585 lines
16 KiB
Python
585 lines
16 KiB
Python
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"""
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Utility functions for integer math.
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TODO: rename, cleanup, perhaps move the gmpy wrapper code
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here from settings.py
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"""
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import math
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from bisect import bisect
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from .backend import xrange
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from .backend import BACKEND, gmpy, sage, sage_utils, MPZ, MPZ_ONE, MPZ_ZERO
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small_trailing = [0] * 256
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for j in range(1,8):
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small_trailing[1<<j::1<<(j+1)] = [j] * (1<<(7-j))
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def giant_steps(start, target, n=2):
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"""
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Return a list of integers ~=
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[start, n*start, ..., target/n^2, target/n, target]
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but conservatively rounded so that the quotient between two
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successive elements is actually slightly less than n.
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With n = 2, this describes suitable precision steps for a
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quadratically convergent algorithm such as Newton's method;
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with n = 3 steps for cubic convergence (Halley's method), etc.
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>>> giant_steps(50,1000)
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[66, 128, 253, 502, 1000]
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>>> giant_steps(50,1000,4)
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[65, 252, 1000]
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"""
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L = [target]
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while L[-1] > start*n:
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L = L + [L[-1]//n + 2]
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return L[::-1]
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def rshift(x, n):
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"""For an integer x, calculate x >> n with the fastest (floor)
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rounding. Unlike the plain Python expression (x >> n), n is
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allowed to be negative, in which case a left shift is performed."""
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if n >= 0: return x >> n
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else: return x << (-n)
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def lshift(x, n):
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"""For an integer x, calculate x << n. Unlike the plain Python
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expression (x << n), n is allowed to be negative, in which case a
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right shift with default (floor) rounding is performed."""
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if n >= 0: return x << n
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else: return x >> (-n)
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if BACKEND == 'sage':
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import operator
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rshift = operator.rshift
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lshift = operator.lshift
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def python_trailing(n):
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"""Count the number of trailing zero bits in abs(n)."""
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if not n:
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return 0
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low_byte = n & 0xff
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if low_byte:
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return small_trailing[low_byte]
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t = 8
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n >>= 8
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while not n & 0xff:
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n >>= 8
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t += 8
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return t + small_trailing[n & 0xff]
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if BACKEND == 'gmpy':
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if gmpy.version() >= '2':
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def gmpy_trailing(n):
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"""Count the number of trailing zero bits in abs(n) using gmpy."""
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if n: return MPZ(n).bit_scan1()
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else: return 0
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else:
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def gmpy_trailing(n):
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"""Count the number of trailing zero bits in abs(n) using gmpy."""
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if n: return MPZ(n).scan1()
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else: return 0
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# Small powers of 2
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powers = [1<<_ for _ in range(300)]
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def python_bitcount(n):
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"""Calculate bit size of the nonnegative integer n."""
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bc = bisect(powers, n)
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if bc != 300:
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return bc
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bc = int(math.log(n, 2)) - 4
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return bc + bctable[n>>bc]
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def gmpy_bitcount(n):
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"""Calculate bit size of the nonnegative integer n."""
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if n: return MPZ(n).numdigits(2)
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else: return 0
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#def sage_bitcount(n):
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# if n: return MPZ(n).nbits()
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# else: return 0
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def sage_trailing(n):
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return MPZ(n).trailing_zero_bits()
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if BACKEND == 'gmpy':
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bitcount = gmpy_bitcount
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trailing = gmpy_trailing
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elif BACKEND == 'sage':
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sage_bitcount = sage_utils.bitcount
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bitcount = sage_bitcount
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trailing = sage_trailing
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else:
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bitcount = python_bitcount
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trailing = python_trailing
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if BACKEND == 'gmpy' and 'bit_length' in dir(gmpy):
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bitcount = gmpy.bit_length
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# Used to avoid slow function calls as far as possible
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trailtable = [trailing(n) for n in range(256)]
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bctable = [bitcount(n) for n in range(1024)]
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# TODO: speed up for bases 2, 4, 8, 16, ...
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def bin_to_radix(x, xbits, base, bdigits):
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"""Changes radix of a fixed-point number; i.e., converts
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x * 2**xbits to floor(x * 10**bdigits)."""
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return x * (MPZ(base)**bdigits) >> xbits
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stddigits = '0123456789abcdefghijklmnopqrstuvwxyz'
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def small_numeral(n, base=10, digits=stddigits):
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"""Return the string numeral of a positive integer in an arbitrary
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base. Most efficient for small input."""
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if base == 10:
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return str(n)
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digs = []
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while n:
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n, digit = divmod(n, base)
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digs.append(digits[digit])
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return "".join(digs[::-1])
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def numeral_python(n, base=10, size=0, digits=stddigits):
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"""Represent the integer n as a string of digits in the given base.
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Recursive division is used to make this function about 3x faster
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than Python's str() for converting integers to decimal strings.
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The 'size' parameters specifies the number of digits in n; this
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number is only used to determine splitting points and need not be
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exact."""
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if n <= 0:
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if not n:
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return "0"
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return "-" + numeral(-n, base, size, digits)
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# Fast enough to do directly
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if size < 250:
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return small_numeral(n, base, digits)
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# Divide in half
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half = (size // 2) + (size & 1)
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A, B = divmod(n, base**half)
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ad = numeral(A, base, half, digits)
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bd = numeral(B, base, half, digits).rjust(half, "0")
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return ad + bd
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def numeral_gmpy(n, base=10, size=0, digits=stddigits):
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"""Represent the integer n as a string of digits in the given base.
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Recursive division is used to make this function about 3x faster
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than Python's str() for converting integers to decimal strings.
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The 'size' parameters specifies the number of digits in n; this
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number is only used to determine splitting points and need not be
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exact."""
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if n < 0:
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return "-" + numeral(-n, base, size, digits)
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# gmpy.digits() may cause a segmentation fault when trying to convert
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# extremely large values to a string. The size limit may need to be
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# adjusted on some platforms, but 1500000 works on Windows and Linux.
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if size < 1500000:
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return gmpy.digits(n, base)
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# Divide in half
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half = (size // 2) + (size & 1)
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A, B = divmod(n, MPZ(base)**half)
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ad = numeral(A, base, half, digits)
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bd = numeral(B, base, half, digits).rjust(half, "0")
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return ad + bd
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if BACKEND == "gmpy":
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numeral = numeral_gmpy
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else:
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numeral = numeral_python
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_1_800 = 1<<800
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_1_600 = 1<<600
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_1_400 = 1<<400
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_1_200 = 1<<200
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_1_100 = 1<<100
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_1_50 = 1<<50
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def isqrt_small_python(x):
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"""
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Correctly (floor) rounded integer square root, using
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division. Fast up to ~200 digits.
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"""
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if not x:
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return x
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if x < _1_800:
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# Exact with IEEE double precision arithmetic
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if x < _1_50:
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return int(x**0.5)
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# Initial estimate can be any integer >= the true root; round up
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r = int(x**0.5 * 1.00000000000001) + 1
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else:
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bc = bitcount(x)
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n = bc//2
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r = int((x>>(2*n-100))**0.5+2)<<(n-50) # +2 is to round up
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# The following iteration now precisely computes floor(sqrt(x))
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# See e.g. Crandall & Pomerance, "Prime Numbers: A Computational
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# Perspective"
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while 1:
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y = (r+x//r)>>1
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if y >= r:
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return r
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r = y
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def isqrt_fast_python(x):
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"""
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Fast approximate integer square root, computed using division-free
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Newton iteration for large x. For random integers the result is almost
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always correct (floor(sqrt(x))), but is 1 ulp too small with a roughly
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0.1% probability. If x is very close to an exact square, the answer is
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1 ulp wrong with high probability.
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With 0 guard bits, the largest error over a set of 10^5 random
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inputs of size 1-10^5 bits was 3 ulp. The use of 10 guard bits
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almost certainly guarantees a max 1 ulp error.
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"""
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# Use direct division-based iteration if sqrt(x) < 2^400
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# Assume floating-point square root accurate to within 1 ulp, then:
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# 0 Newton iterations good to 52 bits
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# 1 Newton iterations good to 104 bits
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# 2 Newton iterations good to 208 bits
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# 3 Newton iterations good to 416 bits
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if x < _1_800:
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y = int(x**0.5)
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if x >= _1_100:
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y = (y + x//y) >> 1
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if x >= _1_200:
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y = (y + x//y) >> 1
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if x >= _1_400:
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y = (y + x//y) >> 1
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return y
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bc = bitcount(x)
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guard_bits = 10
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x <<= 2*guard_bits
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bc += 2*guard_bits
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bc += (bc&1)
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hbc = bc//2
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startprec = min(50, hbc)
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# Newton iteration for 1/sqrt(x), with floating-point starting value
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r = int(2.0**(2*startprec) * (x >> (bc-2*startprec)) ** -0.5)
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pp = startprec
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for p in giant_steps(startprec, hbc):
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# r**2, scaled from real size 2**(-bc) to 2**p
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r2 = (r*r) >> (2*pp - p)
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# x*r**2, scaled from real size ~1.0 to 2**p
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xr2 = ((x >> (bc-p)) * r2) >> p
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# New value of r, scaled from real size 2**(-bc/2) to 2**p
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r = (r * ((3<<p) - xr2)) >> (pp+1)
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pp = p
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# (1/sqrt(x))*x = sqrt(x)
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return (r*(x>>hbc)) >> (p+guard_bits)
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def sqrtrem_python(x):
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"""Correctly rounded integer (floor) square root with remainder."""
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# to check cutoff:
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# plot(lambda x: timing(isqrt, 2**int(x)), [0,2000])
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if x < _1_600:
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y = isqrt_small_python(x)
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return y, x - y*y
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y = isqrt_fast_python(x) + 1
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rem = x - y*y
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# Correct remainder
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while rem < 0:
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y -= 1
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rem += (1+2*y)
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else:
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if rem:
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while rem > 2*(1+y):
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y += 1
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rem -= (1+2*y)
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return y, rem
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def isqrt_python(x):
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"""Integer square root with correct (floor) rounding."""
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return sqrtrem_python(x)[0]
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def sqrt_fixed(x, prec):
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return isqrt_fast(x<<prec)
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sqrt_fixed2 = sqrt_fixed
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if BACKEND == 'gmpy':
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if gmpy.version() >= '2':
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isqrt_small = isqrt_fast = isqrt = gmpy.isqrt
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sqrtrem = gmpy.isqrt_rem
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else:
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isqrt_small = isqrt_fast = isqrt = gmpy.sqrt
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sqrtrem = gmpy.sqrtrem
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elif BACKEND == 'sage':
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isqrt_small = isqrt_fast = isqrt = \
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getattr(sage_utils, "isqrt", lambda n: MPZ(n).isqrt())
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sqrtrem = lambda n: MPZ(n).sqrtrem()
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else:
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isqrt_small = isqrt_small_python
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isqrt_fast = isqrt_fast_python
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isqrt = isqrt_python
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sqrtrem = sqrtrem_python
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def ifib(n, _cache={}):
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"""Computes the nth Fibonacci number as an integer, for
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integer n."""
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if n < 0:
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return (-1)**(-n+1) * ifib(-n)
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if n in _cache:
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return _cache[n]
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m = n
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# Use Dijkstra's logarithmic algorithm
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# The following implementation is basically equivalent to
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# http://en.literateprograms.org/Fibonacci_numbers_(Scheme)
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a, b, p, q = MPZ_ONE, MPZ_ZERO, MPZ_ZERO, MPZ_ONE
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while n:
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if n & 1:
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aq = a*q
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a, b = b*q+aq+a*p, b*p+aq
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n -= 1
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else:
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qq = q*q
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p, q = p*p+qq, qq+2*p*q
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n >>= 1
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if m < 250:
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_cache[m] = b
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return b
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MAX_FACTORIAL_CACHE = 1000
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def ifac(n, memo={0:1, 1:1}):
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"""Return n factorial (for integers n >= 0 only)."""
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f = memo.get(n)
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if f:
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return f
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k = len(memo)
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p = memo[k-1]
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MAX = MAX_FACTORIAL_CACHE
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while k <= n:
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p *= k
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if k <= MAX:
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memo[k] = p
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k += 1
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return p
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def ifac2(n, memo_pair=[{0:1}, {1:1}]):
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"""Return n!! (double factorial), integers n >= 0 only."""
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memo = memo_pair[n&1]
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f = memo.get(n)
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if f:
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return f
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k = max(memo)
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p = memo[k]
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MAX = MAX_FACTORIAL_CACHE
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while k < n:
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k += 2
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p *= k
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if k <= MAX:
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memo[k] = p
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return p
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if BACKEND == 'gmpy':
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ifac = gmpy.fac
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elif BACKEND == 'sage':
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ifac = lambda n: int(sage.factorial(n))
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ifib = sage.fibonacci
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def list_primes(n):
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n = n + 1
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sieve = list(xrange(n))
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sieve[:2] = [0, 0]
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for i in xrange(2, int(n**0.5)+1):
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if sieve[i]:
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for j in xrange(i**2, n, i):
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sieve[j] = 0
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return [p for p in sieve if p]
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if BACKEND == 'sage':
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# Note: it is *VERY* important for performance that we convert
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# the list to Python ints.
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def list_primes(n):
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return [int(_) for _ in sage.primes(n+1)]
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small_odd_primes = (3,5,7,11,13,17,19,23,29,31,37,41,43,47)
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small_odd_primes_set = set(small_odd_primes)
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def isprime(n):
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"""
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Determines whether n is a prime number. A probabilistic test is
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performed if n is very large. No special trick is used for detecting
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perfect powers.
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>>> sum(list_primes(100000))
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454396537
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>>> sum(n*isprime(n) for n in range(100000))
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454396537
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"""
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n = int(n)
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if not n & 1:
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return n == 2
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if n < 50:
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return n in small_odd_primes_set
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|
for p in small_odd_primes:
|
||
|
if not n % p:
|
||
|
return False
|
||
|
m = n-1
|
||
|
s = trailing(m)
|
||
|
d = m >> s
|
||
|
def test(a):
|
||
|
x = pow(a,d,n)
|
||
|
if x == 1 or x == m:
|
||
|
return True
|
||
|
for r in xrange(1,s):
|
||
|
x = x**2 % n
|
||
|
if x == m:
|
||
|
return True
|
||
|
return False
|
||
|
# See http://primes.utm.edu/prove/prove2_3.html
|
||
|
if n < 1373653:
|
||
|
witnesses = [2,3]
|
||
|
elif n < 341550071728321:
|
||
|
witnesses = [2,3,5,7,11,13,17]
|
||
|
else:
|
||
|
witnesses = small_odd_primes
|
||
|
for a in witnesses:
|
||
|
if not test(a):
|
||
|
return False
|
||
|
return True
|
||
|
|
||
|
def moebius(n):
|
||
|
"""
|
||
|
Evaluates the Moebius function which is `mu(n) = (-1)^k` if `n`
|
||
|
is a product of `k` distinct primes and `mu(n) = 0` otherwise.
|
||
|
|
||
|
TODO: speed up using factorization
|
||
|
"""
|
||
|
n = abs(int(n))
|
||
|
if n < 2:
|
||
|
return n
|
||
|
factors = []
|
||
|
for p in xrange(2, n+1):
|
||
|
if not (n % p):
|
||
|
if not (n % p**2):
|
||
|
return 0
|
||
|
if not sum(p % f for f in factors):
|
||
|
factors.append(p)
|
||
|
return (-1)**len(factors)
|
||
|
|
||
|
def gcd(*args):
|
||
|
a = 0
|
||
|
for b in args:
|
||
|
if a:
|
||
|
while b:
|
||
|
a, b = b, a % b
|
||
|
else:
|
||
|
a = b
|
||
|
return a
|
||
|
|
||
|
|
||
|
# Comment by Juan Arias de Reyna:
|
||
|
#
|
||
|
# I learn this method to compute EulerE[2n] from van de Lune.
|
||
|
#
|
||
|
# We apply the formula EulerE[2n] = (-1)^n 2**(-2n) sum_{j=0}^n a(2n,2j+1)
|
||
|
#
|
||
|
# where the numbers a(n,j) vanish for j > n+1 or j <= -1 and satisfies
|
||
|
#
|
||
|
# a(0,-1) = a(0,0) = 0; a(0,1)= 1; a(0,2) = a(0,3) = 0
|
||
|
#
|
||
|
# a(n,j) = a(n-1,j) when n+j is even
|
||
|
# a(n,j) = (j-1) a(n-1,j-1) + (j+1) a(n-1,j+1) when n+j is odd
|
||
|
#
|
||
|
#
|
||
|
# But we can use only one array unidimensional a(j) since to compute
|
||
|
# a(n,j) we only need to know a(n-1,k) where k and j are of different parity
|
||
|
# and we have not to conserve the used values.
|
||
|
#
|
||
|
# We cached up the values of Euler numbers to sufficiently high order.
|
||
|
#
|
||
|
# Important Observation: If we pretend to use the numbers
|
||
|
# EulerE[1], EulerE[2], ... , EulerE[n]
|
||
|
# it is convenient to compute first EulerE[n], since the algorithm
|
||
|
# computes first all
|
||
|
# the previous ones, and keeps them in the CACHE
|
||
|
|
||
|
MAX_EULER_CACHE = 500
|
||
|
|
||
|
def eulernum(m, _cache={0:MPZ_ONE}):
|
||
|
r"""
|
||
|
Computes the Euler numbers `E(n)`, which can be defined as
|
||
|
coefficients of the Taylor expansion of `1/cosh x`:
|
||
|
|
||
|
.. math ::
|
||
|
|
||
|
\frac{1}{\cosh x} = \sum_{n=0}^\infty \frac{E_n}{n!} x^n
|
||
|
|
||
|
Example::
|
||
|
|
||
|
>>> [int(eulernum(n)) for n in range(11)]
|
||
|
[1, 0, -1, 0, 5, 0, -61, 0, 1385, 0, -50521]
|
||
|
>>> [int(eulernum(n)) for n in range(11)] # test cache
|
||
|
[1, 0, -1, 0, 5, 0, -61, 0, 1385, 0, -50521]
|
||
|
|
||
|
"""
|
||
|
# for odd m > 1, the Euler numbers are zero
|
||
|
if m & 1:
|
||
|
return MPZ_ZERO
|
||
|
f = _cache.get(m)
|
||
|
if f:
|
||
|
return f
|
||
|
MAX = MAX_EULER_CACHE
|
||
|
n = m
|
||
|
a = [MPZ(_) for _ in [0,0,1,0,0,0]]
|
||
|
for n in range(1, m+1):
|
||
|
for j in range(n+1, -1, -2):
|
||
|
a[j+1] = (j-1)*a[j] + (j+1)*a[j+2]
|
||
|
a.append(0)
|
||
|
suma = 0
|
||
|
for k in range(n+1, -1, -2):
|
||
|
suma += a[k+1]
|
||
|
if n <= MAX:
|
||
|
_cache[n] = ((-1)**(n//2))*(suma // 2**n)
|
||
|
if n == m:
|
||
|
return ((-1)**(n//2))*suma // 2**n
|
||
|
|
||
|
def stirling1(n, k):
|
||
|
"""
|
||
|
Stirling number of the first kind.
|
||
|
"""
|
||
|
if n < 0 or k < 0:
|
||
|
raise ValueError
|
||
|
if k >= n:
|
||
|
return MPZ(n == k)
|
||
|
if k < 1:
|
||
|
return MPZ_ZERO
|
||
|
L = [MPZ_ZERO] * (k+1)
|
||
|
L[1] = MPZ_ONE
|
||
|
for m in xrange(2, n+1):
|
||
|
for j in xrange(min(k, m), 0, -1):
|
||
|
L[j] = (m-1) * L[j] + L[j-1]
|
||
|
return (-1)**(n+k) * L[k]
|
||
|
|
||
|
def stirling2(n, k):
|
||
|
"""
|
||
|
Stirling number of the second kind.
|
||
|
"""
|
||
|
if n < 0 or k < 0:
|
||
|
raise ValueError
|
||
|
if k >= n:
|
||
|
return MPZ(n == k)
|
||
|
if k <= 1:
|
||
|
return MPZ(k == 1)
|
||
|
s = MPZ_ZERO
|
||
|
t = MPZ_ONE
|
||
|
for j in xrange(k+1):
|
||
|
if (k + j) & 1:
|
||
|
s -= t * MPZ(j)**n
|
||
|
else:
|
||
|
s += t * MPZ(j)**n
|
||
|
t = t * (k - j) // (j + 1)
|
||
|
return s // ifac(k)
|