00407             i++;
00408             v = rb_funcall(b, '+', 1, rb_funcall(INT2NUM(i), '*', 1, step));
00409         }
00410     }
00411     else {
00412         tmp = rb_check_string_type(b);
00413 
00414         if (!NIL_P(tmp)) {
00415             VALUE args[2], iter[2];
00416 
00417             b = tmp;
00418             args[0] = e;
00419             args[1] = EXCL(range) ? Qtrue : Qfalse;
00420             iter[0] = INT2FIX(1);
00421             iter[1] = step;
00422             rb_block_call(b, rb_intern("upto"), 2, args, step_i, (VALUE)iter);
00423         }
00424         else {
00425             VALUE args[2];
00426 
00427             if (!discrete_object_p(b)) {
00428                 rb_raise(rb_eTypeError, "can't iterate from %s",
00429                          rb_obj_classname(b));
00430             }
00431             args[0] = INT2FIX(1);
00432             args[1] = step;
00433             range_each_func(range, step_i, args);
00434         }
00435     }
00436     return range;
00437 }
00438 
00439 static VALUE
00440 each_i(VALUE v, void *arg)
00441 {
00442     rb_yield(v);
00443     return Qnil;
00444 }
00445 
00446 static VALUE
00447 sym_each_i(VALUE v, void *arg)
00448 {
00449     rb_yield(rb_str_intern(v));
00450     return Qnil;
00451 }
00452 
00453 /*
00454  *  call-seq:
00455  *     rng.each {| i | block } -> rng
00456  *     rng.each                -> an_enumerator
00457  *
00458  *  Iterates over the elements <i>rng</i>, passing each in turn to the
00459  *  block. You can only iterate if the start object of the range
00460  *  supports the +succ+ method (which means that you can't iterate over
00461  *  ranges of +Float+ objects).
00462  *
00463  *  If no block is given, an enumerator is returned instead.
00464  *
00465  *     (10..15).each do |n|
00466  *        print n, ' '
00467  *     end
00468  *
00469  *  <em>produces:</em>
00470  *
00471  *     10 11 12 13 14 15
00472  */
00473 
00474 static VALUE
00475 range_each(VALUE range)
00476 {
00477     VALUE beg, end;
00478 
00479     RETURN_ENUMERATOR(range, 0, 0);
00480 
00481     beg = RANGE_BEG(range);
00482     end = RANGE_END(range);
00483 
00484     if (FIXNUM_P(beg) && FIXNUM_P(end)) { /* fixnums are special */
00485         long lim = FIX2LONG(end);
00486         long i;
00487 
00488         if (!EXCL(range))
00489             lim += 1;
00490         for (i = FIX2LONG(beg); i < lim; i++) {
00491             rb_yield(LONG2FIX(i));
00492         }
00493     }
00494     else if (SYMBOL_P(beg) && SYMBOL_P(end)) { /* symbols are special */
00495         VALUE args[2];
00496 
00497         args[0] = rb_sym_to_s(end);
00498         args[1] = EXCL(range) ? Qtrue : Qfalse;
00499         rb_block_call(rb_sym_to_s(beg), rb_intern("upto"), 2, args, sym_each_i, 0);
00500     }
00501     else {
00502         VALUE tmp = rb_check_string_type(beg);
00503 
00504         if (!NIL_P(tmp)) {
00505             VALUE args[2];
00506 
00507             args[0] = end;
00508             args[1] = EXCL(range) ? Qtrue : Qfalse;
00509             rb_block_call(tmp, rb_intern("upto"), 2, args, rb_yield, 0);
00510         }
00511         else {
00512             if (!discrete_object_p(beg)) {
00513                 rb_raise(rb_eTypeError, "can't iterate from %s",
00514                          rb_obj_classname(beg));
00515             }
00516             range_each_func(range, each_i, NULL);
00517         }
00518     }
00519     return range;
00520 }
00521 
00522 /*
00523  *  call-seq:
00524  *     rng.begin    -> obj
00525  *
00526  *  Returns the first object in <i>rng</i>.
00527  */
00528 
00529 static VALUE
00530 range_begin(VALUE range)
00531 {
00532     return RANGE_BEG(range);
00533 }
00534 
00535 
00536 /*
00537  *  call-seq:
00538  *     rng.end    -> obj
00539  *
00540  *  Returns the object that defines the end of <i>rng</i>.
00541  *
00542  *     (1..10).end    #=> 10
00543  *     (1...10).end   #=> 10
00544  */
00545 
00546 
00547 static VALUE
00548 range_end(VALUE range)
00549 {
00550     return RANGE_END(range);
00551 }
00552 
00553 
00554 static VALUE
00555 first_i(VALUE i, VALUE *ary)
00556 {
00557     long n = NUM2LONG(ary[0]);
00558 
00559     if (n <= 0) {
00560         rb_iter_break();
00561     }
00562     rb_ary_push(ary[1], i);
00563     n--;
00564     ary[0] = INT2NUM(n);
00565     return Qnil;
00566 }
00567 
00568 /*
00569  *  call-seq:
00570  *     rng.first    -> obj
00571  *     rng.first(n) -> an_array
00572  *
00573  *  Returns the first object in <i>rng</i>, or the first +n+ elements.
00574  */
00575 
00576 static VALUE
00577 range_first(int argc, VALUE *argv, VALUE range)
00578 {
00579     VALUE n, ary[2];
00580 
00581     if (argc == 0) return RANGE_BEG(range);
00582 
00583     rb_scan_args(argc, argv, "1", &n);
00584     ary[0] = n;
00585     ary[1] = rb_ary_new2(NUM2LONG(n));
00586     rb_block_call(range, rb_intern("each"), 0, 0, first_i, (VALUE)ary);
00587 
00588     return ary[1];
00589 }
00590 
00591 
00592 /*
00593  *  call-seq:
00594  *     rng.last    -> obj
00595  *     rng.last(n) -> an_array
00596  *
00597  *  Returns the last object in <i>rng</i>, or the last +n+ elements.
00598  */
00599 
00600 static VALUE
00601 range_last(int argc, VALUE *argv, VALUE range)
00602 {
00603     if (argc == 0) return RANGE_END(range);
00604     return rb_ary_last(argc, argv, rb_Array(range));
00605 }
00606 
00607 
00608 /*
00609  *  call-seq:
00610  *     rng.min                    -> obj
00611  *     rng.min {| a,b | block }   -> obj
00612  *
00613  *  Returns the minimum value in <i>rng</i>. The second uses
00614  *  the block to compare values.  Returns nil if the first
00615  *  value in range is larger than the last value.
00616  *
00617  */
00618 
00619 
00620 static VALUE
00621 range_min(VALUE range)
00622 {
00623     if (rb_block_given_p()) {
00624         return rb_call_super(0, 0);
00625     }
00626     else {
00627         VALUE b = RANGE_BEG(range);
00628         VALUE e = RANGE_END(range);
00629         int c = rb_cmpint(rb_funcall(b, id_cmp, 1, e), b, e);
00630 
00631         if (c > 0 || (c == 0 && EXCL(range)))
00632             return Qnil;
00633         return b;
00634     }
00635 }
00636 
00637 /*
00638  *  call-seq:
00639  *     rng.max                    -> obj
00640  *     rng.max {| a,b | block }   -> obj
00641  *
00642  *  Returns the maximum value in <i>rng</i>. The second uses
00643  *  the block to compare values.  Returns nil if the first
00644  *  value in range is larger than the last value.
00645  *
00646  */
00647 
00648 static VALUE
00649 range_max(VALUE range)
00650 {
00651     VALUE e = RANGE_END(range);
00652     int nm = FIXNUM_P(e) || rb_obj_is_kind_of(e, rb_cNumeric);
00653 
00654     if (rb_block_given_p() || (EXCL(range) && !nm)) {
00655         return rb_call_super(0, 0);
00656     }
00657     else {
00658         VALUE b = RANGE_BEG(range);
00659         int c = rb_cmpint(rb_funcall(b, id_cmp, 1, e), b, e);
00660 
00661         if (c > 0)
00662             return Qnil;
00663         if (EXCL(range)) {
00664             if (!FIXNUM_P(e) && !rb_obj_is_kind_of(e, rb_cInteger)) {
00665                 rb_raise(rb_eTypeError, "cannot exclude non Integer end value");
00666             }
00667             if (c == 0) return Qnil;
00668             if (!FIXNUM_P(b) && !rb_obj_is_kind_of(b,rb_cInteger)) {
00669                 rb_raise(rb_eTypeError, "cannot exclude end value with non Integer begin value");
00670             }
00671             if (FIXNUM_P(e)) {
00672                 return LONG2NUM(FIX2LONG(e) - 1);
00673             }
00674             return rb_funcall(e, '-', 1, INT2FIX(1));
00675         }
00676         return e;
00677     }
00678 }
00679 
00680 int
00681 rb_range_values(VALUE range, VALUE *begp, VALUE *endp, int *exclp)
00682 {
00683     VALUE b, e;
00684     int excl;
00685 
00686     if (rb_obj_is_kind_of(range, rb_cRange)) {
00687         b = RANGE_BEG(range);
00688         e = RANGE_END(range);
00689         excl = EXCL(range);
00690     }
00691     else {
00692         if (!rb_respond_to(range, id_beg)) return (int)Qfalse;
00693         if (!rb_respond_to(range, id_end)) return (int)Qfalse;
00694         b = rb_funcall(range, id_beg, 0);
00695         e = rb_funcall(range, id_end, 0);
00696         excl = RTEST(rb_funcall(range, rb_intern("exclude_end?"), 0));
00697     }
00698     *begp = b;
00699     *endp = e;
00700     *exclp = excl;
00701     return (int)Qtrue;
00702 }
00703 
00704 VALUE
00705 rb_range_beg_len(VALUE range, long *begp, long *lenp, long len, int err)
00706 {
00707     long beg, end, origbeg, origend;
00708     VALUE b, e;
00709     int excl;
00710 
00711     if (!rb_range_values(range, &b, &e, &excl))
00712         return Qfalse;
00713     beg = NUM2LONG(b);
00714     end = NUM2LONG(e);
00715     origbeg = beg;
00716     origend = end;
00717     if (beg < 0) {
00718         beg += len;
00719         if (beg < 0)
00720             goto out_of_range;
00721     }
00722     if (err == 0 || err == 2) {
00723         if (beg > len)
00724             goto out_of_range;
00725         if (end > len)
00726             end = len;
00727     }
00728     if (end < 0)
00729         end += len;
00730     if (!excl)
00731         end++;                  /* include end point */
00732     len = end - beg;
00733     if (len < 0)
00734         len = 0;
00735 
00736     *begp = beg;
00737     *lenp = len;
00738     return Qtrue;
00739 
00740   out_of_range:
00741     if (err) {
00742         rb_raise(rb_eRangeError, "%ld..%s%ld out of range",
00743                  origbeg, excl ? "." : "", origend);
00744     }
00745     return Qnil;
00746 }
00747 
00748 /*
00749  * call-seq:
00750  *   rng.to_s   -> string
00751  *
00752  * Convert this range object to a printable form.
00753  */
00754 
00755 static VALUE
00756 range_to_s(VALUE range)
00757 {
00758     VALUE str, str2;
00759 
00760     str = rb_obj_as_string(RANGE_BEG(range));
00761     str2 = rb_obj_as_string(RANGE_END(range));
00762     str = rb_str_dup(str);
00763     rb_str_cat(str, "...", EXCL(range) ? 3 : 2);
00764     rb_str_append(str, str2);
00765     OBJ_INFECT(str, str2);
00766 
00767     return str;
00768 }
00769 
00770 static VALUE
00771 inspect_range(VALUE range, VALUE dummy, int recur)
00772 {
00773     VALUE str, str2;
00774 
00775     if (recur) {
00776         return rb_str_new2(EXCL(range) ? "(... ... ...)" : "(... .. ...)");
00777     }
00778     str = rb_inspect(RANGE_BEG(range));
00779     str2 = rb_inspect(RANGE_END(range));
00780     str = rb_str_dup(str);
00781     rb_str_cat(str, "...", EXCL(range) ? 3 : 2);
00782     rb_str_append(str, str2);
00783     OBJ_INFECT(str, str2);
00784 
00785     return str;
00786 }
00787 
00788 /*
00789  * call-seq:
00790  *   rng.inspect  -> string
00791  *
00792  * Convert this range object to a printable form (using
00793  * <code>inspect</code> to convert the start and end
00794  * objects).
00795  */
00796 
00797 
00798 static VALUE
00799 range_inspect(VALUE range)
00800 {
00801     return rb_exec_recursive(inspect_range, range, 0);
00802 }
00803 
00804 /*
00805  *  call-seq:
00806  *     rng === obj       ->  true or false
00807  *
00808  *  Returns <code>true</code> if <i>obj</i> is an element of
00809  *  <i>rng</i>, <code>false</code> otherwise. Conveniently,
00810  *  <code>===</code> is the comparison operator used by
00811  *  <code>case</code> statements.
00812  *
00813  *     case 79
00814  *     when 1..50   then   print "low\n"
00815  *     when 51..75  then   print "medium\n"
00816  *     when 76..100 then   print "high\n"
00817  *     end
00818  *
00819  *  <em>produces:</em>
00820  *
00821  *     high
00822  */
00823 
00824 static VALUE
00825 range_eqq(VALUE range, VALUE val)
00826 {
00827     return rb_funcall(range, rb_intern("include?"), 1, val);
00828 }
00829 
00830 
00831 /*
00832  *  call-seq:
00833  *     rng.member?(val)  ->  true or false
00834  *     rng.include?(val) ->  true or false
00835  *
00836  *  Returns <code>true</code> if <i>obj</i> is an element of
00837  *  <i>rng</i>, <code>false</code> otherwise.  If beg and end are
00838  *  numeric, comparison is done according magnitude of values.
00839  *
00840  *     ("a".."z").include?("g")  # -> true
00841  *     ("a".."z").include?("A")  # -> false
00842  */
00843 
00844 static VALUE
00845 range_include(VALUE range, VALUE val)
00846 {
00847     VALUE beg = RANGE_BEG(range);
00848     VALUE end = RANGE_END(range);
00849     int nv = FIXNUM_P(beg) || FIXNUM_P(end) ||
00850              rb_obj_is_kind_of(beg, rb_cNumeric) ||
00851              rb_obj_is_kind_of(end, rb_cNumeric);
00852 
00853     if (nv ||
00854         !NIL_P(rb_check_to_integer(beg, "to_int")) ||
00855         !NIL_P(rb_check_to_integer(end, "to_int"))) {
00856         if (r_le(beg, val)) {
00857             if (EXCL(range)) {
00858                 if (r_lt(val, end))
00859                     return Qtrue;
00860             }
00861             else {
00862                 if (r_le(val, end))
00863                     return Qtrue;
00864             }
00865         }
00866         return Qfalse;
00867     }
00868     else if (TYPE(beg) == T_STRING && TYPE(end) == T_STRING &&
00869              RSTRING_LEN(beg) == 1 && RSTRING_LEN(end) == 1) {
00870         if (NIL_P(val)) return Qfalse;
00871         if (TYPE(val) == T_STRING) {
00872             if (RSTRING_LEN(val) == 0 || RSTRING_LEN(val) > 1)
00873                 return Qfalse;
00874             else {
00875                 char b = RSTRING_PTR(beg)[0];
00876                 char e = RSTRING_PTR(end)[0];
00877                 char v = RSTRING_PTR(val)[0];
00878 
00879                 if (ISASCII(b) && ISASCII(e) && ISASCII(v)) {
00880                     if (b <= v && v < e) return Qtrue;
00881                     if (!EXCL(range) && v == e) return Qtrue;
00882                     return Qfalse;
00883                 }
00884             }
00885         }
00886     }
00887     /* TODO: ruby_frame->this_func = rb_intern("include?"); */
00888     return rb_call_super(1, &val);
00889 }
00890 
00891 
00892 /*
00893  *  call-seq:
00894  *     rng.cover?(val)  ->  true or false
00895  *
00896  *  Returns <code>true</code> if <i>obj</i> is between beg and end,
00897  *  i.e <code>beg <= obj <= end</code> (or <i>end</i> exclusive when
00898  *  <code>exclude_end?</code> is true).
00899  *
00900  *     ("a".."z").cover?("c")    #=> true
00901  *     ("a".."z").cover?("5")    #=> false
00902  */
00903 
00904 static VALUE
00905 range_cover(VALUE range, VALUE val)
00906 {
00907     VALUE beg, end;
00908 
00909     beg = RANGE_BEG(range);
00910     end = RANGE_END(range);
00911     if (r_le(beg, val)) {
00912         if (EXCL(range)) {
00913             if (r_lt(val, end))
00914                 return Qtrue;
00915         }
00916         else {
00917             if (r_le(val, end))
00918                 return Qtrue;
00919         }
00920     }
00921     return Qfalse;
00922 }
00923 
00924 static VALUE
00925 range_dumper(VALUE range)
00926 {
00927     VALUE v;
00928     NEWOBJ(m, struct RObject);
00929     OBJSETUP(m, rb_cObject, T_OBJECT);
00930 
00931     v = (VALUE)m;
00932 
00933     rb_ivar_set(v, id_excl, RANGE_EXCL(range));
00934     rb_ivar_set(v, id_beg, RANGE_BEG(range));
00935     rb_ivar_set(v, id_end, RANGE_END(range));
00936     return v;
00937 }
00938 
00939 static VALUE
00940 range_loader(VALUE range, VALUE obj)
00941 {
00942     if (TYPE(obj) != T_OBJECT || RBASIC(obj)->klass != rb_cObject) {
00943         rb_raise(rb_eTypeError, "not a dumped range object");
00944     }
00945 
00946     RSTRUCT(range)->as.ary[0] = rb_ivar_get(obj, id_beg);
00947     RSTRUCT(range)->as.ary[1] = rb_ivar_get(obj, id_end);
00948     RSTRUCT(range)->as.ary[2] = rb_ivar_get(obj, id_excl);
00949     return range;
00950 }
00951 
00952 static VALUE
00953 range_alloc(VALUE klass)
00954 {
00955   /* rb_struct_alloc_noinit itself should not be used because
00956    * rb_marshal_define_compat uses equality of allocaiton function */
00957     return rb_struct_alloc_noinit(klass);
00958 }
00959 
00960 /*  A <code>Range</code> represents an interval---a set of values with a
00961  *  start and an end. Ranges may be constructed using the
00962  *  <em>s</em><code>..</code><em>e</em> and
00963  *  <em>s</em><code>...</code><em>e</em> literals, or with
00964  *  <code>Range::new</code>. Ranges constructed using <code>..</code>
00965  *  run from the start to the end inclusively. Those created using
00966  *  <code>...</code> exclude the end value. When used as an iterator,
00967  *  ranges return each value in the sequence.
00968  *
00969  *     (-1..-5).to_a      #=> []
00970  *     (-5..-1).to_a      #=> [-5, -4, -3, -2, -1]
00971  *     ('a'..'e').to_a    #=> ["a", "b", "c", "d", "e"]
00972  *     ('a'...'e').to_a   #=> ["a", "b", "c", "d"]
00973  *
00974  *  Ranges can be constructed using objects of any type, as long as the
00975  *  objects can be compared using their <code><=></code> operator and
00976  *  they support the <code>succ</code> method to return the next object
00977  *  in sequence.
00978  *
00979  *     class Xs                # represent a string of 'x's
00980  *       include Comparable
00981  *       attr :length
00982  *       def initialize(n)
00983  *         @length = n
00984  *       end
00985  *       def succ
00986  *         Xs.new(@length + 1)
00987  *       end
00988  *       def <=>(other)
00989  *         @length <=> other.length
00990  *       end
00991  *       def to_s
00992  *         sprintf "%2d #{inspect}", @length
00993  *       end
00994  *       def inspect
00995  *         'x' * @length
00996  *       end
00997  *     end
00998  *
00999  *     r = Xs.new(3)..Xs.new(6)   #=> xxx..xxxxxx
01000  *     r.to_a                     #=> [xxx, xxxx, xxxxx, xxxxxx]
01001  *     r.member?(Xs.new(5))       #=> true
01002  *
01003  *  In the previous code example, class <code>Xs</code> includes the
01004  *  <code>Comparable</code> module. This is because
01005  *  <code>Enumerable#member?</code> checks for equality using
01006  *  <code>==</code>. Including <code>Comparable</code> ensures that the
01007  *  <code>==</code> method is defined in terms of the <code><=></code>
01008  *  method implemented in <code>Xs</code>.
01009  *
01010  */
01011 
01012 void
01013 Init_Range(void)
01014 {
01015 #undef rb_intern
01016 #define rb_intern(str) rb_intern_const(str)
01017 
01018     id_cmp = rb_intern("<=>");
01019     id_succ = rb_intern("succ");
01020     id_beg = rb_intern("begin");
01021     id_end = rb_intern("end");
01022     id_excl = rb_intern("excl");
01023 
01024     rb_cRange = rb_struct_define_without_accessor(
01025         "Range", rb_cObject, range_alloc,
01026         "begin", "end", "excl", NULL);
01027 
01028     rb_include_module(rb_cRange, rb_mEnumerable);
01029     rb_marshal_define_compat(rb_cRange, rb_cObject, range_dumper, range_loader);
01030     rb_define_method(rb_cRange, "initialize", range_initialize, -1);
01031     rb_define_method(rb_cRange, "initialize_copy", range_initialize_copy, 1);
01032     rb_define_method(rb_cRange, "==", range_eq, 1);
01033     rb_define_method(rb_cRange, "===", range_eqq, 1);
01034     rb_define_method(rb_cRange, "eql?", range_eql, 1);
01035     rb_define_method(rb_cRange, "hash", range_hash, 0);
01036     rb_define_method(rb_cRange, "each", range_each, 0);
01037     rb_define_method(rb_cRange, "step", range_step, -1);
01038     rb_define_method(rb_cRange, "begin", range_begin, 0);
01039     rb_define_method(rb_cRange, "end", range_end, 0);
01040     rb_define_method(rb_cRange, "first", range_first, -1);
01041     rb_define_method(rb_cRange, "last", range_last, -1);
01042     rb_define_method(rb_cRange, "min", range_min, 0);
01043     rb_define_method(rb_cRange, "max", range_max, 0);
01044     rb_define_method(rb_cRange, "to_s", range_to_s, 0);
01045     rb_define_method(rb_cRange, "inspect", range_inspect, 0);
01046 
01047     rb_define_method(rb_cRange, "exclude_end?", range_exclude_end_p, 0);
01048 
01049     rb_define_method(rb_cRange, "member?", range_include, 1);
01050     rb_define_method(rb_cRange, "include?", range_include, 1);
01051     rb_define_method(rb_cRange, "cover?", range_cover, 1);
01052 }
01053