1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
|
IDEAS ABOUT THINGS TO WORK ON
* mpq_cmp: Maybe the most sensible thing to do would be to multiply the, say,
4 most significant limbs of each operand and compare them. If that is not
sufficient, do the same for 8 limbs, etc.
* Write mpi, the Multiple Precision Interval Arithmetic layer.
* Write `mpX_eval' that take lambda-like expressions and a list of operands.
* As a general rule, recognize special operand values in mpz and mpf, and
use shortcuts for speed. Examples: Recognize (small or all) 2^n in
multiplication and division. Recognize small bases in mpz_pow_ui.
* Implement lazy allocation? mpz->d == 0 would mean no allocation made yet.
* Maybe store one-limb numbers according to Per Bothner's idea:
struct {
mp_ptr d;
union {
mp_limb val; /* if (d == NULL). */
mp_size size; /* Length of data array, if (d != NULL). */
} u;
};
Problem: We can't normalize to that format unless we free the space
pointed to by d, and therefore small values will not be stored in a
canonical way.
* Document complexity of all functions.
* Add predicate functions mpz_fits_signedlong_p, mpz_fits_unsignedlong_p,
mpz_fits_signedint_p, etc.
mpz_floor (mpz, mpq), mpz_trunc (mpz, mpq), mpz_round (mpz, mpq).
* Better random number generators. There should be fast (like mpz_random),
very good (mpz_veryrandom), and special purpose (like mpz_random2). Sizes
in *bits*, not in limbs.
* It'd be possible to have an interface "s = add(a,b)" with automatic GC.
If the mpz_xinit routine remembers the address of the variable we could
walk-and-mark the list of remembered variables, and free the space
occupied by the remembered variables that didn't get marked. Fairly
standard.
* Improve speed for non-gcc compilers by defining umul_ppmm, udiv_qrnnd,
etc, to call __umul_ppmm, __udiv_qrnnd. A typical definition for
umul_ppmm would be
#define umul_ppmm(ph,pl,m0,m1) \
{unsigned long __ph; (pl) = __umul_ppmm (&__ph, (m0), (m1)); (ph) = __ph;}
In order to maintain just one version of longlong.h (gmp and gcc), this
has to be done outside of longlong.h.
Bennet Yee at CMU proposes:
* mpz_{put,get}_raw for memory oriented I/O like other *_raw functions.
* A function mpfatal that is called for exceptions. Let the user override
a default definition.
* Make all computation mpz_* functions return a signed int indicating if the
result was zero, positive, or negative?
* Implement mpz_cmpabs, mpz_xor, mpz_to_double, mpz_to_si, mpz_lcm, mpz_dpb,
mpz_ldb, various bit string operations. Also mpz_@_si for most @??
* Add macros for looping efficiently over a number's limbs:
MPZ_LOOP_OVER_LIMBS_INCREASING(num,limb)
{ user code manipulating limb}
MPZ_LOOP_OVER_LIMBS_DECREASING(num,limb)
{ user code manipulating limb}
Brian Beuning proposes:
1. An array of small primes
3. A function to factor a mpz_t. [How do we return the factors? Maybe
we just return one arbitrary factor? In the latter case, we have to
use a data structure that records the state of the factoring routine.]
4. A routine to look for "small" divisors of an mpz_t
5. A 'multiply mod n' routine based on Montgomery's algorithm.
Dough Lea proposes:
1. A way to find out if an integer fits into a signed int, and if so, a
way to convert it out.
2. Similarly for double precision float conversion.
3. A function to convert the ratio of two integers to a double. This
can be useful for mixed mode operations with integers, rationals, and
doubles.
Elliptic curve method description in the Chapter `Algorithms in Number
Theory' in the Handbook of Theoretical Computer Science, Elsevier,
Amsterdam, 1990. Also in Carl Pomerance's lecture notes on Cryptology and
Computational Number Theory, 1990.
* Harald Kirsh suggests:
mpq_set_str (MP_RAT *r, char *numerator, char *denominator).
* New function: mpq_get_ifstr (int_str, frac_str, base,
precision_in_som_way, rational_number). Convert RATIONAL_NUMBER to a
string in BASE and put the integer part in INT_STR and the fraction part
in FRAC_STR. (This function would do a division of the numerator and the
denominator.)
* Should mpz_powm* handle negative exponents?
* udiv_qrnnd: If the denominator is normalized, the n0 argument has very
little effect on the quotient. Maybe we can assume it is 0, and
compensate at a later stage?
* Better sqrt: First calculate the reciprocal square root, then multiply by
the operand to get the square root. The reciprocal square root can be
obtained through Newton-Raphson without division. To compute sqrt(A), the
iteration is,
2
x = x (3 - A x )/2.
i+1 i i
The final result can be computed without division using,
sqrt(A) = A x .
n
* Newton-Raphson using multiplication: We get twice as many correct digits
in each iteration. So if we square x(k) as part of the iteration, the
result will have the leading digits in common with the entire result from
iteration k-1. A _mpn_mul_lowpart could help us take advantage of this.
* Peter Montgomery: If 0 <= a, b < p < 2^31 and I want a modular product
a*b modulo p and the long long type is unavailable, then I can write
typedef signed long slong;
typedef unsigned long ulong;
slong a, b, p, quot, rem;
quot = (slong) (0.5 + (double)a * (double)b / (double)p);
rem = (slong)((ulong)a * (ulong)b - (ulong)p * (ulong)quot);
if (rem < 0} {rem += p; quot--;}
* Speed modulo arithmetic, using Montgomery's method or my pre-inversion
method. In either case, special arithmetic calls would be needed,
mpz_mmmul, mpz_mmadd, mpz_mmsub, plus some kind of initialization
functions. Better yet: Write a new mpr layer.
* mpz_powm* should not use division to reduce the result in the loop, but
instead pre-compute the reciprocal of the MOD argument and do reduced_val
= val-val*reciprocal(MOD)*MOD, or use Montgomery's method.
* mpz_mod_2expplussi -- to reduce a bignum modulo (2**n)+s
* It would be a quite important feature never to allocate more memory than
really necessary for a result. Sometimes we can achieve this cheaply, by
deferring reallocation until the result size is known.
* New macro in longlong.h: shift_rhl that extracts a word by shifting two
words as a unit. (Supported by i386, i860, HP-PA, POWER, 29k.) Useful
for shifting multiple precision numbers.
* The installation procedure should make a test run of multiplication to
decide the threshold values for algorithm switching between the available
methods.
* Fast output conversion of x to base B:
1. Find n, such that (B^n > x).
2. Set y to (x*2^m)/(B^n), where m large enough to make 2^n ~~ B^n
3. Multiply the low half of y by B^(n/2), and recursively convert the
result. Truncate the low half of y and convert that recursively.
Complexity: O(M(n)log(n))+O(D(n))!
* Improve division using Newton-Raphson. Check out "Newton Iteration and
Integer Division" by Stephen Tate in "Synthesis of Parallel Algorithms",
Morgan Kaufmann, 1993 ("beware of some errors"...)
* Improve implementation of Karatsuba's algorithm. For most operand sizes,
we can reduce the number of operations by splitting differently.
* Faster multiplication: The best approach is to first implement Toom-Cook.
People report that it beats Karatsuba's algorithm already at about 100
limbs. FFT would probably never beat a well-written Toom-Cook (not even for
millions of bits).
FFT:
{
* Multiplication could be done with Montgomery's method combined with
the "three primes" method described in Lipson. Maybe this would be
faster than to Nussbaumer's method with 3 (simple) moduli?
* Maybe the modular tricks below are not needed: We are using very
special numbers, Fermat numbers with a small base and a large exponent,
and maybe it's possible to just subtract and add?
* Modify Nussbaumer's convolution algorithm, to use 3 words for each
coefficient, calculating in 3 relatively prime moduli (e.g.
0xffffffff, 0x100000000, and 0x7fff on a 32-bit computer). Both all
operations and CRR would be very fast with such numbers.
* Optimize the Schoenhage-Stassen multiplication algorithm. Take advantage
of the real valued input to save half of the operations and half of the
memory. Use recursive FFT with large base cases, since recursive FFT has
better memory locality. A normal FFT get 100% cache misses for large
enough operands.
* In the 3-prime convolution method, it might sometimes be a win to use 2,
3, or 5 primes. Imagine that using 3 primes would require a transform
length of 2^n. But 2 primes might still sometimes give us correct
results with that same transform length, or 5 primes might allow us to
decrease the transform size to 2^(n-1).
To optimize floating-point based complex FFT we have to think of:
1. The normal implementation accesses all input exactly once for each of
the log(n) passes. This means that we will get 0% cache hit when n >
our cache. Remedy: Reorganize computation to compute partial passes,
maybe similar to a standard recursive FFT implementation. Use a large
`base case' to make any extra overhead of this organization negligible.
2. Use base-4, base-8 and base-16 FFT instead of just radix-2. This can
reduce the number of operations by 2x.
3. Inputs are real-valued. According to Knuth's "Seminumerical
Algorithms", exercise 4.6.4-14, we can save half the memory and half
the operations if we take advantage of that.
4. Maybe make it possible to write the innermost loop in assembly, since
that could win us another 2x speedup. (If we write our FFT to avoid
cache-miss (see #1 above) it might be logical to write the `base case'
in assembly.)
5. Avoid multiplication by 1, i, -1, -i. Similarly, optimize
multiplication by (+-\/2 +- i\/2).
6. Put as many bits as possible in each double (but don't waste time if
that doesn't make the transform size become smaller).
7. For n > some large number, we will get accuracy problems because of the
limited precision of our floating point arithmetic. This can easily be
solved by using the Karatsuba trick a few times until our operands
become small enough.
8. Precompute the roots-of-unity and store them in a vector.
}
* When a division result is going to be just one limb, (i.e. nsize-dsize is
small) normalization could be done in the division loop.
* Never allocate temporary space for a source param that overlaps with a
destination param needing reallocation. Instead malloc a new block for
the destination (and free the source before returning to the caller).
* Parallel addition. Since each processors have to tell it is ready to the
next processor, we can use simplified synchronization, and actually write
it in C: For each processor (apart from the least significant):
while (*svar != my_number)
;
*svar = my_number + 1;
The least significant processor does this:
*svar = my_number + 1; /* i.e., *svar = 1 */
Before starting the addition, one processor has to store 0 in *svar.
Other things to think about for parallel addition: To avoid false
(cache-line) sharing, allocate blocks on cache-line boundaries.
Local Variables:
mode: text
fill-column: 77
fill-prefix: " "
version-control: never
End:
|