#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#define FUNC_popcnt 1
#define FUNC_isqrt 1
#include "ptypes.h"
#include "sieve.h"
#include "cache.h"
#include "lmo.h"
#include "constants.h"
#include "prime_nth_count.h"
#include "util.h"
#include <math.h>
#if _MSC_VER || defined(__IBMC__) || defined(__IBMCPP__) || (defined(__STDC_VERSION__) && __STDC_VERSION >= 199901L)
/* math.h should give us these as functions or macros.
*
* extern long double floorl(long double);
* extern long double ceill(long double);
* extern long double sqrtl(long double);
* extern long double logl(long double);
*/
#else
#define floorl(x) (long double) floor( (double) (x) )
#define ceill(x) (long double) ceil( (double) (x) )
#define sqrtl(x) (long double) sqrt( (double) (x) )
#define logl(x) (long double) log( (double) (x) )
#endif
#if defined(__GNUC__)
#define word_unaligned(m,wordsize) ((uintptr_t)m & (wordsize-1))
#else /* uintptr_t is part of C99 */
#define word_unaligned(m,wordsize) ((unsigned int)m & (wordsize-1))
#endif
/* TODO: This data is duplicated in util.c. */
static const unsigned char prime_sieve30[] =
{0x01,0x20,0x10,0x81,0x49,0x24,0xc2,0x06,0x2a,0xb0,0xe1,0x0c,0x15,0x59,0x12,
0x61,0x19,0xf3,0x2c,0x2c,0xc4,0x22,0xa6,0x5a,0x95,0x98,0x6d,0x42,0x87,0xe1,
0x59,0xa9,0xa9,0x1c,0x52,0xd2,0x21,0xd5,0xb3,0xaa,0x26,0x5c,0x0f,0x60,0xfc,
0xab,0x5e,0x07,0xd1,0x02,0xbb,0x16,0x99,0x09,0xec,0xc5,0x47,0xb3,0xd4,0xc5,
0xba,0xee,0x40,0xab,0x73,0x3e,0x85,0x4c,0x37,0x43,0x73,0xb0,0xde,0xa7,0x8e,
0x8e,0x64,0x3e,0xe8,0x10,0xab,0x69,0xe5,0xf7,0x1a,0x7c,0x73,0xb9,0x8d,0x04,
0x51,0x9a,0x6d,0x70,0xa7,0x78,0x2d,0x6d,0x27,0x7e,0x9a,0xd9,0x1c,0x5f,0xee,
0xc7,0x38,0xd9,0xc3,0x7e,0x14,0x66,0x72,0xae,0x77,0xc1,0xdb,0x0c,0xcc,0xb2,
0xa5,0x74,0xe3,0x58,0xd5,0x4b,0xa7,0xb3,0xb1,0xd9,0x09,0xe6,0x7d,0x23,0x7c,
0x3c,0xd3,0x0e,0xc7,0xfd,0x4a,0x32,0x32,0xfd,0x4d,0xb5,0x6b,0xf3,0xa8,0xb3,
0x85,0xcf,0xbc,0xf4,0x0e,0x34,0xbb,0x93,0xdb,0x07,0xe6,0xfe,0x6a,0x57,0xa3,
0x8c,0x15,0x72,0xdb,0x69,0xd4,0xaf,0x59,0xdd,0xe1,0x3b,0x2e,0xb7,0xf9,0x2b,
0xc5,0xd0,0x8b,0x63,0xf8,0x95,0xfa,0x77,0x40,0x97,0xea,0xd1,0x9f,0xaa,0x1c,
0x48,0xae,0x67,0xf7,0xeb,0x79,0xa5,0x55,0xba,0xb2,0xb6,0x8f,0xd8,0x2d,0x6c,
0x2a,0x35,0x54,0xfd,0x7c,0x9e,0xfa,0xdb,0x31,0x78,0xdd,0x3d,0x56,0x52,0xe7,
0x73,0xb2,0x87,0x2e,0x76,0xe9,0x4f,0xa8,0x38,0x9d,0x5d,0x3f,0xcb,0xdb,0xad,
0x51,0xa5,0xbf,0xcd,0x72,0xde,0xf7,0xbc,0xcb,0x49,0x2d,0x49,0x26,0xe6,0x1e,
0x9f,0x98,0xe5,0xc6,0x9f,0x2f,0xbb,0x85,0x6b,0x65,0xf6,0x77,0x7c,0x57,0x8b,
0xaa,0xef,0xd8,0x5e,0xa2,0x97,0xe1,0xdc,0x37,0xcd,0x1f,0xe6,0xfc,0xbb,0x8c,
0xb7,0x4e,0xc7,0x3c,0x19,0xd5,0xa8,0x9e,0x67,0x4a,0xe3,0xf5,0x97,0x3a,0x7e,
0x70,0x53,0xfd,0xd6,0xe5,0xb8,0x1c,0x6b,0xee,0xb1,0x9b,0xd1,0xeb,0x34,0xc2,
0x23,0xeb,0x3a,0xf9,0xef,0x16,0xd6,0x4e,0x7d,0x16,0xcf,0xb8,0x1c,0xcb,0xe6,
0x3c,0xda,0xf5,0xcf};
#define NPRIME_SIEVE30 (sizeof(prime_sieve30)/sizeof(prime_sieve30[0]))
static const unsigned short primes_small[] =
{0,2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97,
101,103,107,109,113,127,131,137,139,149,151,157,163,167,173,179,181,191,
193,197,199,211,223,227,229,233,239,241,251,257,263,269,271,277,281,283,
293,307,311,313,317,331,337,347,349,353,359,367,373,379,383,389,397,401,
409,419,421,431,433,439,443,449,457,461,463,467,479,487,491,499};
#define NPRIMES_SMALL (sizeof(primes_small)/sizeof(primes_small[0]))
static const unsigned char byte_zeros[256] =
{8,7,7,6,7,6,6,5,7,6,6,5,6,5,5,4,7,6,6,5,6,5,5,4,6,5,5,4,5,4,4,3,
7,6,6,5,6,5,5,4,6,5,5,4,5,4,4,3,6,5,5,4,5,4,4,3,5,4,4,3,4,3,3,2,
7,6,6,5,6,5,5,4,6,5,5,4,5,4,4,3,6,5,5,4,5,4,4,3,5,4,4,3,4,3,3,2,
6,5,5,4,5,4,4,3,5,4,4,3,4,3,3,2,5,4,4,3,4,3,3,2,4,3,3,2,3,2,2,1,
7,6,6,5,6,5,5,4,6,5,5,4,5,4,4,3,6,5,5,4,5,4,4,3,5,4,4,3,4,3,3,2,
6,5,5,4,5,4,4,3,5,4,4,3,4,3,3,2,5,4,4,3,4,3,3,2,4,3,3,2,3,2,2,1,
6,5,5,4,5,4,4,3,5,4,4,3,4,3,3,2,5,4,4,3,4,3,3,2,4,3,3,2,3,2,2,1,
5,4,4,3,4,3,3,2,4,3,3,2,3,2,2,1,4,3,3,2,3,2,2,1,3,2,2,1,2,1,1,0};
static UV count_zero_bits(const unsigned char* m, UV nbytes)
{
UV count = 0;
#if BITS_PER_WORD == 64
if (nbytes >= 16) {
while ( word_unaligned(m,sizeof(UV)) && nbytes--)
count += byte_zeros[*m++];
if (nbytes >= 8) {
UV* wordptr = (UV*)m;
UV nwords = nbytes / 8;
UV nzeros = nwords * 64;
m += nwords * 8;
nbytes %= 8;
while (nwords--)
nzeros -= popcnt(*wordptr++);
count += nzeros;
}
}
#endif
while (nbytes--)
count += byte_zeros[*m++];
return count;
}
/* Given a sieve of size nbytes, walk it counting zeros (primes) until:
*
* (1) we counted them all: return the count, which will be less than maxcount.
*
* (2) we hit maxcount: set position to the index of the maxcount'th prime
* and return count (which will be equal to maxcount).
*/
static UV count_segment_maxcount(const unsigned char* sieve, UV base, UV nbytes, UV maxcount, UV* pos)
{
UV count = 0;
UV byte = 0;
const unsigned char* sieveptr = sieve;
const unsigned char* maxsieve = sieve + nbytes;
MPUassert(sieve != 0, "count_segment_maxcount incorrect args");
MPUassert(pos != 0, "count_segment_maxcount incorrect args");
*pos = 0;
if ( (nbytes == 0) || (maxcount == 0) )
return 0;
/* Do fixed-length word counts to start, with possible overcounting */
while ((count+64) < maxcount && sieveptr < maxsieve) {
UV top = base + 3*maxcount;
UV div = (top < 8000) ? 8 : /* 8 cannot overcount */
(top < 1000000) ? 4 :
(top < 10000000) ? 3 : 2;
UV minbytes = (maxcount-count)/div;
if (minbytes > (UV)(maxsieve-sieveptr)) minbytes = maxsieve-sieveptr;
count += count_zero_bits(sieveptr, minbytes);
sieveptr += minbytes;
}
/* Count until we reach the end or >= maxcount */
while ( (sieveptr < maxsieve) && (count < maxcount) )
count += byte_zeros[*sieveptr++];
/* If we went too far, back up. */
while (count >= maxcount)
count -= byte_zeros[*--sieveptr];
/* We counted this many bytes */
byte = sieveptr - sieve;
MPUassert(count < maxcount, "count_segment_maxcount wrong count");
if (byte == nbytes)
return count;
/* The result is somewhere in the next byte */
START_DO_FOR_EACH_SIEVE_PRIME(sieve, 0, byte*30+1, nbytes*30-1)
if (++count == maxcount) { *pos = p; return count; }
END_DO_FOR_EACH_SIEVE_PRIME;
MPUassert(0, "count_segment_maxcount failure");
return 0;
}
/* Given a sieve of size nbytes, counting zeros (primes) but excluding the
* areas outside lowp and highp.
*/
static UV count_segment_ranged(const unsigned char* sieve, UV nbytes, UV lowp, UV highp)
{
UV count, hi_d, lo_d, lo_m;
MPUassert( sieve != 0, "count_segment_ranged incorrect args");
if (nbytes == 0) return 0;
count = 0;
hi_d = highp/30;
if (hi_d >= nbytes) {
hi_d = nbytes-1;
highp = hi_d*30+29;
}
if (highp < lowp)
return 0;
#if 0
/* Dead simple way */
START_DO_FOR_EACH_SIEVE_PRIME(sieve, 0, lowp, highp)
count++;
END_DO_FOR_EACH_SIEVE_PRIME;
return count;
#endif
lo_d = lowp/30;
lo_m = lowp - lo_d*30;
/* Count first fragment */
if (lo_m > 1) {
UV upper = (highp <= (lo_d*30+29)) ? highp : (lo_d*30+29);
START_DO_FOR_EACH_SIEVE_PRIME(sieve, 0, lowp, upper)
count++;
END_DO_FOR_EACH_SIEVE_PRIME;
lowp = upper+2;
lo_d = lowp/30;
}
if (highp < lowp)
return count;
/* Count bytes in the middle */
{
UV hi_m = highp - hi_d*30;
UV count_bytes = hi_d - lo_d + (hi_m == 29);
if (count_bytes > 0) {
count += count_zero_bits(sieve+lo_d, count_bytes);
lowp += 30*count_bytes;
}
}
if (highp < lowp)
return count;
/* Count last fragment */
START_DO_FOR_EACH_SIEVE_PRIME(sieve, 0, lowp, highp)
count++;
END_DO_FOR_EACH_SIEVE_PRIME;
return count;
}
/*
* The pi(x) prime count functions. prime_count(x) gives an exact number,
* but requires determining all the primes up to x, so will be much slower.
*
* prime_count_lower(x) and prime_count_upper(x) give lower and upper limits,
* which will bound the exact value. These bounds should be fairly tight.
*
* pi_upper(x) - pi(x) pi_lower(x) - pi(x)
* < 10 for x < 5_371 < 10 for x < 9_437
* < 50 for x < 295_816 < 50 for x < 136_993
* < 100 for x < 1_761_655 < 100 for x < 909_911
* < 200 for x < 9_987_821 < 200 for x < 8_787_901
* < 400 for x < 34_762_891 < 400 for x < 30_332_723
* < 1000 for x < 372_748_528 < 1000 for x < 233_000_533
* < 5000 for x < 1_882_595_905 < 5000 for x < over 4300M
*
* The average of the upper and lower bounds is within 9 for all x < 15809, and
* within 50 for all x < 1_763_367.
*
* It is common to use the following Chebyshev inequality for x >= 17:
* 1*x/logx <-> 1.25506*x/logx
* but this gives terribly loose bounds.
*
* Rosser and Schoenfeld's bound for x >= 67 of
* x/(logx-1/2) <-> x/(logx-3/2)
* is much tighter. These bounds can be tightened even more.
*
* The formulas of Dusart for higher x are better yet. I recommend the paper
* by Burde for further information. Dusart's thesis is also a good resource.
*
* I have tweaked the bounds formulas for small (under 70_000M) numbers so they
* are tighter. These bounds are verified via trial. The Dusart bounds
* (1.8 and 2.51) are used for larger numbers since those are proven.
*
*/
#include "prime_count_tables.h"
UV segment_prime_count(UV low, UV high)
{
const unsigned char* cache_sieve;
unsigned char* segment;
UV segment_size, low_d, high_d;
UV count = 0;
if ((low <= 2) && (high >= 2)) count++;
if ((low <= 3) && (high >= 3)) count++;
if ((low <= 5) && (high >= 5)) count++;
if (low < 7) low = 7;
if (low > high) return count;
if (low == 7 && high <= 30*NPRIME_SIEVE30) {
count += count_segment_ranged(prime_sieve30, NPRIME_SIEVE30, low, high);
return count;
}
/* If we have sparse prime count tables, use them here. These will adjust
* 'low' and 'count' appropriately for a value slightly less than ours.
* This should leave just a small amount of sieving left. They stop at
* some point, e.g. 3000M, so we'll get the answer to that point then have
* to sieve all the rest. We should be using LMO or Lehmer much earlier. */
#ifdef APPLY_TABLES
APPLY_TABLES
#endif
low_d = low/30;
high_d = high/30;
/* Count full bytes only -- no fragments from primary cache */
segment_size = get_prime_cache(0, &cache_sieve) / 30;
if (segment_size < high_d) {
/* Expand sieve to sqrt(n) */
UV endp = (high_d >= (UV_MAX/30)) ? UV_MAX-2 : 30*high_d+29;
release_prime_cache(cache_sieve);
segment_size = get_prime_cache( isqrt(endp) + 1 , &cache_sieve) / 30;
}
if ( (segment_size > 0) && (low_d <= segment_size) ) {
/* Count all the primes in the primary cache in our range */
count += count_segment_ranged(cache_sieve, segment_size, low, high);
if (high_d < segment_size) {
release_prime_cache(cache_sieve);
return count;
}
low_d = segment_size;
if (30*low_d > low) low = 30*low_d;
}
release_prime_cache(cache_sieve);
/* More primes needed. Repeatedly segment sieve. */
{
void* ctx = start_segment_primes(low, high, &segment);
UV seg_base, seg_low, seg_high;
while (next_segment_primes(ctx, &seg_base, &seg_low, &seg_high)) {
segment_size = seg_high/30 - seg_low/30 + 1;
count += count_segment_ranged(segment, segment_size, seg_low-seg_base, seg_high-seg_base);
}
end_segment_primes(ctx);
}
return count;
}
UV prime_count(UV lo, UV hi)
{
UV count, range_threshold;
if (lo > hi || hi < 2)
return 0;
/* We use table acceleration so this is preferable for small inputs */
if (hi < 66000000) return segment_prime_count(lo, hi);
/* Rough empirical threshold for when segment faster than LMO */
range_threshold = hi / (isqrt(hi)/200);
if ( (hi-lo+1) < range_threshold )
return segment_prime_count(lo, hi);
return LMO_prime_count(hi) - ((lo < 2) ? 0 : LMO_prime_count(lo-1));
return count;
}
UV prime_count_approx(UV n)
{
if (n < 3000000) return segment_prime_count(2, n);
return (UV) (RiemannR( (long double) n ) + 0.5 );
}
/* See http://numbers.computation.free.fr/Constants/Primes/twin.pdf, page 5 */
/* Upper limit is in Wu, Acta Arith 114 (2004). 4.48857*x/(log(x)*log(x) */
UV twin_prime_count_approx(UV n)
{
/* Best would be another estimate for n < ~ 5000 */
if (n < 2000) return twin_prime_count(3,n);
{
/* Sebah and Gourdon 2002 */
const long double two_C2 = 1.32032363169373914785562422L;
const long double two_over_log_two = 2.8853900817779268147198494L;
long double ln = (long double) n;
long double logn = logl(ln);
long double li2 = Ei(logn) + two_over_log_two-ln/logn;
/* try to minimize MSE */
if (n < 32000000) {
long double fm;
if (n < 4000) fm = 0.2952;
else if (n < 8000) fm = 0.3152;
else if (n < 16000) fm = 0.3090;
else if (n < 32000) fm = 0.3096;
else if (n < 64000) fm = 0.3100;
else if (n < 128000) fm = 0.3089;
else if (n < 256000) fm = 0.3099;
else if (n < 600000) fm = .3091 + (n-256000) * (.3056-.3091) / (600000-256000);
else if (n < 1000000) fm = .3062 + (n-600000) * (.3042-.3062) / (1000000-600000);
else if (n < 4000000) fm = .3067 + (n-1000000) * (.3041-.3067) / (4000000-1000000);
else if (n <16000000) fm = .3033 + (n-4000000) * (.2983-.3033) / (16000000-4000000);
else fm = .2980 + (n-16000000) * (.2965-.2980) / (32000000-16000000);
li2 *= fm * logl(12+logn);
}
return (UV) (two_C2 * li2 + 0.5L);
}
}
UV prime_count_lower(UV n)
{
long double fn, fl1, fl2, lower, a;
if (n < 33000) return segment_prime_count(2, n);
fn = (long double) n;
fl1 = logl(n);
fl2 = fl1 * fl1;
if (n <= 300000) { /* Quite accurate and avoids calling Li for speed. */
a = (n < 70200) ? 947 : (n < 176000) ? 904 : 829;
lower = fn / (fl1 - 1 - 1/fl1 - 2.85/fl2 - 13.15/(fl1*fl2) + a/(fl2*fl2));
} else if (n < UVCONST(4000000000)) {
/* Loose enough that FP differences in Li(n) should be ok. */
a = (n < 88783) ? 4.0L
: (n < 300000) ? -3.0L
: (n < 303000) ? 5.0L
: (n < 1100000) ? -7.0L
: (n < 4500000) ? -37.0L
: (n < 10200000) ? -70.0L
: (n < 36900000) ? -53.0L
: (n < 38100000) ? -29.0L
: -84.0L;
lower = Li(fn) - (sqrtl(fn)/fl1) * (1.94L + 2.50L/fl1 + a/fl2);
} else if (fn < 1e19) { /* Büthe 2015 1.9 1511.02032v1.pdf */
lower = Li(fn) - (sqrtl(fn)/fl1) * (1.94L + 3.88L/fl1 + 27.57L/fl2);
} else { /* Büthe 2014 v3 7.2 1410.7015v3.pdf */
lower = Li(fn) - fl1*sqrtl(fn)/25.132741228718345907701147L;
}
return (UV) ceill(lower);
}
typedef struct {
UV thresh;
float aval;
} thresh_t;
static const thresh_t _upper_thresh[] = {
{ 59000, 2.48 },
{ 355991, 2.54 },
{ 3550000, 2.51 },
{ 3560000, 2.49 },
{ 5000000, 2.48 },
{ 8000000, 2.47 },
{ 13000000, 2.46 },
{ 18000000, 2.45 },
{ 31000000, 2.44 },
{ 41000000, 2.43 },
{ 48000000, 2.42 },
{ 119000000, 2.41 },
{ 182000000, 2.40 },
{ 192000000, 2.395 },
{ 213000000, 2.390 },
{ 271000000, 2.385 },
{ 322000000, 2.380 },
{ 400000000, 2.375 },
{ 510000000, 2.370 },
{ 682000000, 2.367 },
{ UVCONST(2953652287), 2.362 }
};
#define NUPPER_THRESH (sizeof(_upper_thresh)/sizeof(_upper_thresh[0]))
UV prime_count_upper(UV n)
{
int i;
long double fn, fl1, fl2, upper, a;
if (n < 33000) return segment_prime_count(2, n);
fn = (long double) n;
fl1 = logl(n);
fl2 = fl1 * fl1;
if (BITS_PER_WORD == 32 || fn <= 821800000.0) { /* Dusart 2010, page 2 */
for (i = 0; i < (int)NUPPER_THRESH; i++)
if (n < _upper_thresh[i].thresh)
break;
a = (i < (int)NUPPER_THRESH) ? _upper_thresh[i].aval : 2.334L;
upper = fn/fl1 * (1.0L + 1.0L/fl1 + a/fl2);
} else if (fn < 1e19) { /* Büthe 2015 1.10 Skewes number lower limit */
a = (fn < 1100000000.0) ? 0.032 /* Empirical */
: (fn < 10010000000.0) ? 0.027 /* Empirical */
: (fn < 101260000000.0) ? 0.021 /* Empirical */
: 0.0;
upper = Li(fn) - a * fl1*sqrtl(fn)/25.132741228718345907701147L;
} else { /* Büthe 2014 7.4 */
upper = Li(fn) + fl1*sqrtl(fn)/25.132741228718345907701147L;
}
return (UV) floorl(upper);
}
static void simple_nth_limits(UV *lo, UV *hi, long double n, long double logn, long double loglogn) {
const long double a = (n < 228) ? .6483 : (n < 948) ? .8032 : (n < 2195) ? .8800 : (n < 39017) ? .9019 : .9484;
*lo = n * (logn + loglogn - 1.0 + ((loglogn-2.10)/logn));
*hi = n * (logn + loglogn - a);
if (*hi < *lo) *hi = MPU_MAX_PRIME;
}
/* The nth prime will be less or equal to this number */
UV nth_prime_upper(UV n)
{
long double fn, flogn, flog2n, upper;
if (n < NPRIMES_SMALL)
return primes_small[n];
fn = (long double) n;
flogn = logl(n);
flog2n = logl(flogn); /* Note distinction between log_2(n) and log^2(n) */
if (n < 688383) {
UV lo,hi;
simple_nth_limits(&lo, &hi, fn, flogn, flog2n);
while (lo < hi) {
UV mid = lo + (hi-lo)/2;
if (prime_count_lower(mid) < n) lo = mid+1;
else hi = mid;
}
return lo;
}
/* Dusart 2010 page 2 */
upper = fn * (flogn + flog2n - 1.0 + ((flog2n-2.00)/flogn));
if (n >= 46254381) {
/* Axler 2017 http//arxiv.org/pdf/1706.03651.pdf Corollary 1.2 */
upper -= fn * ((flog2n*flog2n-6*flog2n+10.667)/(2*flogn*flogn));
} else if (n >= 8009824) {
/* Axler 2013 page viii Korollar G */
upper -= fn * ((flog2n*flog2n-6*flog2n+10.273)/(2*flogn*flogn));
}
if (upper >= (long double)UV_MAX) {
if (n <= MPU_MAX_PRIME_IDX) return MPU_MAX_PRIME;
croak("nth_prime_upper(%"UVuf") overflow", n);
}
return (UV) floorl(upper);
}
/* The nth prime will be greater than or equal to this number */
UV nth_prime_lower(UV n)
{
double fn, flogn, flog2n, lower;
if (n < NPRIMES_SMALL)
return primes_small[n];
fn = (double) n;
flogn = log(n);
flog2n = log(flogn);
/* For small values, do a binary search on the inverse prime count */
if (n < 2000000) {
UV lo,hi;
simple_nth_limits(&lo, &hi, fn, flogn, flog2n);
while (lo < hi) {
UV mid = lo + (hi-lo)/2;
if (prime_count_upper(mid) < n) lo = mid+1;
else hi = mid;
}
return lo;
}
{ /* Axler 2017 http//arxiv.org/pdf/1706.03651.pdf Corollary 1.4 */
double b1 = (n < 56000000) ? 11.200 : 11.508;
lower = fn * (flogn + flog2n-1.0 + ((flog2n-2.00)/flogn) - ((flog2n*flog2n-6*flog2n+b1)/(2*flogn*flogn)));
}
return (UV) ceill(lower);
}
UV nth_prime_approx(UV n)
{
return (n < NPRIMES_SMALL) ? primes_small[n] : inverse_R(n);
}
UV nth_prime(UV n)
{
const unsigned char* cache_sieve;
unsigned char* segment;
UV upper_limit, segbase, segment_size, p, count, target;
/* If very small, return the table entry */
if (n < NPRIMES_SMALL)
return primes_small[n];
/* Determine a bound on the nth prime. We know it comes before this. */
upper_limit = nth_prime_upper(n);
MPUassert(upper_limit > 0, "nth_prime got an upper limit of 0");
p = count = 0;
target = n-3;
/* For relatively small values, generate a sieve and count the results.
*
* For larger values, compute an approximate low estimate, use our fast
* prime count, then segment sieve forwards or backwards for the rest.
*/
if (upper_limit <= get_prime_cache(0, 0) || upper_limit <= 32*1024*30) {
/* Generate a sieve and count. */
segment_size = get_prime_cache(upper_limit, &cache_sieve) / 30;
/* Count up everything in the cached sieve. */
if (segment_size > 0)
count += count_segment_maxcount(cache_sieve, 0, segment_size, target, &p);
release_prime_cache(cache_sieve);
} else {
/* A binary search on RiemannR is nice, but ends up either often being
* being higher (requiring going backwards) or biased and then far too
* low. Using the inverse Li is easier and more consistent. */
UV lower_limit = inverse_li(n);
/* For even better performance, add in half the usual correction, which
* will get us even closer, so even less sieving required. However, it
* is now possible to get a result higher than the value, so we'll need
* to handle that case. It still ends up being a better deal than R,
* given that we don't have a fast backward sieve. */
lower_limit += inverse_li(isqrt(n))/4;
segment_size = lower_limit / 30;
lower_limit = 30 * segment_size - 1;
count = prime_count(2,lower_limit);
/* printf("We've estimated %lu too %s.\n", (count>n)?count-n:n-count, (count>n)?"FAR":"little"); */
/* printf("Our limit %lu %s a prime\n", lower_limit, is_prime(lower_limit) ? "is" : "is not"); */
if (count >= n) { /* Too far. Walk backwards */
if (is_prime(lower_limit)) count--;
for (p = 0; p <= (count-n); p++)
lower_limit = prev_prime(lower_limit);
return lower_limit;
}
count -= 3;
/* Make sure the segment siever won't have to keep resieving. */
prime_precalc(isqrt(upper_limit));
}
if (count == target)
return p;
/* Start segment sieving. Get memory to sieve into. */
segbase = segment_size;
segment = get_prime_segment(&segment_size);
while (count < target) {
/* Limit the segment size if we know the answer comes earlier */
if ( (30*(segbase+segment_size)+29) > upper_limit )
segment_size = (upper_limit - segbase*30 + 30) / 30;
/* Do the actual sieving in the range */
sieve_segment(segment, segbase, segbase + segment_size-1);
/* Count up everything in this segment */
count += count_segment_maxcount(segment, 30*segbase, segment_size, target-count, &p);
if (count < target)
segbase += segment_size;
}
release_prime_segment(segment);
MPUassert(count == target, "nth_prime got incorrect count");
return ( (segbase*30) + p );
}
/******************************************************************************/
/* TWIN PRIMES */
/******************************************************************************/
#if BITS_PER_WORD < 64
static const UV twin_steps[] =
{58980,48427,45485,43861,42348,41457,40908,39984,39640,39222,
373059,353109,341253,332437,326131,320567,315883,312511,309244,
2963535,2822103,2734294,2673728,
};
static const unsigned int twin_num_exponents = 3;
static const unsigned int twin_last_mult = 4; /* 4000M */
#else
static const UV twin_steps[] =
{58980,48427,45485,43861,42348,41457,40908,39984,39640,39222,
373059,353109,341253,332437,326131,320567,315883,312511,309244,
2963535,2822103,2734294,2673728,2626243,2585752,2554015,2527034,2501469,
24096420,23046519,22401089,21946975,21590715,21300632,21060884,20854501,20665634,
199708605,191801047,186932018,183404596,180694619,178477447,176604059,174989299,173597482,
1682185723,1620989842,1583071291,1555660927,1534349481,1517031854,1502382532,1489745250, 1478662752,
14364197903,13879821868,13578563641,13361034187,13191416949,13053013447,12936030624,12835090276, 12746487898,
124078078589,120182602778,117753842540,115995331742,114622738809,113499818125,112551549250,111732637241,111012321565,
1082549061370,1050759497170,1030883829367,1016473645857,1005206830409,995980796683,988183329733,981441437376,975508027029,
9527651328494, 9264843314051, 9100153493509, 8980561036751, 8886953365929, 8810223086411, 8745329823109, 8689179566509, 8639748641098,
84499489470819, 82302056642520, 80922166953330, 79918799449753, 79132610984280, 78487688897426, 77941865286827, 77469296499217, 77053075040105,
754527610498466, 735967887462370, 724291736697048,
};
static const unsigned int twin_num_exponents = 12;
static const unsigned int twin_last_mult = 4; /* 4e19 */
#endif
UV twin_prime_count(UV beg, UV end)
{
unsigned char* segment;
UV sum = 0;
/* First use the tables of #e# from 1e7 to 2e16. */
if (beg <= 3 && end >= 10000000) {
UV mult, exp, step = 0, base = 10000000;
for (exp = 0; exp < twin_num_exponents && end >= base; exp++) {
for (mult = 1; mult < 10 && end >= mult*base; mult++) {
sum += twin_steps[step++];
beg = mult*base;
if (exp == twin_num_exponents-1 && mult >= twin_last_mult) break;
}
base *= 10;
}
}
if (beg <= 3 && end >= 3) sum++;
if (beg <= 5 && end >= 5) sum++;
if (beg < 11) beg = 7;
if (beg <= end) {
/* Make end points odd */
beg |= 1;
end = (end-1) | 1;
/* Cheesy way of counting the partial-byte edges */
while ((beg % 30) != 1) {
if (is_prime(beg) && is_prime(beg+2) && beg <= end) sum++;
beg += 2;
}
while ((end % 30) != 29) {
if (is_prime(end) && is_prime(end+2) && beg <= end) sum++;
end -= 2; if (beg > end) break;
}
}
if (beg <= end) {
UV seg_base, seg_low, seg_high;
void* ctx = start_segment_primes(beg, end, &segment);
while (next_segment_primes(ctx, &seg_base, &seg_low, &seg_high)) {
UV bytes = seg_high/30 - seg_low/30 + 1;
unsigned char s;
const unsigned char* sp = segment;
const unsigned char* const spend = segment + bytes - 1;
while (sp < spend) {
s = *sp++;
if (!(s & 0x0C)) sum++;
if (!(s & 0x30)) sum++;
if (!(s & 0x80) && !(*sp & 0x01)) sum++;
}
s = *sp;
if (!(s & 0x0C)) sum++;
if (!(s & 0x30)) sum++;
if (!(s & 0x80) && is_prime(seg_high+2)) sum++;
}
end_segment_primes(ctx);
}
return sum;
}
UV nth_twin_prime(UV n)
{
unsigned char* segment;
double dend;
UV nth = 0;
UV beg, end;
if (n < 6) {
switch (n) {
case 0: nth = 0; break;
case 1: nth = 3; break;
case 2: nth = 5; break;
case 3: nth =11; break;
case 4: nth =17; break;
case 5:
default: nth =29; break;
}
return nth;
}
end = UV_MAX - 16;
dend = 800.0 + 1.01L * (double)nth_twin_prime_approx(n);
if (dend < (double)end) end = (UV) dend;
beg = 2;
if (n > 58980) { /* Use twin_prime_count tables to accelerate if possible */
UV mult, exp, step = 0, base = 10000000;
for (exp = 0; exp < twin_num_exponents && end >= base; exp++) {
for (mult = 1; mult < 10 && n > twin_steps[step]; mult++) {
n -= twin_steps[step++];
beg = mult*base;
if (exp == twin_num_exponents-1 && mult >= twin_last_mult) break;
}
base *= 10;
}
}
if (beg == 2) { beg = 31; n -= 5; }
{
UV seg_base, seg_low, seg_high;
void* ctx = start_segment_primes(beg, end, &segment);
while (n && next_segment_primes(ctx, &seg_base, &seg_low, &seg_high)) {
UV p, bytes = seg_high/30 - seg_low/30 + 1;
UV s = ((UV)segment[0]) << 8;
for (p = 0; p < bytes; p++) {
s >>= 8;
if (p+1 < bytes) s |= (((UV)segment[p+1]) << 8);
else if (!is_prime(seg_high+2)) s |= 0xFF00;
if (!(s & 0x000C) && !--n) { nth=seg_base+p*30+11; break; }
if (!(s & 0x0030) && !--n) { nth=seg_base+p*30+17; break; }
if (!(s & 0x0180) && !--n) { nth=seg_base+p*30+29; break; }
}
}
end_segment_primes(ctx);
}
return nth;
}
UV nth_twin_prime_approx(UV n)
{
long double fn = (long double) n;
long double flogn = logl(n);
long double fnlog2n = fn * flogn * flogn;
UV lo, hi;
if (n < 6)
return nth_twin_prime(n);
/* Binary search on the TPC estimate.
* Good results require that the TPC estimate is both fast and accurate.
* These bounds are good for the actual nth_twin_prime values.
*/
lo = (UV) (0.9 * fnlog2n);
hi = (UV) ( (n >= 1e16) ? (1.04 * fnlog2n) :
(n >= 1e13) ? (1.10 * fnlog2n) :
(n >= 1e7 ) ? (1.31 * fnlog2n) :
(n >= 1200) ? (1.70 * fnlog2n) :
(2.3 * fnlog2n + 5) );
if (hi <= lo) hi = UV_MAX;
while (lo < hi) {
UV mid = lo + (hi-lo)/2;
if (twin_prime_count_approx(mid) < fn) lo = mid+1;
else hi = mid;
}
return lo;
}
/******************************************************************************/
/* SUMS */
/******************************************************************************/
/* The fastest way to compute the sum of primes is using a combinatorial
* algorithm such as Deleglise 2012. Since this code is purely native,
* it will overflow a 64-bit result quite quickly. Hence a relatively small
* table plus sum over sieved primes works quite well.
*
* The following info is useful if we ever return 128-bit results or for a
* GMP implementation.
*
* Combinatorial sum of primes < n. Call with phisum(n, isqrt(n)).
* Needs optimization, either caching, Lehmer, or LMO.
* http://mathoverflow.net/questions/81443/fastest-algorithm-to-compute-the-sum-of-primes
* http://www.ams.org/journals/mcom/2009-78-268/S0025-5718-09-02249-2/S0025-5718-09-02249-2.pdf
* http://mathematica.stackexchange.com/questions/80291/efficient-way-to-sum-all-the-primes-below-n-million-in-mathematica
* Deleglise 2012, page 27, simple Meissel:
* y = x^1/3
* a = Pi(y)
* Pi_f(x) = phisum(x,a) + Pi_f(y) - 1 - P_2(x,a)
* P_2(x,a) = sum prime p : y < p <= sqrt(x) of f(p) * Pi_f(x/p) -
* sum prime p : y < p <= sqrt(x) of f(p) * Pi_f(p-1)
*/
static const unsigned char byte_sum[256] =
{120,119,113,112,109,108,102,101,107,106,100,99,96,95,89,88,103,102,96,95,92,
91,85,84,90,89,83,82,79,78,72,71,101,100,94,93,90,89,83,82,88,87,81,80,77,
76,70,69,84,83,77,76,73,72,66,65,71,70,64,63,60,59,53,52,97,96,90,89,86,85,
79,78,84,83,77,76,73,72,66,65,80,79,73,72,69,68,62,61,67,66,60,59,56,55,49,
48,78,77,71,70,67,66,60,59,65,64,58,57,54,53,47,46,61,60,54,53,50,49,43,42,
48,47,41,40,37,36,30,29,91,90,84,83,80,79,73,72,78,77,71,70,67,66,60,59,74,
73,67,66,63,62,56,55,61,60,54,53,50,49,43,42,72,71,65,64,61,60,54,53,59,58,
52,51,48,47,41,40,55,54,48,47,44,43,37,36,42,41,35,34,31,30,24,23,68,67,61,
60,57,56,50,49,55,54,48,47,44,43,37,36,51,50,44,43,40,39,33,32,38,37,31,30,
27,26,20,19,49,48,42,41,38,37,31,30,36,35,29,28,25,24,18,17,32,31,25,24,21,
20,14,13,19,18,12,11,8,7,1,0};
#if BITS_PER_WORD == 64
/* We have a much more limited range, so use a fixed interval. We should be
* able to get any 64-bit sum in under a half-second. */
static const UV sum_table_2e8[] =
{1075207199997324,3071230303170813,4990865886639877,6872723092050268,8729485610396243,10566436676784677,12388862798895708,14198556341669206,15997206121881531,17783028661796383,19566685687136351,21339485298848693,23108856419719148,
24861364231151903,26619321031799321,28368484289421890,30110050320271201,31856321671656548,33592089385327108,35316546074029522,37040262208390735,38774260466286299,40490125006181147,42207686658844380,43915802985817228,45635106002281013,
47337822860157465,49047713696453759,50750666660265584,52449748364487290,54152689180758005,55832433395290183,57540651847418233,59224867245128289,60907462954737468,62597192477315868,64283665223856098,65961576139329367,67641982565760928,
69339211720915217,71006044680007261,72690896543747616,74358564592509127,76016548794894677,77694517638354266,79351385193517953,81053240048141953,82698120948724835,84380724263091726,86028655116421543,87679091888973563,89348007111430334,
90995902774878695,92678527127292212,94313220293410120,95988730932107432,97603162494502485,99310622699836698,100935243057337310,102572075478649557,104236362884241550,105885045921116836,107546170993472638,109163445284201278,
110835950755374921,112461991135144669,114116351921245042,115740770232532531,117408250788520189,119007914428335965,120652479429703269,122317415246500401,123951466213858688,125596789655927842,127204379051939418,128867944265073217,
130480037123800711,132121840147764197,133752985360747726,135365954823762234,137014594650995101,138614165689305879,140269121741383097,141915099618762647,143529289083557618,145146413750649432,146751434858695468,148397902396643807,
149990139346918801,151661665434334577,153236861034424304,154885985064643097,156500983286383741,158120868946747299,159735201435796748,161399264792716319,162999489977602579,164566400448130092,166219688860475191,167836981098849796,
169447127305804401,171078187147848898,172678849082290997,174284436375728242,175918609754056455,177525046501311788,179125593738290153,180765176633753371,182338473848291683,183966529541155489,185585792988238475,187131988176321434,
188797837140841381,190397649440649965,191981841583560122,193609739194967419,195166830650558070,196865965063113041,198400070713177440,200057161591648721,201621899486413406,203238279253414934,204790684829891896,206407676204061001,
208061050481364659,209641606658938873,211192088300183855,212855420483750498,214394145510853736,216036806225784861,217628995137940563,219277567478725189,220833877268454872,222430818525363309,224007307616922530,225640739533952807,
227213096159236934,228853318075566255,230401824696558125,231961445347821085,233593317860593895,235124654760954338,236777716068869769,238431514923528303,239965003913481640,241515977959535845,243129874530821395};
#define N_SUM_TABLE (sizeof(sum_table_2e8)/sizeof(sum_table_2e8[0]))
#endif
/* Add n to the double-word hi,lo */
#define ADD_128(hi, lo, n) \
do { UV _n = n; \
if (_n > (UV_MAX-lo)) { hi++; if (hi == 0) overflow = 1; } \
lo += _n; } while (0)
#define SET_128(hi, lo, n) \
do { hi = (UV) (((n) >> 64) & UV_MAX); \
lo = (UV) (((n) ) & UV_MAX); } while (0)
/* Legendre method for prime sum */
int sum_primes128(UV n, UV *hi_sum, UV *lo_sum) {
#if BITS_PER_WORD == 64 && HAVE_UINT128
uint128_t *V, *S;
UV j, k, r = isqrt(n), r2 = r + n/(r+1);
New(0, V, r2+1, uint128_t);
New(0, S, r2+1, uint128_t);
for (k = 0; k <= r2; k++) {
uint128_t v = (k <= r) ? k : n/(r2-k+1);
V[k] = v;
S[k] = (v*(v+1))/2 - 1;
}
START_DO_FOR_EACH_PRIME(2, r) {
uint128_t a, b, sp = S[p-1], p2 = ((uint128_t)p) * p;
for (j = k-1; j > 1 && V[j] >= p2; j--) {
a = V[j], b = a/p;
if (a > r) a = r2 - n/a + 1;
if (b > r) b = r2 - n/b + 1;
S[a] -= p * (S[b] - sp); /* sp = sum of primes less than p */
}
} END_DO_FOR_EACH_PRIME;
SET_128(*hi_sum, *lo_sum, S[r2]);
Safefree(V);
Safefree(S);
return 1;
#else
return 0;
#endif
}
int sum_primes(UV low, UV high, UV *return_sum) {
UV sum = 0;
int overflow = 0;
if ((low <= 2) && (high >= 2)) sum += 2;
if ((low <= 3) && (high >= 3)) sum += 3;
if ((low <= 5) && (high >= 5)) sum += 5;
if (low < 7) low = 7;
/* If we know the range will overflow, return now */
#if BITS_PER_WORD == 64
if (low == 7 && high >= 29505444491) return 0;
if (low >= 1e10 && (high-low) >= 32e9) return 0;
if (low >= 1e13 && (high-low) >= 5e7) return 0;
#else
if (low == 7 && high >= 323381) return 0;
#endif
#if 1 && BITS_PER_WORD == 64 /* Tables */
if (low == 7 && high >= 2e8) {
UV step;
for (step = 1; high >= (step * 2e8) && step < N_SUM_TABLE; step++) {
sum += sum_table_2e8[step-1];
low = step * 2e8;
}
}
#endif
if (low <= high) {
unsigned char* segment;
UV seg_base, seg_low, seg_high;
void* ctx = start_segment_primes(low, high, &segment);
while (!overflow && next_segment_primes(ctx, &seg_base, &seg_low, &seg_high)) {
UV bytes = seg_high/30 - seg_low/30 + 1;
unsigned char s;
unsigned char* sp = segment;
unsigned char* const spend = segment + bytes - 1;
UV i, p, pbase = 30*(seg_low/30);
/* Clear primes before and after our range */
p = pbase;
for (i = 0; i < 8 && p+wheel30[i] < low; i++)
if ( (*sp & (1<<i)) == 0 )
*sp |= (1 << i);
p = 30*(seg_high/30);
for (i = 0; i < 8; i++)
if ( (*spend & (1<<i)) == 0 && p+wheel30[i] > high )
*spend |= (1 << i);
while (sp <= spend) {
s = *sp++;
if (sum < (UV_MAX >> 3) && pbase < (UV_MAX >> 5)) {
/* sum block of 8 all at once */
sum += pbase * byte_zeros[s] + byte_sum[s];
} else {
/* sum block of 8, checking for overflow at each step */
for (i = 0; i < byte_zeros[s]; i++) {
if (sum+pbase < sum) overflow = 1;
sum += pbase;
}
if (sum+byte_sum[s] < sum) overflow = 1;
sum += byte_sum[s];
if (overflow) break;
}
pbase += 30;
}
}
end_segment_primes(ctx);
}
if (!overflow && return_sum != 0) *return_sum = sum;
return !overflow;
}
double ramanujan_sa_gn(UV un)
{
long double n = (long double) un;
long double logn = logl(n);
long double log2 = logl(2);
return (double)( (logn + logl(logn) - log2 - 0.5) / (log2 + 0.5) );
}