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确定整数的平方根是否为整数的最快方法

optimization math java perfect-square
2022-08-31 03:54:59

我正在寻找最快的方法来确定一个值是否是一个完美的平方(即它的平方根是另一个整数):long

  1. 通过使用内置的 Math.sqrt() 函数,我以简单的方法完成了此操作,但我想知道是否有一种方法可以通过将自己限制为仅整数域来更快地完成此操作。
  2. 维护查找表是不切实际的(因为大约有 231.5 个整数的平方小于 263)。

以下是我现在做的非常简单明了的方法:

public final static boolean isPerfectSquare(long n)
{
  if (n < 0)
    return false;

  long tst = (long)(Math.sqrt(n) + 0.5);
  return tst*tst == n;
}

注意:我在很多欧拉项目问题中都使用了这个函数。因此,没有其他人必须维护此代码。这种微优化实际上可以有所作为,因为部分挑战是在不到一分钟的时间内完成每个算法,并且在某些问题中需要调用此函数数百万次。

我已经尝试了这个问题的不同解决方案:

  • 经过详尽的测试,我发现没有必要添加Math.sqrt()的结果,至少在我的机器上不是这样。0.5
  • 快速反平方根更快,但它给出了n个>=410881不正确的结果。但是,正如BobbyShaftoe所建议的那样,我们可以将FISR黑客用于n< 410881。
  • 牛顿的方法比 慢一点。这可能是因为使用了类似于牛顿方法的东西,但是在硬件中实现,所以它比Java快得多。此外,牛顿方法仍然需要使用双精度。Math.sqrt()Math.sqrt()
  • 修改后的牛顿方法使用了一些技巧,因此只涉及整数数学,需要一些技巧来避免溢出(我希望这个函数适用于所有正64位有符号整数),它仍然比 慢。Math.sqrt()
  • 二进制斩波甚至更慢。这是有道理的,因为二进制斩波平均需要16次传递才能找到64位数字的平方根。
  • 根据 John 的测试,在 C++中使用语句比使用 a 更快,但在 Java 和 C# 中,和 之间似乎没有区别。orswitchorswitch
  • 我还尝试制作一个查找表(作为64个布尔值的私有静态数组)。然后,我不会说开关或语句,而只是说.令我惊讶的是,这(只是稍微)慢了一点。这是因为数组边界是在 Java 中检查的orif(lookup[(int)(n&0x3F)]) { test } else return false;

答案 1

我想出了一种方法,至少在我的CPU(x86)和编程语言(C / C++)下,比你的6bits + Carmack + sqrt代码快约35%。你的结果可能会有所不同,特别是因为我不知道Java因素将如何发挥作用。

我的方法有三个方面:

  1. 首先,过滤掉明显的答案。这包括负数和查看最后4位。(我发现查看最后六个没有帮助。我也对0的回答是肯定的。(在阅读下面的代码时,请注意我的输入是 .)int64 x
    if( x < 0 || (x&2) || ((x & 7) == 5) || ((x & 11) == 8) )
    return false;
if( x == 0 )
    return true;
  2. 接下来,检查它是否为平方模 255 = 3 * 5 * 17。因为这是三个不同素数的乘积,所以只有大约1/8的残基mod 255是平方。但是,根据我的经验,调用模运算符(%)的成本高于获得的好处,因此我使用涉及255 = 2 ^ 8-1的位技巧来计算残差。(无论好坏,我都没有使用从单词中读取单个字节的技巧,只是按位和移位。 为了实际检查残留物是否是正方形,我在预先计算的表中查找答案。
    int64 y = x;
y = (y & 4294967295LL) + (y >> 32); 
y = (y & 65535) + (y >> 16);
y = (y & 255) + ((y >> 8) & 255) + (y >> 16);
// At this point, y is between 0 and 511.  More code can reduce it farther.

    if( bad255[y] )
    return false;
// However, I just use a table of size 512
  3. 最后,尝试使用类似于汉塞尔引理的方法计算平方根。(我不认为它直接适用,但它可以通过一些修改来工作。在此之前,我通过二进制搜索除以2的所有幂:此时,我们的数字要成为平方,它必须是1 mod 8。 汉塞尔引理的基本结构如下。(注意:未经测试的代码;如果它不起作用,请尝试t=2或8。 这个想法是,在每次迭代时,你在r上添加一个位,r是x的“当前”平方根;每个平方根的精确模数越来越大,为2的幂,即t/2。最后,r 和 t/2-r 将是 x 模 t/2 的平方根。(请注意,如果 r 是 x 的平方根,则 -r 也是如此。这是真的偶数,但要注意,模一些数字,事物甚至可以有2个以上的平方根;值得注意的是,这包括2的幂。因为我们的实际平方根小于2^ 32,在这一点上,我们实际上可以检查r或t / 2-r是否是真正的平方根。在我的实际代码中,我使用以下修改后的循环:此处的加速是通过三种方式获得的:预先计算的起始值(相当于循环的约10次迭代),循环的早期退出以及跳过一些t值。对于最后一部分,我看了一下,并用一个技巧将t设置为2除以z的最大幂。这使我能够跳过无论如何都不会影响r值的t值。在我的例子中,预先计算的起始值挑出“最小正”平方根模8192。
    if((x & 4294967295LL) == 0)
    x >>= 32;
if((x & 65535) == 0)
    x >>= 16;
if((x & 255) == 0)
    x >>= 8;
if((x & 15) == 0)
    x >>= 4;
if((x & 3) == 0)
    x >>= 2;
    if((x & 7) != 1)
    return false;
    int64 t = 4, r = 1;
t <<= 1; r += ((x - r * r) & t) >> 1;
t <<= 1; r += ((x - r * r) & t) >> 1;
t <<= 1; r += ((x - r * r) & t) >> 1;
// Repeat until t is 2^33 or so.  Use a loop if you want.
    int64 r, t, z;
r = start[(x >> 3) & 1023];
do {
    z = x - r * r;
    if( z == 0 )
        return true;
    if( z < 0 )
        return false;
    t = z & (-z);
    r += (z & t) >> 1;
    if( r > (t >> 1) )
        r = t - r;
} while( t <= (1LL << 33) );
    z = r - x * x

即使这段代码对你来说工作得不快,我也希望你喜欢它所包含的一些想法。接下来是经过测试的完整代码,包括预先计算的表。

typedef signed long long int int64;

int start[1024] =
{1,3,1769,5,1937,1741,7,1451,479,157,9,91,945,659,1817,11,
1983,707,1321,1211,1071,13,1479,405,415,1501,1609,741,15,339,1703,203,
129,1411,873,1669,17,1715,1145,1835,351,1251,887,1573,975,19,1127,395,
1855,1981,425,453,1105,653,327,21,287,93,713,1691,1935,301,551,587,
257,1277,23,763,1903,1075,1799,1877,223,1437,1783,859,1201,621,25,779,
1727,573,471,1979,815,1293,825,363,159,1315,183,27,241,941,601,971,
385,131,919,901,273,435,647,1493,95,29,1417,805,719,1261,1177,1163,
1599,835,1367,315,1361,1933,1977,747,31,1373,1079,1637,1679,1581,1753,1355,
513,1539,1815,1531,1647,205,505,1109,33,1379,521,1627,1457,1901,1767,1547,
1471,1853,1833,1349,559,1523,967,1131,97,35,1975,795,497,1875,1191,1739,
641,1149,1385,133,529,845,1657,725,161,1309,375,37,463,1555,615,1931,
1343,445,937,1083,1617,883,185,1515,225,1443,1225,869,1423,1235,39,1973,
769,259,489,1797,1391,1485,1287,341,289,99,1271,1701,1713,915,537,1781,
1215,963,41,581,303,243,1337,1899,353,1245,329,1563,753,595,1113,1589,
897,1667,407,635,785,1971,135,43,417,1507,1929,731,207,275,1689,1397,
1087,1725,855,1851,1873,397,1607,1813,481,163,567,101,1167,45,1831,1205,
1025,1021,1303,1029,1135,1331,1017,427,545,1181,1033,933,1969,365,1255,1013,
959,317,1751,187,47,1037,455,1429,609,1571,1463,1765,1009,685,679,821,
1153,387,1897,1403,1041,691,1927,811,673,227,137,1499,49,1005,103,629,
831,1091,1449,1477,1967,1677,697,1045,737,1117,1737,667,911,1325,473,437,
1281,1795,1001,261,879,51,775,1195,801,1635,759,165,1871,1645,1049,245,
703,1597,553,955,209,1779,1849,661,865,291,841,997,1265,1965,1625,53,
1409,893,105,1925,1297,589,377,1579,929,1053,1655,1829,305,1811,1895,139,
575,189,343,709,1711,1139,1095,277,993,1699,55,1435,655,1491,1319,331,
1537,515,791,507,623,1229,1529,1963,1057,355,1545,603,1615,1171,743,523,
447,1219,1239,1723,465,499,57,107,1121,989,951,229,1521,851,167,715,
1665,1923,1687,1157,1553,1869,1415,1749,1185,1763,649,1061,561,531,409,907,
319,1469,1961,59,1455,141,1209,491,1249,419,1847,1893,399,211,985,1099,
1793,765,1513,1275,367,1587,263,1365,1313,925,247,1371,1359,109,1561,1291,
191,61,1065,1605,721,781,1735,875,1377,1827,1353,539,1777,429,1959,1483,
1921,643,617,389,1809,947,889,981,1441,483,1143,293,817,749,1383,1675,
63,1347,169,827,1199,1421,583,1259,1505,861,457,1125,143,1069,807,1867,
2047,2045,279,2043,111,307,2041,597,1569,1891,2039,1957,1103,1389,231,2037,
65,1341,727,837,977,2035,569,1643,1633,547,439,1307,2033,1709,345,1845,
1919,637,1175,379,2031,333,903,213,1697,797,1161,475,1073,2029,921,1653,
193,67,1623,1595,943,1395,1721,2027,1761,1955,1335,357,113,1747,1497,1461,
1791,771,2025,1285,145,973,249,171,1825,611,265,1189,847,1427,2023,1269,
321,1475,1577,69,1233,755,1223,1685,1889,733,1865,2021,1807,1107,1447,1077,
1663,1917,1129,1147,1775,1613,1401,555,1953,2019,631,1243,1329,787,871,885,
449,1213,681,1733,687,115,71,1301,2017,675,969,411,369,467,295,693,
1535,509,233,517,401,1843,1543,939,2015,669,1527,421,591,147,281,501,
577,195,215,699,1489,525,1081,917,1951,2013,73,1253,1551,173,857,309,
1407,899,663,1915,1519,1203,391,1323,1887,739,1673,2011,1585,493,1433,117,
705,1603,1111,965,431,1165,1863,533,1823,605,823,1179,625,813,2009,75,
1279,1789,1559,251,657,563,761,1707,1759,1949,777,347,335,1133,1511,267,
833,1085,2007,1467,1745,1805,711,149,1695,803,1719,485,1295,1453,935,459,
1151,381,1641,1413,1263,77,1913,2005,1631,541,119,1317,1841,1773,359,651,
961,323,1193,197,175,1651,441,235,1567,1885,1481,1947,881,2003,217,843,
1023,1027,745,1019,913,717,1031,1621,1503,867,1015,1115,79,1683,793,1035,
1089,1731,297,1861,2001,1011,1593,619,1439,477,585,283,1039,1363,1369,1227,
895,1661,151,645,1007,1357,121,1237,1375,1821,1911,549,1999,1043,1945,1419,
1217,957,599,571,81,371,1351,1003,1311,931,311,1381,1137,723,1575,1611,
767,253,1047,1787,1169,1997,1273,853,1247,413,1289,1883,177,403,999,1803,
1345,451,1495,1093,1839,269,199,1387,1183,1757,1207,1051,783,83,423,1995,
639,1155,1943,123,751,1459,1671,469,1119,995,393,219,1743,237,153,1909,
1473,1859,1705,1339,337,909,953,1771,1055,349,1993,613,1393,557,729,1717,
511,1533,1257,1541,1425,819,519,85,991,1693,503,1445,433,877,1305,1525,
1601,829,809,325,1583,1549,1991,1941,927,1059,1097,1819,527,1197,1881,1333,
383,125,361,891,495,179,633,299,863,285,1399,987,1487,1517,1639,1141,
1729,579,87,1989,593,1907,839,1557,799,1629,201,155,1649,1837,1063,949,
255,1283,535,773,1681,461,1785,683,735,1123,1801,677,689,1939,487,757,
1857,1987,983,443,1327,1267,313,1173,671,221,695,1509,271,1619,89,565,
127,1405,1431,1659,239,1101,1159,1067,607,1565,905,1755,1231,1299,665,373,
1985,701,1879,1221,849,627,1465,789,543,1187,1591,923,1905,979,1241,181};

bool bad255[512] =
{0,0,1,1,0,1,1,1,1,0,1,1,1,1,1,0,0,1,1,0,1,0,1,1,1,0,1,1,1,1,0,1,
 1,1,0,1,0,1,1,1,1,1,1,1,1,1,1,1,1,0,1,0,1,1,1,0,1,1,1,1,0,1,1,1,
 0,1,0,1,1,0,0,1,1,1,1,1,0,1,1,1,1,0,1,1,0,0,1,1,1,1,1,1,1,1,0,1,
 1,1,1,1,0,1,1,1,1,1,0,1,1,1,1,0,1,1,1,0,1,1,1,1,0,0,1,1,1,1,1,1,
 1,1,1,1,1,1,1,0,0,1,1,1,1,1,1,1,0,0,1,1,1,1,1,0,1,1,0,1,1,1,1,1,
 1,1,1,1,1,1,0,1,1,0,1,0,1,1,0,1,1,1,1,1,1,1,1,1,1,1,0,1,1,0,1,1,
 1,1,1,0,0,1,1,1,1,1,1,1,0,0,1,1,1,1,1,1,1,1,1,1,1,1,1,0,0,1,1,1,
 1,0,1,1,1,0,1,1,1,1,0,1,1,1,1,1,0,1,1,1,1,1,0,1,1,1,1,1,1,1,1,
 0,0,1,1,0,1,1,1,1,0,1,1,1,1,1,0,0,1,1,0,1,0,1,1,1,0,1,1,1,1,0,1,
 1,1,0,1,0,1,1,1,1,1,1,1,1,1,1,1,1,0,1,0,1,1,1,0,1,1,1,1,0,1,1,1,
 0,1,0,1,1,0,0,1,1,1,1,1,0,1,1,1,1,0,1,1,0,0,1,1,1,1,1,1,1,1,0,1,
 1,1,1,1,0,1,1,1,1,1,0,1,1,1,1,0,1,1,1,0,1,1,1,1,0,0,1,1,1,1,1,1,
 1,1,1,1,1,1,1,0,0,1,1,1,1,1,1,1,0,0,1,1,1,1,1,0,1,1,0,1,1,1,1,1,
 1,1,1,1,1,1,0,1,1,0,1,0,1,1,0,1,1,1,1,1,1,1,1,1,1,1,0,1,1,0,1,1,
 1,1,1,0,0,1,1,1,1,1,1,1,0,0,1,1,1,1,1,1,1,1,1,1,1,1,1,0,0,1,1,1,
 1,0,1,1,1,0,1,1,1,1,0,1,1,1,1,1,0,1,1,1,1,1,0,1,1,1,1,1,1,1,1,
 0,0};

inline bool square( int64 x ) {
    // Quickfail
    if( x < 0 || (x&2) || ((x & 7) == 5) || ((x & 11) == 8) )
        return false;
    if( x == 0 )
        return true;

    // Check mod 255 = 3 * 5 * 17, for fun
    int64 y = x;
    y = (y & 4294967295LL) + (y >> 32);
    y = (y & 65535) + (y >> 16);
    y = (y & 255) + ((y >> 8) & 255) + (y >> 16);
    if( bad255[y] )
        return false;

    // Divide out powers of 4 using binary search
    if((x & 4294967295LL) == 0)
        x >>= 32;
    if((x & 65535) == 0)
        x >>= 16;
    if((x & 255) == 0)
        x >>= 8;
    if((x & 15) == 0)
        x >>= 4;
    if((x & 3) == 0)
        x >>= 2;

    if((x & 7) != 1)
        return false;

    // Compute sqrt using something like Hensel's lemma
    int64 r, t, z;
    r = start[(x >> 3) & 1023];
    do {
        z = x - r * r;
        if( z == 0 )
            return true;
        if( z < 0 )
            return false;
        t = z & (-z);
        r += (z & t) >> 1;
        if( r > (t  >> 1) )
            r = t - r;
    } while( t <= (1LL << 33) );

    return false;
}

答案 2

我来晚了,但我希望能提供更好的答案;更短,(假设我的基准是正确的)也得多。

long goodMask; // 0xC840C04048404040 computed below
{
    for (int i=0; i<64; ++i) goodMask |= Long.MIN_VALUE >>> (i*i);
}

public boolean isSquare(long x) {
    // This tests if the 6 least significant bits are right.
    // Moving the to be tested bit to the highest position saves us masking.
    if (goodMask << x >= 0) return false;
    final int numberOfTrailingZeros = Long.numberOfTrailingZeros(x);
    // Each square ends with an even number of zeros.
    if ((numberOfTrailingZeros & 1) != 0) return false;
    x >>= numberOfTrailingZeros;
    // Now x is either 0 or odd.
    // In binary each odd square ends with 001.
    // Postpone the sign test until now; handle zero in the branch.
    if ((x&7) != 1 | x <= 0) return x == 0;
    // Do it in the classical way.
    // The correctness is not trivial as the conversion from long to double is lossy!
    final long tst = (long) Math.sqrt(x);
    return tst * tst == x;
}

第一个测试可以快速捕获大多数非平方。它使用一个包含 64 项的表,该表打包成一个长表,因此没有数组访问成本(间接寻址和边界检查)。对于均匀随机,有81.25%的概率在这里结束。long

第二个检验捕获在因式分解中具有奇数个二的所有数字。该方法非常快,因为它将JIT-ed转换为单个i86指令。Long.numberOfTrailingZeros

删除尾随零后,第三个测试处理以二进制中 011、101 或 111 结尾的数字,这些数字不是完美的平方。它还关心负数,并处理 0。

最终测试回退到算术。由于只有 53 位尾数,因此从 到 的转换包括大值的舍入。尽管如此,测试是正确的(除非证明是错误的)。doubledoublelongdouble

试图整合mod255的想法并不成功。


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