mingw-w64-v5.0.0/mingw-w64-crt/math/DFP/mpdecimal/libmpdec/literature/mulmod-64.txt - toolchain/mingw - Git at Google



 (* Copyright (c) 2011 Stefan Krah. All rights reserved. *)


 ==========================================================================
                 Calculate (a * b) % p using special primes
 ==========================================================================

 A description of the algorithm can be found in the apfloat manual by
 Tommila [1].


 Definitions:
 ------------

 In the whole document, "==" stands for "is congruent with".

 Result of a * b in terms of high/low words:

    (1) hi * 2**64 + lo = a * b

 Special primes:

    (2) p = 2**64 - z + 1, where z = 2**n

 Single step modular reduction:

    (3) R(hi, lo) = hi * z - hi + lo


 Strategy:
 ---------

    a) Set (hi, lo) to the result of a * b.

    b) Set (hi', lo') to the result of R(hi, lo).

    c) Repeat step b) until 0 <= hi' * 2**64 + lo' < 2*p.

    d) If the result is less than p, return lo'. Otherwise return lo' - p.


 The reduction step b) preserves congruence:
 -------------------------------------------

     hi * 2**64 + lo == hi * z - hi + lo   (mod p)

     Proof:
     ~~~~~~

        hi * 2**64 + lo = (2**64 - z + 1) * hi + z * hi - hi + lo

                        = p * hi               + z * hi - hi + lo

                        == z * hi - hi + lo   (mod p)


 Maximum numbers of step b):
 ---------------------------

 # To avoid unnecessary formalism, define:

 def R(hi, lo, z):
      return divmod(hi * z - hi + lo, 2**64)

 # For simplicity, assume hi=2**64-1, lo=2**64-1 after the
 # initial multiplication a * b. This is of course impossible
 # but certainly covers all cases.

 # Then, for p1:
 hi=2**64-1; lo=2**64-1; z=2**32
 p1 = 2**64 - z + 1

 hi, lo = R(hi, lo, z)    # First reduction
 hi, lo = R(hi, lo, z)    # Second reduction
 hi * 2**64 + lo < 2 * p1 # True

 # For p2:
 hi=2**64-1; lo=2**64-1; z=2**34
 p2 = 2**64 - z + 1

 hi, lo = R(hi, lo, z)    # First reduction
 hi, lo = R(hi, lo, z)    # Second reduction
 hi, lo = R(hi, lo, z)    # Third reduction
 hi * 2**64 + lo < 2 * p2 # True

 # For p3:
 hi=2**64-1; lo=2**64-1; z=2**40
 p3 = 2**64 - z + 1

 hi, lo = R(hi, lo, z)    # First reduction
 hi, lo = R(hi, lo, z)    # Second reduction
 hi, lo = R(hi, lo, z)    # Third reduction
 hi * 2**64 + lo < 2 * p3 # True


 Step d) preserves congruence and yields a result < p:
 -----------------------------------------------------

    Case hi = 0:

        Case lo < p: trivial.

        Case lo >= p:

           lo == lo - p   (mod p)             # result is congruent

           p <= lo < 2*p  ->  0 <= lo - p < p # result is in the correct range

    Case hi = 1:

        p < 2**64 /\ 2**64 + lo < 2*p  ->  lo < p  # lo is always less than p

        2**64 + lo == 2**64 + (lo - p)   (mod p)   # result is congruent

                   = lo - p   # exactly the same value as the previous RHS
                              # in uint64_t arithmetic.

        p < 2**64 + lo < 2*p  ->  0 < 2**64 + (lo - p) < p  # correct range


 [1]  http://www.apfloat.org/apfloat/2.40/apfloat.pdf


	(* Copyright (c) 2011 Stefan Krah. All rights reserved. *)


	==========================================================================
	Calculate (a * b) % p using special primes
	==========================================================================

	A description of the algorithm can be found in the apfloat manual by
	Tommila [1].


	Definitions:
	------------

	In the whole document, "==" stands for "is congruent with".

	Result of a * b in terms of high/low words:

	(1) hi * 2*64 + lo = a b

	Special primes:

	(2) p = 264 - z + 1, where z = 2n

	Single step modular reduction:

	(3) R(hi, lo) = hi * z - hi + lo


	Strategy:
	---------

	a) Set (hi, lo) to the result of a * b.

	b) Set (hi', lo') to the result of R(hi, lo).

	c) Repeat step b) until 0 <= hi' * 2*64 + lo' < 2p.

	d) If the result is less than p, return lo'. Otherwise return lo' - p.


	The reduction step b) preserves congruence:
	-------------------------------------------

	hi * 2*64 + lo == hi z - hi + lo (mod p)

	Proof:
	~~~~~~

	hi * 264 + lo = (264 - z + 1) * hi + z * hi - hi + lo

	= p * hi + z * hi - hi + lo

	== z * hi - hi + lo (mod p)


	Maximum numbers of step b):
	---------------------------

	# To avoid unnecessary formalism, define:

	def R(hi, lo, z):
	return divmod(hi * z - hi + lo, 2**64)

	# For simplicity, assume hi=264-1, lo=264-1 after the
	# initial multiplication a * b. This is of course impossible
	# but certainly covers all cases.

	# Then, for p1:
	hi=264-1; lo=264-1; z=2**32
	p1 = 2**64 - z + 1

	hi, lo = R(hi, lo, z) # First reduction
	hi, lo = R(hi, lo, z) # Second reduction
	hi * 2*64 + lo < 2 p1 # True

	# For p2:
	hi=264-1; lo=264-1; z=2**34
	p2 = 2**64 - z + 1

	hi, lo = R(hi, lo, z) # First reduction
	hi, lo = R(hi, lo, z) # Second reduction
	hi, lo = R(hi, lo, z) # Third reduction
	hi * 2*64 + lo < 2 p2 # True

	# For p3:
	hi=264-1; lo=264-1; z=2**40
	p3 = 2**64 - z + 1

	hi, lo = R(hi, lo, z) # First reduction
	hi, lo = R(hi, lo, z) # Second reduction
	hi, lo = R(hi, lo, z) # Third reduction
	hi * 2*64 + lo < 2 p3 # True


	Step d) preserves congruence and yields a result < p:
	-----------------------------------------------------

	Case hi = 0:

	Case lo < p: trivial.

	Case lo >= p:

	lo == lo - p (mod p) # result is congruent

	p <= lo < 2*p -> 0 <= lo - p < p # result is in the correct range

	Case hi = 1:

	p < 264 /\ 264 + lo < 2*p -> lo < p # lo is always less than p

	264 + lo == 264 + (lo - p) (mod p) # result is congruent

	= lo - p # exactly the same value as the previous RHS
	# in uint64_t arithmetic.

	p < 2*64 + lo < 2p -> 0 < 2**64 + (lo - p) < p # correct range



	[1] http://www.apfloat.org/apfloat/2.40/apfloat.pdf