Find first and last set bit of a long integer: Difference between revisions
(Find first and last set bit of a long integer en BASIC256) |
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{{libheader|Wren-big}} |
{{libheader|Wren-big}} |
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{{libheader|Wren-fmt}} |
{{libheader|Wren-fmt}} |
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{{libheader|Wren-math}} |
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<lang ecmascript>import "/big" for BigInt |
<lang ecmascript>import "/big" for BigInt |
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import "/fmt" for Fmt |
import "/fmt" for Fmt |
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import "/math" for Math |
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var rupb = Fn.new { |x| (x is BigInt) ? x.bitLength - 1 : |
var rupb = Fn.new { |x| (x is BigInt) ? x.bitLength - 1 : x.log2.floor } |
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var rlwb = Fn.new { |x| rupb.call(x & -x) } |
var rlwb = Fn.new { |x| rupb.call(x & -x) } |
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1302^6 = 4,871,535,877,925,849,664 rupb: 62 rlwb: 6 |
1302^6 = 4,871,535,877,925,849,664 rupb: 62 rlwb: 6 |
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</pre> |
</pre> |
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=={{header|Yabasic}}== |
=={{header|Yabasic}}== |
Revision as of 12:58, 11 December 2021
Clarification: This task is asking for the position of two bits in the binary representation of a positive integer. Some parts of this task assume that this is the native representation in the language you are working in. Any part of this task which makes assumptions about native representation should be treated as a recommendation which is only relevant in some contexts. A bit is defined as the exponent in a binary polynomial -- an exponent corresponding to a power of 2 which has a non-zero multiplier in the summation sequence of powers of two which yields the desired positive integer, where the only allowed coefficients are 0 and 1.
Define routines (or operators) lwb and upb that find the first and last set bit in a binary value. Implement using a binary search to find the location of the particular upper/lower bit.
Also: Define the reverse routines (or operators) rlwb and rupb that find host's positive integers least- and most-significant set bit in a binary value expressed in LSB 0 bit numbering, i.e. indexed from the extreme right bit.
Use primarily bit operations, such as and, or, and bit shifting. Avoid additions, multiplications and especially avoid divisions.
- Two implementations
- For the host word size on the host platform, implement the routine "efficiently" in without looping or recursion.
- For the extended precision/long word implement the algorithm more generally - maybe as a template, and maybe with looping - so that any bits width for a binary type can be accommodated.
- Test cases
- For the host machine word size: Use the powers of 42 up to host's the "natural" word size to calculate the index of the first and last set bit.
- For the extended precision: Use the powers of 1302 up to the host's next "natural" long host word size to calculate the index of the first and last set bit.
- Output bit indexes in LSB 0 bit numbering.
- Additionally
In a particular language, there maybe (at least) two alternative approaches of calculating the required values:
- Using an external library.
- Using a built-in library.
If any of these approaches are available, then also note the library or built-in name.
- See also
- Find the log base 2 of an N-bit integer in O(lg(N)) operations
- 80386 Instruction Set - BSF -- Bit Scan Forward
11l
<lang 11l>L(i) 6
V x = Int(42 ^ i) print(‘#10 MSB: #2 LSB: #2’.format(x, bsr(x), bsf(x)))
L(i) 6
V x = Int64(1302 ^ i) print(‘#20 MSB: #2 LSB: #2’.format(x, bsr(x), bsf(x)))</lang>
- Output:
1 MSB: 0 LSB: 0 42 MSB: 5 LSB: 1 1764 MSB: 10 LSB: 2 74088 MSB: 16 LSB: 3 3111696 MSB: 21 LSB: 4 130691232 MSB: 26 LSB: 5 1 MSB: 0 LSB: 0 1302 MSB: 10 LSB: 1 1695204 MSB: 20 LSB: 2 2207155608 MSB: 31 LSB: 3 2873716601616 MSB: 41 LSB: 4 3741579015304032 MSB: 51 LSB: 5
Ada
<lang Ada>with Ada.Text_IO; with Ada.Integer_Text_IO; with Ada.Unchecked_Conversion;
procedure Find_Last_Bit is
type My_Integer is range -2**63 .. 2**63 - 1;
procedure Find_Set_Bits (Value : in My_Integer; MSB_Bit : out Integer; LSB_Bit : out Integer) is type Bit_Field is array (0 .. My_Integer'Size - 1) of Boolean; pragma Pack (Bit_Field); for Bit_Field'Size use My_Integer'Size;
function To_Field is new Ada.Unchecked_Conversion (My_Integer, Bit_Field);
Field : constant Bit_Field := To_Field (Value); begin
LSB_Bit := -1; MSB_Bit := -1;
for Bit in Field'Range loop if Field (Bit) then LSB_Bit := Bit; exit; end if; end loop;
for Bit in reverse Field'Range loop if Field (Bit) then MSB_Bit := Bit; exit; end if; end loop; end Find_Set_Bits;
procedure Put_Result (Value : in My_Integer) is package My_Integer_IO is new Ada.Text_IO.Integer_IO (My_Integer); use Ada.Text_IO; use Ada.Integer_Text_IO; Use My_Integer_IO;
LSB_Bit, MSB_Bit : Integer; Placeholder : String := " MSB XX LSB YY"; Image_MSB : String renames Placeholder ( 6 .. 7); Image_LSB : String renames Placeholder (13 .. 14); begin Find_Set_Bits (Value, MSB_Bit => MSB_Bit, LSB_Bit => LSB_Bit); Put (Value, Width => 18); Put (Value, Width => 66, Base => 2); Put (Image_MSB, MSB_Bit); Put (Image_LSB, LSB_Bit); Put_Line (Placeholder); end Put_Result;
begin
Put_Result (Value => 0); for A in 0 .. 11 loop Put_Result (Value => 42 ** A); end loop;
end Find_Last_Bit;</lang>
- Output:
0 2#0# MSB -1 LSB -1 1 2#1# MSB 0 LSB 0 42 2#101010# MSB 5 LSB 1 1764 2#11011100100# MSB 10 LSB 2 74088 2#10010000101101000# MSB 16 LSB 3 3111696 2#1011110111101100010000# MSB 21 LSB 4 130691232 2#111110010100011000010100000# MSB 26 LSB 5 5489031744 2#101000111001010111111101001000000# MSB 32 LSB 6 230539333248 2#11010110101101001101110000111010000000# MSB 37 LSB 7 9682651996416 2#10001100111001101011000010000110000100000000# MSB 43 LSB 8 406671383849472 2#1011100011101110110001111010111111110101000000000# MSB 48 LSB 9 17080198121677824 2#111100101011100101100110000101101111000110010000000000# MSB 53 LSB 10 717368321110468608 2#100111110100100110101010111111110000111010000110100000000000# MSB 59 LSB 11
ALGOL 68
File: Template.Find_first_and_last_set_bit.a68<lang algol68>INT lbits width = UPB []BOOL(LBITS(2r0));
OP LWB = (BITS in x)INT: bits width - RUPB in x;
OP RUPB = (BITS in x)INT:
### 32 bit LWB Find Lower Set Bit using an unrolled loop ###
- Note: BITS ELEM 1 is actually numerically the Most Significant Bit!! #
IF in x = 2r0 THEN -1 # EXIT # ELSE BITS x := in x, out := 2r0; IF(x AND NOT 2r1111111111111111)/=2r0 THEN x := x SHR 16; out := out OR 2r10000 FI; IF(x AND NOT 2r11111111) /=2r0 THEN x := x SHR 8; out := out OR 2r1000 FI; IF(x AND NOT 2r1111) /=2r0 THEN x := x SHR 4; out := out OR 2r100 FI; IF(x AND NOT 2r11) /=2r0 THEN x := x SHR 2; out := out OR 2r10 FI; IF(x AND NOT 2r1) /=2r0 THEN out := out OR 2r1 FI; ABS out # EXIT # FI;
OP LWB = (LBITS in x)INT: lbits width - RUPB in x;
OP RUPB = (LBITS in x)INT:
### Generalised Find Lower Set Bit using a loop ###
- Note: BITS ELEM 32 is actually numerically the Least Significant Bit!! #
IF in x = 2r0 THEN -1 # EXIT # ELSE LBITS x := in x; BITS out bit := BIN 1 SHL (bits width - LWB BIN lbits width), out := BIN 0; WHILE LBITS mask := NOT BIN (ABS (LONG 2r1 SHL ABS out bit) - 1); IF(x AND mask) /= 2r0 THEN x := x SHR ABS out bit; out := out OR out bit FI; out bit := out bit SHR 1; # WHILE # out bit /= 2r0 DO SKIP OD; ABS out # EXIT # FI;
OP UPB = (BITS in x)INT: bits width - RLWB in x;
OP RLWB = (BITS in x)INT:
### 32 bit Find Upper Set Bit using an unrolled loop ###
- Note: BITS ELEM 1 is actually numerically the Most Significant Bit!! #
IF in x = 2r0 THEN 0 # EXIT # ELSE BITS x := in x, out := 2r0; IF(x AND 2r1111111111111111)=2r0 THEN x := x SHR 16; out := out OR 2r10000 FI; IF(x AND 2r11111111) =2r0 THEN x := x SHR 8; out := out OR 2r1000 FI; IF(x AND 2r1111) =2r0 THEN x := x SHR 4; out := out OR 2r100 FI; IF(x AND 2r11) =2r0 THEN x := x SHR 2; out := out OR 2r10 FI; IF(x AND 2r1) =2r0 THEN out := out OR 2r1 FI; ABS out # EXIT # FI;
OP UPB = (LBITS in x)INT: lbits width - RLWB in x;
OP RLWB = (LBITS in x)INT:
### Generalised Find Upper Set Bit using a loop ###
- Note: BITS ELEM 1 is actually numerically the Most Significant Bit!! #
IF in x = 2r0 THEN 0 # EXIT # ELSE LBITS x := in x; BITS out bit := BIN 1 SHL (bits width - LWB BIN lbits width), out := BIN 0; WHILE LBITS mask := BIN (ABS (LONG 2r1 SHL ABS out bit) - 1); IF(x AND mask) = 2r0 THEN x := x SHR ABS out bit; out := out OR out bit FI; out bit := out bit SHR 1; # WHILE # out bit /= 2r0 DO SKIP OD; ABS out # EXIT # FI;</lang>File: test.Find_first_and_last_set_bit.a68<lang algol68>#!/usr/local/bin/a68g --script #
MODE LBITS = LONG BITS; PR READ "Template.Find_first_and_last_set_bit.a68" PR
INT bits of prod; FORMAT header fmt = $g 36k"|RLWB|RUPB|Bits"l$; FORMAT row fmt0 = $g(-35)"|"2(g(-3)" |"),2rd l$; FORMAT row fmt = $g(-35)"|"2(g(-3)" |"),2rn(bits of prod+1)d l$;
test int:(
printf((header fmt, "INT: find first & last set bit")); INT prod := 0; # test case 0 # prod := 0; bits of prod := RUPB BIN prod; printf((row fmt0, prod, RLWB BIN prod, RUPB BIN prod, BIN prod)); prod := 1; # test case 1 etc ... # INT zoom := 2 * 3 * 7; WHILE bits of prod := RUPB BIN prod; printf((row fmt, prod, RLWB BIN prod, RUPB BIN prod, BIN prod));
- WHILE # prod <= max int / zoom DO
prod *:= zoom OD
);
test long int:(
printf(($l$,header fmt, "LONG INT:")); LONG INT prod := 0; # test case 0 # prod := 0; bits of prod := RUPB BIN prod; printf((row fmt0, prod, RLWB BIN prod, RUPB BIN prod, BIN prod)); prod := 1; # test case 1 etc ... # INT zoom := 2 * 3 * 7 * 31; WHILE bits of prod := RUPB BIN prod; printf((row fmt, prod, RLWB BIN prod, RUPB BIN prod, BIN prod));
- WHILE # prod <= long max int / zoom DO
prod *:= zoom OD
)</lang>
- Output:
INT: find first & last set bit |RLWB|RUPB|Bits 0| 0 | -1 |0 1| 0 | 0 |1 42| 1 | 5 |101010 1764| 2 | 10 |11011100100 74088| 3 | 16 |10010000101101000 3111696| 4 | 21 |1011110111101100010000 130691232| 5 | 26 |111110010100011000010100000 LONG INT: |RLWB|RUPB|Bits 0| 0 | -1 |0 1| 0 | 0 |1 1302| 1 | 10 |10100010110 1695204| 2 | 20 |110011101110111100100 2207155608| 3 | 31 |10000011100011101000010110011000 2873716601616| 4 | 41 |101001110100010110110110110111001100010000 3741579015304032| 5 | 51 |1101010010101111001001000000000110110011001101100000 4871535877925849664| 6 | 62 |100001110011011001011000001001000001010010101110100101001000000 6342739713059456262528| 7 | 72 |1010101111101011100110010001000111100000010010111111100111010000110000000 8258247106403412053811456| 8 | 82 |11011010100110000000111100100000001110101011000010011010001000101110110000100000000 10752237732537242494062515712| 9 | 93 |1000101011111000001010111001110110111101010011111100010111111101101100111001110101011000000000 13999413527763489727269395457024| 10 |103 |10110000101100101000101101110101000100000011010011101110001111100001001111100000100011110110010000000000 18227236413148063624904752885045248| 11 |113 |111000001010101100000100010100010101100000011011010011001110101111101110010001100000011001010001101001100000000000
AutoHotkey
<lang AutoHotkey>loop, 12{ First := Last := "" n:=42**(A_Index-1) while (n>v) if (n&v := 2**(A_Index-1)) First := First ? First : A_Index-1 , Last := A_Index-1 Res .= 42 "^" A_Index-1 " --> First : " First " , Last : " Last "`n" } MsgBox % Res</lang>
- Output:
42^0 --> First : 0 , Last : 0 42^1 --> First : 1 , Last : 5 42^2 --> First : 2 , Last : 10 42^3 --> First : 3 , Last : 16 42^4 --> First : 4 , Last : 21 42^5 --> First : 5 , Last : 26 42^6 --> First : 6 , Last : 32 42^7 --> First : 7 , Last : 37 42^8 --> First : 8 , Last : 43 42^9 --> First : 9 , Last : 48 42^10 --> First : 10 , Last : 53 42^11 --> First : 11 , Last : 59
BASIC256
<lang BASIC256>print "INT: find first & last set bit" p = 1 for j = 0 to 5 print rjust(p,9); " "; rjust(ToBinary(p),29,0); " MSB: "; rjust(MSB(p),2); " LSB: "; rjust(LSB(p),2) p *= 42 next j print end
function MSB(i) return length(ToBinary(i))-1 end function
function LSB(i) return (i & -i) end function </lang>
- Output:
INT: find first & last set bit 1 00000000000000000000000000001 MSB: 0 LSB: 1 42 00000000000000000000000101010 MSB: 5 LSB: 2 1764 00000000000000000011011100100 MSB: 10 LSB: 4 74088 00000000000010010000101101000 MSB: 16 LSB: 8 3111696 00000001011110111101100010000 MSB: 21 LSB: 16 130691232 00111110010100011000010100000 MSB: 26 LSB: 32
C
<lang c>#include <stdio.h>
- include <stdint.h>
uint32_t msb32(uint32_t n) { uint32_t b = 1; if (!n) return 0;
- define step(x) if (n >= ((uint32_t)1) << x) b <<= x, n >>= x
step(16); step(8); step(4); step(2); step(1);
- undef step
return b; }
int msb32_idx(uint32_t n) { int b = 0; if (!n) return -1;
- define step(x) if (n >= ((uint32_t)1) << x) b += x, n >>= x
step(16); step(8); step(4); step(2); step(1);
- undef step
return b; }
- define lsb32(n) ( (uint32_t)(n) & -(int32_t)(n) )
/* finding the *position* of the least significant bit
rarely makes sense, so we don't put much effort in it*/
inline int lsb32_idx(uint32_t n) { return msb32_idx(lsb32(n)); }
int main() { int32_t n; int i;
for (i = 0, n = 1; ; i++, n *= 42) { printf("42**%d = %10d(x%08x): M x%08x(%2d) L x%03x(%2d)\n", i, n, n, msb32(n), msb32_idx(n), lsb32(n), lsb32_idx(n));
if (n >= INT32_MAX / 42) break; }
return 0; }</lang>
- Output:
42**0 = 1(x00000001): M x00000001( 0) L x001( 0) 42**1 = 42(x0000002a): M x00000020( 5) L x002( 1) 42**2 = 1764(x000006e4): M x00000400(10) L x004( 2) 42**3 = 74088(x00012168): M x00010000(16) L x008( 3) 42**4 = 3111696(x002f7b10): M x00200000(21) L x010( 4) 42**5 = 130691232(x07ca30a0): M x04000000(26) L x020( 5)
Where "x###" are in base 16
GCC extension
<lang c>#include <stdio.h>
- include <limits.h>
int msb_int(unsigned int x) { int ret = sizeof(unsigned int) * CHAR_BIT - 1; return x ? ret - __builtin_clz(x) : ret; }
int msb_long(unsigned long x) { int ret = sizeof(unsigned long) * CHAR_BIT - 1; return x ? ret - __builtin_clzl(x) : ret; }
int msb_longlong(unsigned long long x) { int ret = sizeof(unsigned long long) * CHAR_BIT - 1; return x ? ret - __builtin_clzll(x) : ret; }
- define lsb_int(x) (__builtin_ffs(x) - 1)
- define lsb_long(x) (__builtin_ffsl(x) - 1)
- define lsb_longlong(x) (__builtin_ffsll(x) - 1)
int main() { int i;
printf("int:\n");
unsigned int n1; for (i = 0, n1 = 1; ; i++, n1 *= 42) { printf("42**%d = %10u(x%08x): M %2d L %2d\n", i, n1, n1, msb_int(n1), lsb_int(n1));
if (n1 >= UINT_MAX / 42) break; }
printf("long:\n");
unsigned long n2; for (i = 0, n2 = 1; ; i++, n2 *= 42) { printf("42**%02d = %20lu(x%016lx): M %2d L %2d\n", i, n2, n2, msb_long(n2), lsb_long(n2));
if (n2 >= ULONG_MAX / 42) break; }
return 0; }</lang>
- Output:
int: 42**0 = 1(x00000001): M 0 L 0 42**1 = 42(x0000002a): M 5 L 1 42**2 = 1764(x000006e4): M 10 L 2 42**3 = 74088(x00012168): M 16 L 3 42**4 = 3111696(x002f7b10): M 21 L 4 42**5 = 130691232(x07ca30a0): M 26 L 5 long: 42**00 = 1(x0000000000000001): M 0 L 0 42**01 = 42(x000000000000002a): M 5 L 1 42**02 = 1764(x00000000000006e4): M 10 L 2 42**03 = 74088(x0000000000012168): M 16 L 3 42**04 = 3111696(x00000000002f7b10): M 21 L 4 42**05 = 130691232(x0000000007ca30a0): M 26 L 5 42**06 = 5489031744(x00000001472bfa40): M 32 L 6 42**07 = 230539333248(x00000035ad370e80): M 37 L 7 42**08 = 9682651996416(x000008ce6b086100): M 43 L 8 42**09 = 406671383849472(x000171dd8f5fea00): M 48 L 9 42**10 = 17080198121677824(x003cae5985bc6400): M 53 L 10 42**11 = 717368321110468608(x09f49aaff0e86800): M 59 L 11
Where "x###" are in base 16
D
(This task is not complete, the second part will be added later.) <lang d>import std.stdio, core.bitop, std.bigint;
void main() {
enum size_t test = 42; for (size_t i = 0; true; i++) { immutable size_t x = test ^^ i; if (x != BigInt(test) ^^ i) break; writefln("%18d %0*b MSB: %2d LSB: %2d", x, size_t.sizeof * 8, x, bsr(x), bsf(x)); }
}</lang>
- Output:
On a 32 bit system:
1 00000000000000000000000000000001 MSB: 0 LSB: 0 42 00000000000000000000000000101010 MSB: 5 LSB: 1 1764 00000000000000000000011011100100 MSB: 10 LSB: 2 74088 00000000000000010010000101101000 MSB: 16 LSB: 3 3111696 00000000001011110111101100010000 MSB: 21 LSB: 4 130691232 00000111110010100011000010100000 MSB: 26 LSB: 5
On a 64 bit system:
1 0000000000000000000000000000000000000000000000000000000000000001 MSB: 0 LSB: 0 42 0000000000000000000000000000000000000000000000000000000000101010 MSB: 5 LSB: 1 1764 0000000000000000000000000000000000000000000000000000011011100100 MSB: 10 LSB: 2 74088 0000000000000000000000000000000000000000000000010010000101101000 MSB: 16 LSB: 3 3111696 0000000000000000000000000000000000000000001011110111101100010000 MSB: 21 LSB: 4 130691232 0000000000000000000000000000000000000111110010100011000010100000 MSB: 26 LSB: 5 5489031744 0000000000000000000000000000000101000111001010111111101001000000 MSB: 32 LSB: 6 230539333248 0000000000000000000000000011010110101101001101110000111010000000 MSB: 37 LSB: 7 9682651996416 0000000000000000000010001100111001101011000010000110000100000000 MSB: 43 LSB: 8 406671383849472 0000000000000001011100011101110110001111010111111110101000000000 MSB: 48 LSB: 9 17080198121677824 0000000000111100101011100101100110000101101111000110010000000000 MSB: 53 LSB: 10 717368321110468608 0000100111110100100110101010111111110000111010000110100000000000 MSB: 59 LSB: 11
Delphi
Thanks for Rudy Velthuis for Velthuis.BigIntegers[1].
<lang Delphi> program Find_first_and_last_set_bit_of_a_long_integer;
{$APPTYPE CONSOLE}
uses
System.SysUtils, Velthuis.BigIntegers;
function bsf(x: string): Integer; begin
Result := x.Length - x.LastIndexOf('1') - 1;
end;
function bsr(x: string): Integer; begin
Result := x.Length - x.IndexOf('1') - 1;
end;
var
i: integer; value: BigInteger; binary: string;
begin
for i := 0 to 11 do begin value := BigInteger.Pow(42, i); binary := value.ToBinaryString.PadLeft(64, '0');
Writeln(format('%18s %60s MSB: %2d LSB: %2d', [value.ToString, binary, bsr(binary), bsf(binary)])); end;
readln;
end.</lang>
- Output:
1 0000000000000000000000000000000000000000000000000000000000000001 MSB: 0 LSB: 0 42 0000000000000000000000000000000000000000000000000000000000101010 MSB: 5 LSB: 1 1764 0000000000000000000000000000000000000000000000000000011011100100 MSB: 10 LSB: 2 74088 0000000000000000000000000000000000000000000000010010000101101000 MSB: 16 LSB: 3 3111696 0000000000000000000000000000000000000000001011110111101100010000 MSB: 21 LSB: 4 130691232 0000000000000000000000000000000000000111110010100011000010100000 MSB: 26 LSB: 5 5489031744 0000000000000000000000000000000101000111001010111111101001000000 MSB: 32 LSB: 6 230539333248 0000000000000000000000000011010110101101001101110000111010000000 MSB: 37 LSB: 7 9682651996416 0000000000000000000010001100111001101011000010000110000100000000 MSB: 43 LSB: 8 406671383849472 0000000000000001011100011101110110001111010111111110101000000000 MSB: 48 LSB: 9 17080198121677824 0000000000111100101011100101100110000101101111000110010000000000 MSB: 53 LSB: 10 717368321110468608 0000100111110100100110101010111111110000111010000110100000000000 MSB: 59 LSB: 11
Fortran
Since the Fortran 2008 standard, the language has LEADZ and TRAILZ intrinsic functions that yield respectively the number of leading (i.e. HSB) and trailing (LSB) zero bits. This gives an immediate solution to the task.
<lang fortran>program bits
implicit none integer :: n = 1, i
do i = 1, 6 print "(B32,2(' ',I2))", n, trailz(n), 31 - leadz(n) n = 42 * n end do
end program</lang>
- Output:
1 0 0 101010 1 5 11011100100 2 10 10010000101101000 3 16 1011110111101100010000 4 21 111110010100011000010100000 5 26
FreeBASIC
<lang freebasic>Function MSB(i As Integer) As Integer
Return Len(Bin(i))-1
End Function
Function LSB(i As Integer) As Integer
Return MSB(i And -i)
End Function
Dim As Integer p = 1 For j As Integer = 0 To 11
Print Using "################## & MSB: ## LSB: ##"; p; Bin(p,64); MSB(p); LSB(p) p *= 42
Next j Sleep</lang>
- Output:
1 0000000000000000000000000000000000000000000000000000000000000001 MSB: 0 LSB: 0 42 0000000000000000000000000000000000000000000000000000000000101010 MSB: 5 LSB: 1 1764 0000000000000000000000000000000000000000000000000000011011100100 MSB: 10 LSB: 2 74088 0000000000000000000000000000000000000000000000010010000101101000 MSB: 16 LSB: 3 3111696 0000000000000000000000000000000000000000001011110111101100010000 MSB: 21 LSB: 4 130691232 0000000000000000000000000000000000000111110010100011000010100000 MSB: 26 LSB: 5 5489031744 0000000000000000000000000000000101000111001010111111101001000000 MSB: 32 LSB: 6 230539333248 0000000000000000000000000011010110101101001101110000111010000000 MSB: 37 LSB: 7 9682651996416 0000000000000000000010001100111001101011000010000110000100000000 MSB: 43 LSB: 8 406671383849472 0000000000000001011100011101110110001111010111111110101000000000 MSB: 48 LSB: 9 17080198121677824 0000000000111100101011100101100110000101101111000110010000000000 MSB: 53 LSB: 10 717368321110468608 0000100111110100100110101010111111110000111010000110100000000000 MSB: 59 LSB: 11
Go
<lang go>package main
import (
"fmt" "math/big"
)
const (
mask0, bit0 = (1 << (1 << iota)) - 1, 1 << iota mask1, bit1 mask2, bit2 mask3, bit3 mask4, bit4 mask5, bit5
)
func rupb(x uint64) (out int) {
if x == 0 { return -1 } if x&^mask5 != 0 { x >>= bit5 out |= bit5 } if x&^mask4 != 0 { x >>= bit4 out |= bit4 } if x&^mask3 != 0 { x >>= bit3 out |= bit3 } if x&^mask2 != 0 { x >>= bit2 out |= bit2 } if x&^mask1 != 0 { x >>= bit1 out |= bit1 } if x&^mask0 != 0 { out |= bit0 } return
}
func rlwb(x uint64) (out int) {
if x == 0 { return 0 } if x&mask5 == 0 { x >>= bit5 out |= bit5 } if x&mask4 == 0 { x >>= bit4 out |= bit4 } if x&mask3 == 0 { x >>= bit3 out |= bit3 } if x&mask2 == 0 { x >>= bit2 out |= bit2 } if x&mask1 == 0 { x >>= bit1 out |= bit1 } if x&mask0 == 0 { out |= bit0 } return
}
// Big number versions of functions do not use the techniques of the ALGOL 68 // solution. The big number version of rupb is trivial given one of the // standard library functions, And for rlwb, I couldn't recommend shifting // the whole input number when working with smaller numbers would do. func rupbBig(x *big.Int) int {
return x.BitLen() - 1
}
// Binary search, for the spirit of the task, but without shifting the input // number x. (Actually though, I don't recommend this either. Linear search // would be much faster.) func rlwbBig(x *big.Int) int {
if x.BitLen() < 2 { return 0 } bit := uint(1) mask := big.NewInt(1) var ms []*big.Int var y, z big.Int for y.And(x, z.Lsh(mask, bit)).BitLen() == 0 { ms = append(ms, mask) mask = new(big.Int).Or(mask, &z) bit <<= 1 } out := bit for i := len(ms) - 1; i >= 0; i-- { bit >>= 1 if y.And(x, z.Lsh(ms[i], out)).BitLen() == 0 { out |= bit } } return int(out)
}
func main() {
show() showBig()
}
func show() {
fmt.Println("uint64:") fmt.Println("power number rupb rlwb") const base = 42 n := uint64(1) for i := 0; i < 12; i++ { fmt.Printf("%d^%02d %19d %5d %5d\n", base, i, n, rupb(n), rlwb(n)) n *= base }
}
func showBig() {
fmt.Println("\nbig numbers:") fmt.Println(" power number rupb rlwb") base := big.NewInt(1302) n := big.NewInt(1) for i := 0; i < 12; i++ { fmt.Printf("%d^%02d %36d %5d %5d\n", base, i, n, rupbBig(n), rlwbBig(n)) n.Mul(n, base) }
}</lang>
- Output:
uint64: power number rupb rlwb 42^00 1 0 0 42^01 42 5 1 42^02 1764 10 2 42^03 74088 16 3 42^04 3111696 21 4 42^05 130691232 26 5 42^06 5489031744 32 6 42^07 230539333248 37 7 42^08 9682651996416 43 8 42^09 406671383849472 48 9 42^10 17080198121677824 53 10 42^11 717368321110468608 59 11 big numbers: power number rupb rlwb 1302^00 1 0 0 1302^01 1302 10 1 1302^02 1695204 20 2 1302^03 2207155608 31 3 1302^04 2873716601616 41 4 1302^05 3741579015304032 51 5 1302^06 4871535877925849664 62 6 1302^07 6342739713059456262528 72 7 1302^08 8258247106403412053811456 82 8 1302^09 10752237732537242494062515712 93 9 1302^10 13999413527763489727269395457024 103 10 1302^11 18227236413148063624904752885045248 113 11
Icon and Unicon
The task definition makes some assumptions that don't work in Icon/Unicon and are going to require some reinterpretation. In Icon/Unicon all integers appear to be implemented as a single common type. A specific implementation may or may not have large integers, but if it does they are essentially indistinguishable from regular integers. Given all of this, implementing "efficient" procedures for the platform word size without loops or recursion makes little sense.
Instead of this, to meet the spirit of the task, these lsb and msb routines are generalized to reduce the integer in blocks of bits and then zoom in on the desired bit by binary search (i.e. successively looking a blocks that are half the size again). The exponent for the initial power used to create the masks does not need to be itself a power of two. The xsb_initial procedure uses introspection to determine the word size of a basic integer type. This is used to build a mask that fits within the basic word size of the implementation. In this way we won't create unnecessary large integers through implicit type conversions.
<lang Icon>link printf,hexcvt
procedure main()
every B := [42,2^32-1] | [1302,2^64-1] do { base := B[1] lim := B[2] fmt := sprintf("%%i^%%i = %%%is (x%%0%is) : MSB=%%s LSB=%%s\n",*lim,*hexstring(lim)) every e := seq(0) do { if (i := base^e) > lim then break printf(fmt,base,e,i,hexstring(i),msb(i)|"-",lsb(i)|"-") } }
end
procedure msb(i) #: return the most significant set bit index or fail static mask initial mask := xsb_initial()
if i > 0 then { b := 0 every m := mask[j := 1 to *mask by 2] & r := mask[j+1] do { repeat { l := iand(i,m) i := ishift(i,r) if i = 0 then break b -:= r } i := l } return b }
end
procedure lsb(i) #: return the least significant set bit index or fail static mask initial mask := xsb_initial()
if i > 0 then { b := 0 every m := mask[j := 1 to *mask by 2] & r := mask[j+1] do until iand(i,m) > 0 do { i := ishift(i,r) b -:= r } return b }
end
procedure xsb_initial() #: setup tables for lsb/msb static mask initial { # build
a := &allocated # bigint affects allocation p := if 2^63 & a=&allocated then 63 else 31 # find wordsize-1 p *:= 2 # adjust pre-loop mask := [] until (p := p / 2) = 0 do put(mask,2^p-1,-p) # list of masks and shifts } return mask # return pre-built data
end</lang>
printf.icn provides formatting hexcvt.icn provides hexstring
- Output:
42^0 = 1 (x00000001) : MSB=0 LSB=0 42^1 = 42 (x0000002A) : MSB=5 LSB=1 42^2 = 1764 (x000006E4) : MSB=10 LSB=2 42^3 = 74088 (x00012168) : MSB=16 LSB=3 42^4 = 3111696 (x002F7B10) : MSB=21 LSB=4 42^5 = 130691232 (x07CA30A0) : MSB=26 LSB=5 1302^0 = 1 (x0000000000000001) : MSB=0 LSB=0 1302^1 = 1302 (x0000000000000516) : MSB=10 LSB=1 1302^2 = 1695204 (x000000000019DDE4) : MSB=20 LSB=2 1302^3 = 2207155608 (x00000000838E8598) : MSB=31 LSB=3 1302^4 = 2873716601616 (x0000029D16DB7310) : MSB=41 LSB=4 1302^5 = 3741579015304032 (x000D4AF2401B3360) : MSB=51 LSB=5 1302^6 = 4871535877925849664 (x439B2C120A574A40) : MSB=62 LSB=6
J
Implementation:
<lang j>lwb=: 0: upb=: (#: i: 1:)"0 rlwb=: #@#:"0 - 1: rupb=: rlwb - upb</lang>
Notes:
This implementation is agnostic to numeric storage format.
J's #:
converts integers to bit lists.
lwb is the required name for the index of "first set bit in a binary value". This is always zero here. Here's why:
<lang J> #: 7 1 1 1
#: 8
1 0 0 0
#: 20
1 0 1 0 0
#: 789
1 1 0 0 0 1 0 1 0 1
#:123456789123456789123456789x
1 1 0 0 1 1 0 0 0 0 1 1 1 1 0 1 1 1 1 1 1 0 1 1 1 1 1 0 0 1 0 1 1 1 0 0 0 1 1 1 0 1 1 0 0 0 1 1 0 0 1 1 1 1 1 0 1 1 1 1 1 0 0 0 0 0 0 0 1 0 0 0 1 0 1 1 1 1 1 0 0 0 1 0 1 0 1</lang>
The the first set bit in J's binary representation for a positive integer is always the first bit of that integer (there's an exception for zero, because it has no first set bit, but that's outside the domain of this task). That said, note that this would not hold for an arbitrary integer in a list of integers. But bit representations of lists of integers is outside the scope of this task.
And the index of the first bit will always be 0.
Example use:
<lang j> (,.lwb,.upb,.rlwb,.rupb) <.i.@>.&.(42&^.) 2^64
1 0 0 0 0 42 0 4 5 1 1764 0 8 10 2 74088 0 13 16 3 3111696 0 17 21 4 130691232 0 21 26 5 5489031744 0 26 32 6 230539333248 0 30 37 7 9682651996416 0 35 43 8 406671383849472 0 39 48 9 17080198121677824 0 43 53 10
717368321110468608 0 48 59 11
(,.lwb,.upb,.rlwb,.rupb) i.@x:@>.&.(1302&^.) 2^128 1 0 0 0 0 1302 0 9 10 1 1695204 0 18 20 2 2207155608 0 28 31 3 2873716601616 0 37 41 4 3741579015304032 0 46 51 5 4871535877925849664 0 56 62 6 6342739713059456262528 0 65 72 7 8258247106403412053811456 0 74 82 8 10752237732537242494062515712 0 84 93 9 13999413527763489727269395457024 0 93 103 10 18227236413148063624904752885045248 0 102 113 11
23731861809918778839625988256328912896 0 112 124 12</lang>
Note, in the above sentences, the rightmost part of each sentence is about generating an arbitrary sequence of values. The phrase <.i.@>.&.(42&^.) 2^64 generates the sequence 1 42 1764 74088 3111696 130691232 ... and the phrase i.@x:@>.&.(1302&^.) 2^128 generates the sequence 1 1302 1695204 2207155608 ...
The left part of each sentence uses the words we defined here, organizing their results as columns in a table.
Java
Library
Notes:
- least significant bit is bit 0 (such that bit i always has value 2i, and the result is independent of integer type width)
- when the integer 0 is given, mssb() and lssb() both return no bits set; mssb_idx() and lssb_idx() will return -1 and the integer type width, respectively
<lang java>public class FirstLastBits {
// most significant set bit public static int mssb(int x) { return Integer.highestOneBit(x); }
public static long mssb(long x) { return Long.highestOneBit(x); }
public static int mssb_idx(int x) { return Integer.SIZE - 1 - Integer.numberOfLeadingZeros(x); }
public static int mssb_idx(long x) { return Long.SIZE - 1 - Long.numberOfLeadingZeros(x); }
public static int mssb_idx(BigInteger x) {
return x.bitLength() - 1;
}
// least significant set bit public static int lssb(int x) { return Integer.lowestOneBit(x); }
public static long lssb(long x) { return Long.lowestOneBit(x); }
public static int lssb_idx(int x) { return Integer.numberOfTrailingZeros(x); }
public static int lssb_idx(long x) { return Long.numberOfTrailingZeros(x); }
public static int lssb_idx(BigInteger x) {
return x.getLowestSetBit();
}
public static void main(String[] args) { System.out.println("int:"); int n1 = 1; for (int i = 0; ; i++, n1 *= 42) { System.out.printf("42**%d = %10d(x%08x): M x%08x(%2d) L x%03x(%2d)\n", i, n1, n1, mssb(n1), mssb_idx(n1), lssb(n1), lssb_idx(n1)); if (n1 >= Integer.MAX_VALUE / 42) break; } System.out.println(); System.out.println("long:"); long n2 = 1; for (int i = 0; ; i++, n2 *= 42) { System.out.printf("42**%02d = %20d(x%016x): M x%016x(%2d) L x%06x(%2d)\n", i, n2, n2, mssb(n2), mssb_idx(n2), lssb(n2), lssb_idx(n2)); if (n2 >= Long.MAX_VALUE / 42) break; }
System.out.println(); System.out.println("BigInteger:"); BigInteger n3 = BigInteger.ONE; BigInteger k = BigInteger.valueOf(1302); for (int i = 0; i < 10; i++, n3 = n3.multiply(k)) { System.out.printf("1302**%02d = %30d(x%28x): M %2d L %2d\n", i, n3, n3, mssb_idx(n3), lssb_idx(n3)); }
}
}</lang>
- Output:
int: 42**0 = 1(x00000001): M x00000001( 0) L x001( 0) 42**1 = 42(x0000002a): M x00000020( 5) L x002( 1) 42**2 = 1764(x000006e4): M x00000400(10) L x004( 2) 42**3 = 74088(x00012168): M x00010000(16) L x008( 3) 42**4 = 3111696(x002f7b10): M x00200000(21) L x010( 4) 42**5 = 130691232(x07ca30a0): M x04000000(26) L x020( 5) long: 42**00 = 1(x0000000000000001): M x0000000000000001( 0) L x000001( 0) 42**01 = 42(x000000000000002a): M x0000000000000020( 5) L x000002( 1) 42**02 = 1764(x00000000000006e4): M x0000000000000400(10) L x000004( 2) 42**03 = 74088(x0000000000012168): M x0000000000010000(16) L x000008( 3) 42**04 = 3111696(x00000000002f7b10): M x0000000000200000(21) L x000010( 4) 42**05 = 130691232(x0000000007ca30a0): M x0000000004000000(26) L x000020( 5) 42**06 = 5489031744(x00000001472bfa40): M x0000000100000000(32) L x000040( 6) 42**07 = 230539333248(x00000035ad370e80): M x0000002000000000(37) L x000080( 7) 42**08 = 9682651996416(x000008ce6b086100): M x0000080000000000(43) L x000100( 8) 42**09 = 406671383849472(x000171dd8f5fea00): M x0001000000000000(48) L x000200( 9) 42**10 = 17080198121677824(x003cae5985bc6400): M x0020000000000000(53) L x000400(10) 42**11 = 717368321110468608(x09f49aaff0e86800): M x0800000000000000(59) L x000800(11) BigInteger: 1302**00 = 1(x 1): M 0 L 0 1302**01 = 1302(x 516): M 10 L 1 1302**02 = 1695204(x 19dde4): M 20 L 2 1302**03 = 2207155608(x 838e8598): M 31 L 3 1302**04 = 2873716601616(x 29d16db7310): M 41 L 4 1302**05 = 3741579015304032(x d4af2401b3360): M 51 L 5 1302**06 = 4871535877925849664(x 439b2c120a574a40): M 62 L 6 1302**07 = 6342739713059456262528(x 157d73223c097f3a180): M 72 L 7 1302**08 = 8258247106403412053811456(x 6d4c07901d584d1176100): M 82 L 8 1302**09 = 10752237732537242494062515712(x 22be0ae76f53f17f6ce75600): M 93 L 9
Julia
Module: <lang julia>module Bits
export lwb, upb
lwb(n) = trailing_zeros(n) upb(n) = 8 * sizeof(n) - leading_zeros(n) - 1
end # module Bits</lang>
Main: <lang julia>using Main.Bits
- Using the built-in functions `leading_zeros` and `trailing_zeros`
println("# 64 bits integers:") @printf(" %-18s | %-64s | %-2s | %-2s\n", "number", "bit representation", "lwb", "upb") for n in 42 .^ (0:11)
@printf(" %-18i | %-64s | %-3i | %-3i\n", n, bits(n), lwb(n), upb(n))
end
println("\n# 128 bits integers:") @printf(" %-40s | %-2s | %-2s\n", "number", "lwb", "upb") for n in int128"1302" .^ (0:11)
@printf(" %-40i | %-3i | %-3i\n", n, lwb(n), upb(n))
end</lang>
- Output:
# 64 bits integers: number | bit representation | lwb | upb 1 | 0000000000000000000000000000000000000000000000000000000000000001 | 0 | 0 42 | 0000000000000000000000000000000000000000000000000000000000101010 | 1 | 5 1764 | 0000000000000000000000000000000000000000000000000000011011100100 | 2 | 10 74088 | 0000000000000000000000000000000000000000000000010010000101101000 | 3 | 16 3111696 | 0000000000000000000000000000000000000000001011110111101100010000 | 4 | 21 130691232 | 0000000000000000000000000000000000000111110010100011000010100000 | 5 | 26 5489031744 | 0000000000000000000000000000000101000111001010111111101001000000 | 6 | 32 230539333248 | 0000000000000000000000000011010110101101001101110000111010000000 | 7 | 37 9682651996416 | 0000000000000000000010001100111001101011000010000110000100000000 | 8 | 43 406671383849472 | 0000000000000001011100011101110110001111010111111110101000000000 | 9 | 48 17080198121677824 | 0000000000111100101011100101100110000101101111000110010000000000 | 10 | 53 717368321110468608 | 0000100111110100100110101010111111110000111010000110100000000000 | 11 | 59 # 128 bits integers: number | lwb | upb 1 | 0 | 0 1302 | 1 | 10 1695204 | 2 | 20 2207155608 | 3 | 31 2873716601616 | 4 | 41 3741579015304032 | 5 | 51 4871535877925849664 | 6 | 62 6342739713059456262528 | 7 | 72 8258247106403412053811456 | 8 | 82 10752237732537242494062515712 | 9 | 93 13999413527763489727269395457024 | 10 | 103 18227236413148063624904752885045248 | 11 | 113
Kotlin
As I have no idea what the difference is supposed to be between lwb/uwb and rlwb/ruwb (unless the former numbers bits from left to right), I have only provided implementations of the latter - using Java/Kotlin library functions - which seem to be all that is needed in any case to perform the task in hand: <lang scala>// version 1.1.0
import java.math.BigInteger
fun Long.rlwb() = when {
this <= 0L -> throw IllegalArgumentException("Receiver must be positive") else -> java.lang.Long.numberOfTrailingZeros(this) }
fun Long.ruwb() = when {
this <= 0L -> throw IllegalArgumentException("Receiver must be positive") else -> 63 - java.lang.Long.numberOfLeadingZeros(this) }
fun BigInteger.rlwb() = when {
this <= BigInteger.ZERO -> throw IllegalArgumentException("Receiver must be positive") else -> this.lowestSetBit }
fun BigInteger.ruwb() = when {
this <= BigInteger.ZERO -> throw IllegalArgumentException("Receiver must be positive") else -> this.bitLength() - 1 }
fun main(args: Array<String>) {
var pow42 = 1L for (i in 0..11) { print("42 ^ ${i.toString().padEnd(2)} = ${pow42.toString(2).padStart(64, '0').padEnd(64)} -> ") println("MSB: %2d, LSB: %2d".format(pow42.ruwb(), pow42.rlwb())) pow42 *= 42L } println() val big1302 = BigInteger.valueOf(1302) var pow1302 = BigInteger.ONE for (i in 0..6) { print("1302 ^ $i = ${pow1302.toString(2).padStart(64, '0').padEnd(64)} -> ") println("MSB: %2d, LSB: %2d".format(pow1302.ruwb(), pow1302.rlwb())) pow1302 *= big1302 }
}</lang>
- Output:
42 ^ 0 = 0000000000000000000000000000000000000000000000000000000000000001 -> MSB: 0, LSB: 0 42 ^ 1 = 0000000000000000000000000000000000000000000000000000000000101010 -> MSB: 5, LSB: 1 42 ^ 2 = 0000000000000000000000000000000000000000000000000000011011100100 -> MSB: 10, LSB: 2 42 ^ 3 = 0000000000000000000000000000000000000000000000010010000101101000 -> MSB: 16, LSB: 3 42 ^ 4 = 0000000000000000000000000000000000000000001011110111101100010000 -> MSB: 21, LSB: 4 42 ^ 5 = 0000000000000000000000000000000000000111110010100011000010100000 -> MSB: 26, LSB: 5 42 ^ 6 = 0000000000000000000000000000000101000111001010111111101001000000 -> MSB: 32, LSB: 6 42 ^ 7 = 0000000000000000000000000011010110101101001101110000111010000000 -> MSB: 37, LSB: 7 42 ^ 8 = 0000000000000000000010001100111001101011000010000110000100000000 -> MSB: 43, LSB: 8 42 ^ 9 = 0000000000000001011100011101110110001111010111111110101000000000 -> MSB: 48, LSB: 9 42 ^ 10 = 0000000000111100101011100101100110000101101111000110010000000000 -> MSB: 53, LSB: 10 42 ^ 11 = 0000100111110100100110101010111111110000111010000110100000000000 -> MSB: 59, LSB: 11 1302 ^ 0 = 0000000000000000000000000000000000000000000000000000000000000001 -> MSB: 0, LSB: 0 1302 ^ 1 = 0000000000000000000000000000000000000000000000000000010100010110 -> MSB: 10, LSB: 1 1302 ^ 2 = 0000000000000000000000000000000000000000000110011101110111100100 -> MSB: 20, LSB: 2 1302 ^ 3 = 0000000000000000000000000000000010000011100011101000010110011000 -> MSB: 31, LSB: 3 1302 ^ 4 = 0000000000000000000000101001110100010110110110110111001100010000 -> MSB: 41, LSB: 4 1302 ^ 5 = 0000000000001101010010101111001001000000000110110011001101100000 -> MSB: 51, LSB: 5 1302 ^ 6 = 0100001110011011001011000001001000001010010101110100101001000000 -> MSB: 62, LSB: 6
Mathematica / Wolfram Language
<lang Mathematica>MSB[n_]:=BitLength[n]-1 LSB[n_]:=IntegerExponent[n,2]</lang>
Map[{#,"MSB:",MSB[#],"LSB:",LSB[#]}&, Join[NestList[(42*#)&,42,5],NestList[(1302*#)&,1302,5]]]//TableForm 42 MSB: 5 LSB: 1 1764 MSB: 10 LSB: 2 74088 MSB: 16 LSB: 3 3111696 MSB: 21 LSB: 4 130691232 MSB: 26 LSB: 5 5489031744 MSB: 32 LSB: 6 1302 MSB: 10 LSB: 1 1695204 MSB: 20 LSB: 2 2207155608 MSB: 31 LSB: 3 2873716601616 MSB: 41 LSB: 4 3741579015304032 MSB: 51 LSB: 5 4871535877925849664 MSB: 62 LSB: 6
PARI/GP
This version uses PARI. These work on arbitrary-length integers; the implementation for wordsize integers would be identical to C's. <lang c>long msb(GEN n) { return expi(n); }
long lsb(GEN n) { return vali(n); }</lang>
This version uses GP. It works on arbitrary-length integers; GP cannot directly work on wordsize integers except in a vecsmall
.
<lang parigp>lsb(n)=valuation(n,2);
msb(n)=#binary(n)-1;</lang>
Perl
This is simple and works with both native and bigint numbers. <lang perl>sub msb {
my ($n, $base) = (shift, 0); $base++ while $n >>= 1; $base;
} sub lsb {
my $n = shift; msb($n & -$n);
}</lang> With large bigints, this is much faster (while as_bin seems expensive, every Math::BigInt transaction has large overhead, so Perl ops on the binary string ends up being a huge win vs. anything doing shifts, ands, compares, etc.). If we want one function to work on both types, we could easily modify this to make a Math::BigInt object if the input isn't already one. <lang perl>sub bi_msb { # Input should be a Math::BigInt object
length(shift->as_bin)-3;
}</lang> With native ints, this meets the task description assuming a 64-bit Perl: <lang perl>sub msb64 {
my($n, $pos) = (shift, 0); die "n must be a 64-bit integer)" if $n > ~0; no warnings 'portable'; # Remove this and adjust lines for 32-bit if (($n & 0xFFFFFFFF00000000) == 0) { $pos += 32; $n <<= 32; } if (($n & 0xFFFF000000000000) == 0) { $pos += 16; $n <<= 16; } if (($n & 0xFF00000000000000) == 0) { $pos += 8; $n <<= 8; } if (($n & 0xF000000000000000) == 0) { $pos += 4; $n <<= 4; } if (($n & 0xC000000000000000) == 0) { $pos += 2; $n <<= 2; } if (($n & 0x8000000000000000) == 0) { $pos += 1; $n <<= 1; } 63-$pos;
}</lang>
Phix
machine-sized integers
There is nothing like this already built in, so we will roll our own, in low-level assembly.
Of course you would normally hide this sort of stuff out of sight, far away from the usual day-to-day code.
without javascript_semantics function msb(integer i) #ilASM{ [32] mov eax,[i] bsr ecx,eax mov [i],ecx [64] mov rax,[i] bsr rcx,rax mov [i],rcx } return i end function function lsb(integer i) #ilASM{ [32] mov eax,[i] bsf ecx,eax mov [i],ecx [64] mov rax,[i] bsf rcx,rax mov [i],rcx } return i end function atom p = 1 for i=0 to 11 do printf(1,"%18d %064b MSB:%2d LSB: %2d\n",{p,p,msb(p),lsb(p)}) p *= 42 if not integer(p) then exit end if end for
- Output:
1 0000000000000000000000000000000000000000000000000000000000000001 MSB: 0 LSB: 0 42 0000000000000000000000000000000000000000000000000000000000101010 MSB: 5 LSB: 1 1764 0000000000000000000000000000000000000000000000000000011011100100 MSB:10 LSB: 2 74088 0000000000000000000000000000000000000000000000010010000101101000 MSB:16 LSB: 3 3111696 0000000000000000000000000000000000000000001011110111101100010000 MSB:21 LSB: 4 130691232 0000000000000000000000000000000000000111110010100011000010100000 MSB:26 LSB: 5 5489031744 0000000000000000000000000000000101000111001010111111101001000000 MSB:32 LSB: 6 230539333248 0000000000000000000000000011010110101101001101110000111010000000 MSB:37 LSB: 7 9682651996416 0000000000000000000010001100111001101011000010000110000100000000 MSB:43 LSB: 8 406671383849472 0000000000000001011100011101110110001111010111111110101000000000 MSB:48 LSB: 9 17080198121677824 0000000000111100101011100101100110000101101111000110010000000000 MSB:53 LSB: 10 717368321110468608 0000100111110100100110101010111111110000111010000110100000000000 MSB:59 LSB: 11
On 32-bit the table stops at msb of 26. Since this task is specifically looking for bsf/bsr it is explicitly tagged as incompatible with pwa/p2js
Aside: power(42,5) [and above] are implemented on the FPU using fyl2x, f2xm1, and fscale;
on 64-bit that results in 130691232 + ~7.3e-12 rather than the integer 130691232 exactly,
whereas repeated multiplication by 42 as shown keeps it integer for longer.
mpfr/gmp
with javascript_semantics include mpfr.e function rupbz(mpz n) integer res = mpz_sizeinbase(n,2) while res!=0 and mpz_tstbit(n,res)=0 do res -= 1 end while return res end function function rlwbz(mpz n) return mpz_scan1(n,0) end function mpz n = mpz_init(1) for i = 0 to 12 do printf(1,"1302^%02d %38s %5d %5d\n", {i,mpz_get_str(n), rupbz(n), rlwbz(n)}) mpz_mul_si(n,n,1302) end for
- Output:
1302^00 1 0 0 1302^01 1302 10 1 1302^02 1695204 20 2 1302^03 2207155608 31 3 1302^04 2873716601616 41 4 1302^05 3741579015304032 51 5 1302^06 4871535877925849664 62 6 1302^07 6342739713059456262528 72 7 1302^08 8258247106403412053811456 82 8 1302^09 10752237732537242494062515712 93 9 1302^10 13999413527763489727269395457024 103 10 1302^11 18227236413148063624904752885045248 113 11 1302^12 23731861809918778839625988256328912896 124 12
In my tests the while loop in rupbz() always iterated precisely once, suggesting it merely converts a 1-based bit count to a 0-based bit number and could be replaced by -1
Note that under pwa/p2js this will quietly perform the very kind of looping the task specifically asks not for, but at least it works, and it does not do that under desktop/Phix.
PicoLisp
<lang PicoLisp>(de msb (N)
(dec (length (bin (abs N)))) )
(de lsb (N)
(length (stem (chop (bin N)) "1")) )</lang>
Test: <lang PicoLisp>(for N (1 42 717368321110468608 291733167875766667063796853374976)
(tab (33 6 6) N (lsb N) (msb N)) )</lang>
- Output:
1 0 0 42 1 5 717368321110468608 11 59 291733167875766667063796853374976 20 107
Python
<lang python>def msb(x):
return x.bit_length() - 1
def lsb(x):
return msb(x & -x)
for i in range(6):
x = 42 ** i print("%10d MSB: %2d LSB: %2d" % (x, msb(x), lsb(x)))
for i in range(6):
x = 1302 ** i print("%20d MSB: %2d LSB: %2d" % (x, msb(x), lsb(x)))</lang>
- Output:
1 MSB: 0 LSB: 0 42 MSB: 5 LSB: 1 1764 MSB: 10 LSB: 2 74088 MSB: 16 LSB: 3 3111696 MSB: 21 LSB: 4 130691232 MSB: 26 LSB: 5 1 MSB: 0 LSB: 0 1302 MSB: 10 LSB: 1 1695204 MSB: 20 LSB: 2 2207155608 MSB: 31 LSB: 3 2873716601616 MSB: 41 LSB: 4 3741579015304032 MSB: 51 LSB: 5
Racket
<lang racket>
- lang racket
(require rnrs/arithmetic/bitwise-6) (for/list ([n 20])
(define x (expt 42 n)) (list n (bitwise-first-bit-set x) (- (integer-length x) 1)))
</lang>
- Output:
<lang racket> '((0 0 0)
(1 1 5) (2 2 10) (3 3 16) (4 4 21) (5 5 26) (6 6 32) (7 7 37) (8 8 43) (9 9 48) (10 10 53) (11 11 59) (12 12 64) (13 13 70) (14 14 75) (15 15 80) (16 16 86) (17 17 91) (18 18 97) (19 19 102))
</lang>
Raku
(formerly Perl 6)
Raku integers are arbitrary sized, and the lsb and msb methods are built-in. <lang perl6>sub table ($base,$power) {
my $digits = ($base ** $power).chars; printf "%{$digits}s lsb msb\n", 'number'; for 0..$power {
my $x = $base ** $_; printf "%{$digits}d %2d %2d\n", $x, $x.lsb, $x.msb;
}
}
table 42, 20; table 1302, 20;</lang>
- Output:
number lsb msb 1 0 0 42 1 5 1764 2 10 74088 3 16 3111696 4 21 130691232 5 26 5489031744 6 32 230539333248 7 37 9682651996416 8 43 406671383849472 9 48 17080198121677824 10 53 717368321110468608 11 59 30129469486639681536 12 64 1265437718438866624512 13 70 53148384174432398229504 14 75 2232232135326160725639168 15 80 93753749683698750476845056 16 86 3937657486715347520027492352 17 91 165381614442044595841154678784 18 97 6946027806565873025328496508928 19 102 291733167875766667063796853374976 20 107 number lsb msb 1 0 0 1302 1 10 1695204 2 20 2207155608 3 31 2873716601616 4 41 3741579015304032 5 51 4871535877925849664 6 62 6342739713059456262528 7 72 8258247106403412053811456 8 82 10752237732537242494062515712 9 93 13999413527763489727269395457024 10 103 18227236413148063624904752885045248 11 113 23731861809918778839625988256328912896 12 124 30898884076514250049193036709740244590592 13 134 40230347067621553564049333796081798456950784 14 144 52379911882043262740392232602498501590949920768 15 155 68198645270420328087990686848453049071416796839936 16 165 88794636142087267170563874276685869890984669485596672 17 175 115610616256997621856074164308245002598062039670246866944 18 186 150525022366610903656608561929334993382676775650661420761088 19 196 195983579121327396560904347631994161384245161897161169830936576 20 206
REXX
Programming note: The task's requirements state to compute powers of 1302 up the host's next "natural" long host word
size ···, but for REXX, the "natural" size is a character string (indeed, the only thing REXX knows are character strings, numbers
are expressed as character strings), so the output (below) was limited to four times the default size, but the actual (practical)
limit may be around eight million bytes (for some REXXes).
REXX programmers have no need to know what the host's word size is, as it is irrelevant.
A fair amount of coding was added to align and/or center the displaying of the numbers for the output. <lang rexx>/*REXX program finds the first and last set bit of "integer" and "long integer". */ parse arg digs . /*obtain optional argument from the CL.*/ if digs== | digs=="," then digs= 40 /*Not specified? Then use the default.*/ numeric digits max(9, digs); d= digits() /*maybe use more precision for this run*/ @= '─'; @4= copies(@, 4) /*build parts of the separator line. */
!= '│' /* " part " " output " */ do cycle=1 for 2 base= word(42 1302, cycle) /*pick an integer for this cycle. */ @d= copies(@, d) /*build part of the separator line. */ call sep '─┬─' /* ─┬─ is part of the separator line.*/ say center(base'**n (decimal)', d) ! center("rlwb", 4) ! center('rupb', 4) !, right(base"**n (binary)" , d+5) /*display the title for the output. */ call sep '─┼─' /* ─┼─ is part of the separator line.*/ do j=-1 /*traipse through all the bits. */ if j==-1 then x= 0 /*special handle the first time through*/ else x= base**j /*compute a power of BASE. */ if pos('E', x)>0 then leave /*does it have an exponent? */ say right(x, d) ! right(rlwb(x), 4) ! right(rupb(x), 4) ! bits end /*j*/ call sep '─┴─' /* ─┴─ is part of the separator line.*/ if cycle==1 then do 3; say; end /*show extra blank lines between sets. */ end /*cycle*/
exit 0 /*stick a fork in it, we're all done. */ /*──────────────────────────────────────────────────────────────────────────────────────*/ n2b: bits= word( strip( x2b( d2x( arg(1))), 'L', 0) 0, 1); L= length(bits); return bits rlwb: arg #; call n2b #; if #==0 then return 0; return L - length( strip( bits, 'T', 0)) rupb: arg #; call n2b #; if #==0 then return -1; return L - 1 sep: arg _; say @d || _ || @4 || _ || @4 || _ || copies(@, length( n2b(10**d) )); return</lang>
- output when using the internal default inputs:
(Shown at 3/4 size.)
─────────────────────────────────────────┬──────┬──────┬────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────── 42**n (decimal) │ rlwb │ rupb │ 42**n (binary) ─────────────────────────────────────────┼──────┼──────┼────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────── 0 │ 0 │ -1 │ 0 1 │ 0 │ 0 │ 1 42 │ 1 │ 5 │ 101010 1764 │ 2 │ 10 │ 11011100100 74088 │ 3 │ 16 │ 10010000101101000 3111696 │ 4 │ 21 │ 1011110111101100010000 130691232 │ 5 │ 26 │ 111110010100011000010100000 5489031744 │ 6 │ 32 │ 101000111001010111111101001000000 230539333248 │ 7 │ 37 │ 11010110101101001101110000111010000000 9682651996416 │ 8 │ 43 │ 10001100111001101011000010000110000100000000 406671383849472 │ 9 │ 48 │ 1011100011101110110001111010111111110101000000000 17080198121677824 │ 10 │ 53 │ 111100101011100101100110000101101111000110010000000000 717368321110468608 │ 11 │ 59 │ 100111110100100110101010111111110000111010000110100000000000 30129469486639681536 │ 12 │ 64 │ 11010001000100001011000001101110110000110001000010001000000000000 1265437718438866624512 │ 13 │ 70 │ 10001001001100101111001111001000101100000000001011011001010000000000000 53148384174432398229504 │ 14 │ 75 │ 1011010000010010110111111111011101100111000000111011110100100100000000000000 2232232135326160725639168 │ 15 │ 80 │ 111011000101100011000101111101001011011100110100111010000011111101000000000000000 93753749683698750476845056 │ 16 │ 86 │ 100110110001101001000001111010001001100000111010101110000110100110000010000000000000000 3937657486715347520027492352 │ 17 │ 91 │ 11001011100100100111011010000001010001111100110100010010000010100111101010100000000000000000 165381614442044595841154678784 │ 18 │ 97 │ 10000101100110000001110111000100110101110001111010010011110101101110000001111001000000000000000000 6946027806565873025328496508928 │ 19 │ 102 │ 1010111101010111101001110001001001011010010110000010001000001010000001101001111011010000000000000000000 291733167875766667063796853374976 │ 20 │ 107 │ 111001100010001100001011010010000001011010010011101011001010110100101000101100000111000100000000000000000000 12252793050782200016679467841748992 │ 21 │ 113 │ 100101110000011011111111011001110100111011010000111010010101000110100010101100111100101000101000000000000000000000 514617308132852400700537649353457664 │ 22 │ 118 │ 11000110001110010010111100110111100101110111001000110010001110110010010110001011111110010101010010000000000000000000000 21613926941579800829422581272845221888 │ 23 │ 124 │ 10000010000101011000011011111100011110110110001011110000111101101101000010100011110110111001111101110100000000000000000000000 907784931546351634835748413459499319296 │ 24 │ 129 │ 1010101010111100010000010010101101100001111100011101110001000011111100011101011100010000010000010100100001000000000000000000000000 ─────────────────────────────────────────┴──────┴──────┴────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────── ─────────────────────────────────────────┬──────┬──────┬────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────── 1302**n (decimal) │ rlwb │ rupb │ 1302**n (binary) ─────────────────────────────────────────┼──────┼──────┼────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────── 0 │ 0 │ -1 │ 0 1 │ 0 │ 0 │ 1 1302 │ 1 │ 10 │ 10100010110 1695204 │ 2 │ 20 │ 110011101110111100100 2207155608 │ 3 │ 31 │ 10000011100011101000010110011000 2873716601616 │ 4 │ 41 │ 101001110100010110110110110111001100010000 3741579015304032 │ 5 │ 51 │ 1101010010101111001001000000000110110011001101100000 4871535877925849664 │ 6 │ 62 │ 100001110011011001011000001001000001010010101110100101001000000 6342739713059456262528 │ 7 │ 72 │ 1010101111101011100110010001000111100000010010111111100111010000110000000 8258247106403412053811456 │ 8 │ 82 │ 11011010100110000000111100100000001110101011000010011010001000101110110000100000000 10752237732537242494062515712 │ 9 │ 93 │ 1000101011111000001010111001110110111101010011111100010111111101101100111001110101011000000000 13999413527763489727269395457024 │ 10 │ 103 │ 10110000101100101000101101110101000100000011010011101110001111100001001111100000100011110110010000000000 18227236413148063624904752885045248 │ 11 │ 113 │ 111000001010101100000100010100010101100000011011010011001110101111101110010001100000011001010001101001100000000000 23731861809918778839625988256328912896 │ 12 │ 124 │ 10001110110101001011100011111110101101101100001101011011001001101111110110111011000001001000010001101000010010001000000000000 ─────────────────────────────────────────┴──────┴──────┴──────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
Ruby
<lang ruby>def msb(x)
x.bit_length - 1
end
def lsb(x)
msb(x & -x)
end
6.times do |i|
x = 42 ** i puts "%10d MSB: %2d LSB: %2d" % [x, msb(x), lsb(x)]
end
6.times do |i|
x = 1302 ** i puts "%20d MSB: %2d LSB: %2d" % [x, msb(x), lsb(x)]
end</lang>
- Output:
1 MSB: 0 LSB: 0 42 MSB: 5 LSB: 1 1764 MSB: 10 LSB: 2 74088 MSB: 16 LSB: 3 3111696 MSB: 21 LSB: 4 130691232 MSB: 26 LSB: 5 1 MSB: 0 LSB: 0 1302 MSB: 10 LSB: 1 1695204 MSB: 20 LSB: 2 2207155608 MSB: 31 LSB: 3 2873716601616 MSB: 41 LSB: 4 3741579015304032 MSB: 51 LSB: 5
Seed7
The library integer.s7i defines the functions bitLength and lowestSetBit, which compute the most- and least-significant set bit in a binary value expressed in LSB 0 bit numbering.
<lang seed7>$ include "seed7_05.s7i";
include "bigint.s7i";
const func integer: rlwb (in integer: num) is
return lowestSetBit(num);
const func integer: rupb (in integer: num) is
return bitLength(num);
const func integer: rlwb (in bigInteger: num) is
return lowestSetBit(num);
const func integer: rupb (in bigInteger: num) is
return bitLength(num);
const proc: main is func
local var integer: i is 0; var integer: num is 0; var bigInteger: bigNum is 0_; begin for i range 0 to 5 do num := 42 ** i; writeln(num lpad 10 <& " " <& num radix 2 lpad0 32 <& " MSB: " <& rupb(num) lpad 2 <& " LSB: " <& rlwb(num) lpad 2); end for; for i range 0 to 9 do bigNum := 1302_ ** i; writeln(bigNum lpad 30 <& " " <& bigNum radix 16 lpad0 26 <& " MSB: " <& rupb(bigNum) lpad 2 <& " LSB: " <& rlwb(bigNum) lpad 2); end for; end func;</lang>
- Output:
1 00000000000000000000000000000001 MSB: 1 LSB: 0 42 00000000000000000000000000101010 MSB: 6 LSB: 1 1764 00000000000000000000011011100100 MSB: 11 LSB: 2 74088 00000000000000010010000101101000 MSB: 17 LSB: 3 3111696 00000000001011110111101100010000 MSB: 22 LSB: 4 130691232 00000111110010100011000010100000 MSB: 27 LSB: 5 1 00000000000000000000000001 MSB: 1 LSB: 0 1302 00000000000000000000000516 MSB: 11 LSB: 1 1695204 0000000000000000000019dde4 MSB: 21 LSB: 2 2207155608 000000000000000000838e8598 MSB: 32 LSB: 3 2873716601616 00000000000000029d16db7310 MSB: 42 LSB: 4 3741579015304032 0000000000000d4af2401b3360 MSB: 52 LSB: 5 4871535877925849664 0000000000439b2c120a574a40 MSB: 63 LSB: 6 6342739713059456262528 0000000157d73223c097f3a180 MSB: 73 LSB: 7 8258247106403412053811456 000006d4c07901d584d1176100 MSB: 83 LSB: 8 10752237732537242494062515712 0022be0ae76f53f17f6ce75600 MSB: 94 LSB: 9
Sidef
Sidef has arbitrary sized integers.
<lang ruby>func msb(n) {
var b = 0 while(n >>= 1) { ++b } return b
}
func lsb(n) {
msb(n & -n)
}</lang>
Test cases:
<lang ruby>func table (base,power) {
var digits = length(base**power) printf("%#{digits}s lsb msb\n", 'number') for n in (0..power) { var x = base**n printf("%#{digits}s %2s %3s\n", x, lsb(x), msb(x)) }
}
table(42, 20) table(1302, 20)</lang>
Tcl
<lang tcl>proc lwb {x} {
if {$x == 0} {return -1} set n 0 while {($x&1) == 0} {
set x [expr {$x >> 1}] incr n
} return $n
} proc upb {x} {
if {$x == 0} {return -1} if {$x < 0} {error "no well-defined max bit for negative numbers"} set n 0 while {$x != 1} {
set x [expr {$x >> 1}] incr n
} return $n
}</lang> Code to use the above: <lang tcl>package require Tcl 8.6; # For convenient bit string printing
proc powsTo {pow bits} {
set result {} for {set n 1} {$n < 2**$bits} {set n [expr {$n * $pow}]} {
lappend result $n
} return $result
} proc printPows {pow pows} {
set len [string length [lindex $pows end]] puts [format "%8s | %*s | LWB | UPB | Bits" "What" $len "Number"] set n 0 foreach p $pows {
puts [format "%4d**%-2d = %*lld | %3d | %3d | %b" \ $pow $n $len $p [lwb $p] [upb $p] $p] incr n
}
}
puts "Powers of 42 up to machine word size:" printPows 42 [powsTo 42 [expr {$tcl_platform(wordSize) * 8}]] puts "Powers of 1302 up to 128 bits" printPows 1302 [powsTo 1302 128]</lang>
- Output:
Powers of 42 up to machine word size: What | Number | LWB | UPB | Bits 42**0 = 1 | 0 | 0 | 1 42**1 = 42 | 1 | 5 | 101010 42**2 = 1764 | 2 | 10 | 11011100100 42**3 = 74088 | 3 | 16 | 10010000101101000 42**4 = 3111696 | 4 | 21 | 1011110111101100010000 42**5 = 130691232 | 5 | 26 | 111110010100011000010100000 Powers of 1302 up to 128 bits What | Number | LWB | UPB | Bits 1302**0 = 1 | 0 | 0 | 1 1302**1 = 1302 | 1 | 10 | 10100010110 1302**2 = 1695204 | 2 | 20 | 110011101110111100100 1302**3 = 2207155608 | 3 | 31 | 10000011100011101000010110011000 1302**4 = 2873716601616 | 4 | 41 | 101001110100010110110110110111001100010000 1302**5 = 3741579015304032 | 5 | 51 | 1101010010101111001001000000000110110011001101100000 1302**6 = 4871535877925849664 | 6 | 62 | 100001110011011001011000001001000001010010101110100101001000000 1302**7 = 6342739713059456262528 | 7 | 72 | 1010101111101011100110010001000111100000010010111111100111010000110000000 1302**8 = 8258247106403412053811456 | 8 | 82 | 11011010100110000000111100100000001110101011000010011010001000101110110000100000000 1302**9 = 10752237732537242494062515712 | 9 | 93 | 1000101011111000001010111001110110111101010011111100010111111101101100111001110101011000000000 1302**10 = 13999413527763489727269395457024 | 10 | 103 | 10110000101100101000101101110101000100000011010011101110001111100001001111100000100011110110010000000000 1302**11 = 18227236413148063624904752885045248 | 11 | 113 | 111000001010101100000100010100010101100000011011010011001110101111101110010001100000011001010001101001100000000000 1302**12 = 23731861809918778839625988256328912896 | 12 | 124 | 10001110110101001011100011111110101101101100001101011011001001101111110110111011000001001000010001101000010010001000000000000
Wren
<lang ecmascript>import "/big" for BigInt import "/fmt" for Fmt
var rupb = Fn.new { |x| (x is BigInt) ? x.bitLength - 1 : x.log2.floor } var rlwb = Fn.new { |x| rupb.call(x & -x) }
System.print("Powers of 42 below 2^32 using Num:") var x = 1 for (i in 0..5) {
Fmt.print("42^$d = $,11d rupb: $2d rlwb: $2d", i, x, rupb.call(x), rlwb.call(x)) x = x * 42
}
System.print("\nPowers of 1302 below 2^64 using BigInt:") x = BigInt.new(1) for (i in 0..6) {
Fmt.print("1302^$d = $,25s rupb: $2s rlwb: $2s", i, x, rupb.call(x), rlwb.call(x)) x = x * 1302
}</lang>
- Output:
Powers of 42 below 2^32 using Num: 42^0 = 1 rupb: 0 rlwb: 0 42^1 = 42 rupb: 5 rlwb: 1 42^2 = 1,764 rupb: 10 rlwb: 2 42^3 = 74,088 rupb: 16 rlwb: 3 42^4 = 3,111,696 rupb: 21 rlwb: 4 42^5 = 130,691,232 rupb: 26 rlwb: 5 Powers of 1302 below 2^64 using BigInt: 1302^0 = 1 rupb: 0 rlwb: 0 1302^1 = 1,302 rupb: 10 rlwb: 1 1302^2 = 1,695,204 rupb: 20 rlwb: 2 1302^3 = 2,207,155,608 rupb: 31 rlwb: 3 1302^4 = 2,873,716,601,616 rupb: 41 rlwb: 4 1302^5 = 3,741,579,015,304,032 rupb: 51 rlwb: 5 1302^6 = 4,871,535,877,925,849,664 rupb: 62 rlwb: 6
Yabasic
<lang yabasic>print "INT: find first & last set bit" p = 1 for j = 0 to 5
print p using("##########"), " MSB: ", MSB(p) using("##"), " LSB: ", LSB(p) p = p * 42
next j print end
sub MSB(i)
return len(bin$(i))-1
end sub
sub LSB(i)
return MSB(and(i,-i))
end sub</lang>
- Output:
INT: find first & last set bit 1 MSB: 0 LSB: 0 42 MSB: 5 LSB: 1 1764 MSB: 10 LSB: 2 74088 MSB: 16 LSB: 3 3111696 MSB: 21 LSB: 4 130691232 MSB: 26 LSB: 5
zkl
This uses the Int method log2 (== MSB position), which returns the log base 2 of self. log2 is implemented with shifts and ors (it is a 5 step loop (for 64 bit ints) which could obviously be unrolled). See http://graphics.stanford.edu/~seander/bithacks.html. <lang zkl>fcn lsb(n){ n.bitAnd(n.bitNot()+1).log2() } fcn msb(n){ n.log2() }
foreach p in (200){
n:=(42).pow(p); println("42^%2d = %18d(x%015x): MSB(%2d) LSB(%2d)".fmt(
p,n,n, msb(n), lsb(n)));
if (n>=(1).MAX / 42) break;
}</lang>
- Output:
42^ 0 = 1(x000000000000001): MSB( 0) LSB( 0) 42^ 1 = 42(x00000000000002a): MSB( 5) LSB( 1) 42^ 2 = 1764(x0000000000006e4): MSB(10) LSB( 2) 42^ 3 = 74088(x000000000012168): MSB(16) LSB( 3) 42^ 4 = 3111696(x0000000002f7b10): MSB(21) LSB( 4) 42^ 5 = 130691232(x000000007ca30a0): MSB(26) LSB( 5) 42^ 6 = 5489031744(x0000001472bfa40): MSB(32) LSB( 6) 42^ 7 = 230539333248(x0000035ad370e80): MSB(37) LSB( 7) 42^ 8 = 9682651996416(x00008ce6b086100): MSB(43) LSB( 8) 42^ 9 = 406671383849472(x00171dd8f5fea00): MSB(48) LSB( 9) 42^10 = 17080198121677824(x03cae5985bc6400): MSB(53) LSB(10) 42^11 = 717368321110468608(x9f49aaff0e86800): MSB(59) LSB(11)
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