Math::NumSeq::GolayRudinShapiroCumulative -- cumulative Golay/RudinShapiro sequence
use Math::NumSeq::GolayRudinShapiroCumulative; my $seq = Math::NumSeq::GolayRudinShapiroCumulative->new; my ($i, $value) = $seq->next;
This is the Golay/Rudin/Shapiro sequence values accumulated as GRS(0)+...+GRS(i),
starting from i=0 with value=GRS(0) alone 1, 2, 3, 2, 3, 4, 3, 4, 5, 6, 7, 6, 5, 4, 5, 4, ...
The total is always positive, and in fact a given cumulative total k occurs precisely k times. For example the three occurrences of 3 shown above are all the places 3 occurs.
This GRS cumulative arises as in the alternate paper folding curve as the coordinate sum X+Y. The way k occurs k many times has a geometric interpretation as the points on the diagonal X+Y=k of the curve being visited a total of k many times. See "dSum" in Math::PlanePath::AlternatePaper.
See "FUNCTIONS" in Math::NumSeq for behaviour common to all sequence classes.
$value = $seq->ith($i)
$i'th value from the sequence, being the total
$bool = $seq->pred($value)
Return true if
$valueoccurs in the sequence. All positive integers occur, so this simply means integer
$value >= 1.
The cumulative total GRS(0)+...+GRS(i-1) can be calculated from the 1 bits of i. Each 1 bit becomes a value 2^floor((pos+1)/2) in the total,
bit value --- ----- 0 1 1 2 2 2 3 4 4 4 ... ... k 2^ceil(k/2)
The value is added or subtracted from the total according to the number of 11 bit pairs above that bit position, not including the bit itself,
add value if even count of adjacent 11 bit pairs above sub value if odd count
For example i=27 is 110011 in binary so
1 -1 bit0 low bit 1 -2 bit1 0 bit2 1 +4 bit3 1 +4 bit4 high bit ---- 5 cumulative value GRS(0)+...+GRS(26)
The second lowest bit is negated as value -2 because there's one 11 bit pair above it, and -1 the same because above and not including that bit there's just one 11 bit pair.
Or for example i=31 is 11111 in binary so
1 -1 bit0 low bit 1 +2 bit1 1 -2 bit2 1 +4 bit3 1 +4 bit4 high bit ---- 7 cumulative total GRS(0)+...+GRS(30)
Here at bit2 the value is -2 because there's one adjacent 11 above, not including bit2 itself. Then at bit1 there's two 11 pairs above so +2, and at bit0 there's three so -1.
The total can be formed either by examining the bits from high to low counting adjacent 11 bits on the way down to know whether to add or subtract. Or it can be formed from low to high by negating the total so far when a 11 pair is encountered.
For an inclusive sum GRS(0)+...+GRS(i) as per this module, the extra GRS(i) can be worked into the calculation by its GRS definition +1 or -1 according to the total number of adjacent 11 bits. This can be thought of as an extra value 1 below the least significant bit. For example i=27 inclusive
+1 below all bits 1 -1 bit0 low bit 1 -2 bit1 0 bit2 1 +4 bit3 1 +4 bit4 high bit ---- 5 cumulative value GRS(0)+...+GRS(27)
For low to high this low value 1 can be handled simply by starting the total at 1. It then becomes +1 or -1 by the negations as 11s are encountered for the rest of the bit handling.
total = 1 # initial value below all bits to be inclusive GRS(i) power = 1 # 2^ceil(bitpos/2) thisbit = take bit from low end of i loop nextbit = take bit from low end of i if thisbit&&nextbit then total = -total # negate lower values added if thisbit then total += power thisbit = nextbit power *= 2 exit loop if i==0 nextbit = bit from low end of i if thisbit&&nextbit then total = -total # negate lower values added if thisbit then total += power thisbit = nextbit exit loop if i==0 endloop total += power # final for highest 1-bit in i # total=GRS(0)+...+GRS(i)
This sort of calculation arises implicitly in the alternate paper folding curve to calculate X,Y for a given N point on the curve. But that calculation does X=GRStotal(ceil(N/2)) and Y=GRStotal(floor(N/2)) simultaneously using the base 4 digits of N.
Copyright 2012 Kevin Ryde
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