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#X text 219 661 Outlets (1);
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#X text 15 704 GRID;
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#X text 210 417 Inlets (3);
#X text 213 758 Arguments (3);
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#X text 14 587 Inlet 2;
#X text 13 514 Inlet 1;
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#X text 13 787 Argument 0;
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#X text 12 853 Argument 1;
#X text 12 909 Argument 2;
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#X text 119 270 <-- step value;
#X text 90 247 <-- upper bound;
#X text 60 224 <-- lower bound;
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#X text 11 875 INTEGER;
#X text 11 935 INTEGER;
#X text 14 681 Outlet 0;
#X text 105 875 Upper bound;
#X text 106 935 Step value;
#X text 106 815 Lower bound. As with the other arguments \, they are
overwritten when another value is given.;
#X text 11 488 LIST;
#X text 374 276 <-- step value (1);
#X text 343 252 <-- upper bound (2);
#X text 309 227 <-- lower bound (3);
#X text 26 38 When given scalar bounds \, works like a regular [for]
object plugged to a [#import] tuned for a Dim(size) where size is the
number of values produced by a bang to that [for].;
#X text 26 84 When given vector bounds \, will work like any number
of [for] objects producing all possible combinations of their values
in the proper order.;
#X text 35 193 scalar bounds;
#X text 303 196 vector bounds;
#X text 9 465 INTEGER;
#X text 74 466 Sets the lower bound;
#X text 11 558 LIST;
#X text 9 535 INTEGER;
#X text 74 536 Sets the upper bound;
#X text 11 634 LIST;
#X text 9 611 INTEGER;
#X text 74 612 Sets the step value;
#X text 76 707 The result of the operation is a single dimension grid
in the case of scalar values and variable dimensions for vectors.;
#X text 27 137 Syntax: #for <from> <to> <step> outlet: grid dim(size)
where size = floor(to-from+1)/step.;
#X text 391 3 GridFlow 0.9.0;
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