( The van der Horst Algorithm in Forth --- with minor modifications
for kForth and 4tH.
The "van der Horst" algorithm is a small example program that
finds a factorization of numbers with reasonable "small"
factors. For a 32 bit FORTH this means any factors < 2,000,000,000
The input number can be very large indeed, large enough that the
algorithm becomes totally impractical. [State of the art factoring
uses elliptic curves or quadratic polynomial sieves]
It is based on a very well known base conversion routine and the
observation that if you have given a number in base ``b'', its
divisibility by ``b'' can be established by inspecting the last
digit of the number.
Example : is 97321087 divisible by 10? Answer : no.
The base conversion rewrites the number from one base to the next
and so on with only a small number of additions.
Some lack of modesty is needed to call this combination a new
algorithm and put your name on it.
Author : Albert van der Horst/Adrie Bos/Marcel Hendrix
Rewritten as a pure ANSI forth example by Albert van der Horst )
DECIMAL
include lib/dbldot.4th
\ ( The auxiliary word to forget this application is ``-horst'' )
\ S" TFORTH" ENVIRONMENT?
\ [IF] DROP
\ REVISION -horst " HORST version 4.5 --- ANSI version [LC index bug in HORST]"
\ [ELSE] MARKER -horst
CR .( loading HORST version 4.5 --- 4tH version [LC index bug in HORST]) CR
\ [THEN]
\ S" TFORTH" ENVIRONMENT? 0= [IF]
CHAR 0 CONSTANT &0 \ Ascii value of '0'
\ : <= > 0= ;
: C@+ dup char+ swap c@ ;
\ [ELSE] DROP
\ [THEN]
( PART 2 : DATA STRUCTURES
********************************************************************* )
1000 CONSTANT MAX.DIGITS \ Maximum number of bits handled
\ The number to be factored is represented as follows :
\ num = sum(i from 0 to length-1 : num[i]*current.base^(len-1-i) )
( or in more mundane parlance :
the lowest `length' cells of `num' represent digits in base
`current.base', lowest are the most significant digits )
VARIABLE current.base
VARIABLE length
MAX.DIGITS ARRAY num :this num does> swap th ;
( PART 3 : ALGORITHM
********************************************************************* )
( Before and after HORST the number represented by `num' is the same.
Only `current.base' is one higher than before.
At point one `num' is in a "mixed base" representation with the
I left most digits in the new base and the remainder still in the
old base, throughout representing the same number.
See also Knuth: The art of computer programming page 306 :
a "Hand calculation" for going from octal to decimal.
Only ours is even simpler because our bases differ by 1 not by 2 )
: HORST ( --- )
1 current.base +! \ Next number base
current.base @ 0< ABORT" Remaining factors too large to handle"
length @ 1 ?DO
( point one )
0 I DO
I num @
I 1- num @ - \ subtract more significant digit
DUP 0< IF \ Negative?
-1 I 1- num +! \ Borrow
current.base @ + \ a "ten"
THEN
I num !
-1 +LOOP
LOOP
;
( Simplifies the number by eliminating leading zero digits
Note the nasty conditioning about length,
needs very careful treatment in Forth. )
: SIMPLIFY ( --- )
BEGIN
2 length @ <= \ Prevent wrap around loop for length 1
0 num @ 0=
AND
WHILE
length @ 1- 0 DO \ Shift to the right
I 1+ num @ I num !
LOOP
-1 length +! \ One shorter now
REPEAT
;
( Convert the number to the next higher base )
: NEXT.FACTOR ( --- )
HORST
SIMPLIFY
;
( Store the 4 bits of <word> at 4 successive lower addresses beneath
<adr1>. The last address used is returned.
Least significant bit is stored highest. )
: SPLIT4 ( adr1 word --- adr2 )
SWAP
4 0 DO \ For all 4 bits:
1- >R \ Decrement and store index
2 /MOD SWAP \ Split off right most bit
R@ num ! \ Store it
R> \ Get index back
LOOP
SWAP DROP \ Drop the remainder
;
( Convert the decimal number as given to binary.
Apply HORST 6 times for base 16.
Then each digit contain 4 bits of the number,
split them over 4 cells. )
: DEC.TO.BIN ( --- )
6 0 DO NEXT.FACTOR LOOP \ Now in HEX
length @ 4 * \ Point after last cell of binary representation
-1 length @ 1- DO \ From the end to prevent overwrites
I num @ \ Hex digit I
SPLIT4 \ distribute the bits
-1 +LOOP ( index) DROP
length @ 4 *
length ! \ 4 times as much digits
2 current.base ! \ `num' is binary now
SIMPLIFY \ Rid of leading zero's
length @ 1 = \ But not of the last one,
0 num @ 0= \ because of looping finesses
AND ABORT" Zero cannot be factored"
;
( Convert a character digit to a binary representation )
: ASCII->BINARY ( char --- double )
&0 -
DUP 0< OVER 9 > OR ABORT" Not a decimal number"
;
( Get a decimal number from the input stream and store it in a
base 10 representation in ``num'' )
: READ.NUMBER \ ( --- ) accepts "number.string"
refill drop 0 parse
DUP 0= ABORT" Please input a number"
DUP length ! \ Remember!
0 DO \ Convert each digit
C@+ ASCII->BINARY
I num ! \ to binary in number.
LOOP DROP \ Drop string address.
10 current.base ! \ Start with decimal
;
( Print the remaining factor.
Depending on the circumstances the number may have 1 or 2
digits. It is always prime, because smaller numbers have been
factored out. If it is 1 it is not printed, of course. )
: LAST.FACTOR ( --- )
length @ 1 = IF
0 num @ DUP 1 <> IF
CR ." Factor: " current.base @ U.
ELSE
DROP \ Factor 1 not interesting
THEN
ELSE
( Calculate the number represented by `num' )
( Double precision is sufficient )
0 num @ current.base @ UM*
1 num @ U>D D+
CR ." Factor: " D.
THEN
;
( It is well known that we need not look for factors in a number
that are larger than its square root.
In the representation choosen this means that it need less than 2
digits to be represented. The flag indicated there may be factors to
be found. )
: NOT.PAST.SQRT ( --- flag )
2 length @ <
;
( The number `num' is divisable by base if the last digit is zero
( The flag indicates whether `num' is divisable by `current.base' )
: ?DIVISABLE ( --- flag )
length @ 1- num @ 0=
;
( And finally ......
`FACTORIZE' accepts a string in the input stream with decimal digits
and factorizes it. )
: FACTORIZE
." Factorize: " READ.NUMBER
DEC.TO.BIN
BEGIN
NOT.PAST.SQRT WHILE
BEGIN
?DIVISABLE WHILE
CR ." Factor: " current.base @ U.
-1 length +! \ This divides by factor, scrap the last 0
REPEAT
NEXT.FACTOR \ Base conversion
REPEAT
LAST.FACTOR \ Print the last factor
;
factorize
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