# Tag Info

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I think you want to unpack with C (8-bit unsigned) rather than B (bit string) since the xor operator ^ operates on numbers rather than strings: 'AA'.unpack('C*').zip('BB'.unpack('C*')).map { |a,b| a^b } # => [3, 3] 3 is what one would expect from xoring 65 ('A') with 66 ('B').

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Doubtful. with bit fields you will get 2^n different arrangements but there are n! different permutations

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std::atomic<T*> class provide only atomic inc/dec pointer operations. If you want more complicated atomic operation, it can build with compare-and-swap(CAS) loop. When CAS operaton fails, 1st argument of atomic::compare_exchange_weak are updated latest value. So CAS loop can be little simplified. (omit memory_order for explanation) ...

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public static int divide(int a, int b){ boolean n = false; if(b==0) return -1; if(b==1) return a; if(a<0){ n = true; a = -a;} if(b<0){ n = true; b = -b;} if(a<0 && b<0) n = false; while(b!=1){ a = (a>>1); b = (b>>1); } if (n) return -a; else return a; }

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See Lua logical operators as described at http://www.lua.org/manual/5.1/manual.html#2.5.3.

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if input range is bounded and small, use input as index into a lookup table of results...

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I will just go over the bit type operators. if(value & 0x01): This checks to see if the least significant bit is a 1 or 0. If it is a zero we don't do anything. Array[(byte_offset + ((bit_offset + Bit_Offset + i)/ 8))] Since all values in the array are a single byte, byte_offset is the index of where we are going to OR the bit. Added to ...

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Since version 5.2 Lua comes with bit32 library. bit32.band is equivalent to & operator in php. LuaJIT also has bit operations. Edit Well, they're not exactly equivalent, but serve the same purpose.

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As well as the obvious bitwise XOR solution, you can also exploit the fact that a boolean expression returns 1 or 0, e.g. int f(int x) { return (x == 5) * 7 + (x == 7) * 5; } and there are other simple arithmetic methods, e.g. int f(int x) { return 12 - x; }

7

int fun(int p) { return p^2; }

3

I hope this is no homework I do for you: int mysteriousFunction( int x ) { return (x ^ 2); }

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This will not work for a prefix length that is not a power of 8. Consider a length of 20, you want 0xF0FFFF (network order). That means you'll want to do something like this: PrefixLength ? htonl(~((1 << (32 - PrefixLength)) - 1)) : 0 Or see this answer. But you will need a htonl call or something more complicated than a simple shift to get a ...

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The result is, indeed, converted back to a number, i.e., a 64-bit precision floating point number. However, before it is converted back, both operands are converted to UInt32, then the right shift operation is performed. This is specified in ECMAScript here: http://www.ecma-international.org/ecma-262/5.1/#sec-11.7.3 The net result of length >>> 0 ...

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The ECMAScript specification states that the value is converted to UInt32 in step 5 and 8 of http://www.ecma-international.org/ecma-262/5.1/#sec-11.7: 11.7.3 The Unsigned Right Shift Operator ( >>> ) Performs a zero-filling bitwise right shift operation on the left operand by the amount > specified by the right operand. The production ...

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Bit shift is just like multiplication or division, so you can do like others said. But you can do it without division/multiplication, just add or subtract itself since add a number with itself is like multiply it by 2, hence improve performance a bit unsigned int result = x; for (i = 0; i < shift; i++) result += result; Take care of the case of ...

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Assuming the measurements you are trying to retrieve are truly doubles: If you know the allowable range of the measurement, I would multiply them by a factor of 0xFFFFFFFF/MAX_RANGE factor to give you a value between 0 and int max. Then you can do long int value = double*FACTOR; for (i=0;i<32;i++) { long int nextval = value / 2; char bit = ...

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A left shift 1 is equal to a multiply by 2, a right shift 1 is equal to (integer) division by 2. So, a left shift of 3 is equal to multiplication by 8 (because it is 23). #include <stdio.h> int main() { int a = 17 << 4; int b = 17 * 16; if (a == b) { printf("%i\n", b); } else { puts("false"); } } Output is 272

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Shifting a value is equivalente to multiply/divide by two (using integer math): a / 2 equivalent to a >> 1 a * 2 equivalent to a << 1 You need to check that the scripting language do integer math (or use the floor() or int() or trunc() or wathever the language offers). Be also careful with overflow, if the scripting language uses ...

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Others have provided the explanations. >>> shifts all the bits, even the sign bit (the MSB). >> keeps the sign bit in place and shifts all the others. This is best explained with some sample code: int x=-64; System.out.println("x >>> 3 = " + (x >>> 3)); System.out.println("x >> 3 = " + (x >> 3)); ...

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Double Arrows ">>" and Triple Arrows ">>>" are defined on 32-bit integers, so performing these on a variable will "convert" them so-to-speak from non-numbers, to numbers. Additionally, javascript numbers are stored as double precision floats, so these operations will also cause you to lose any precision bits higher than 32 . ">>" maintains the sign bit ...

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The modulo operation does not give you the inverted bits per se, it is just a bining op. First Line : word expansion b * 0x0202020202 = 01001010 *01001010* 01001010 *01001010* 01001010 0 The multiplication operation has a convolution property, which means it replicate the input variable several times (5 here since it's a 8-bit word). First Line : ...

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C passes all of its function parameters by value, not by reference. That means functions cannot modify their parameters directly: void NoChange(int i) { printf("Before: %d\n", i); i = 10; // Changes only the local copy of the variable. printf("After: %d\n", i); } main() { int n = 1; printf("Start: %d\n", n); NoChange(n); printf("End: %d\n", ...

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scanf("%d", &e); is the correct answer as others have pointed out. The scanf function needs a pointer to where you want it to store the data, otherwise it doesn't know where your variable is. Since scanf was expecting a pointer it converted the uninitialized value stored inside e to a pointer and stored the result there. This is undefined behaviour, a ...

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scanf("%d",&e); You are missing &.

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In the first pseudo-code, the remainder is initialized with leading portion of the input bit string. Then during iterations, in each step the remainder is up-shifted, and the now-vacant bottom bit is filled with the next bit from the input bit string. To complete the operation, the input bit string needs to be appended with zero. These zeros will ...

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Afaik, the JVM will just convert whatever you code into 32 bit chunks whatever you do. JVM is 32 bit. I think even 64 bit version of JVM largely processes in 32 bit chunks. It certainly should to conserve memory... You're just going to slow down your code as the JIT tries to optimise the mess you create. In C/C++ etc. there's no point doing this either as ...

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Your byte order swapping is fine, however building the integer from the sequences of bytes is not. First of all, you get the endianness wrong: the first byte you read in becomes the most significant byte, while it should be the other way around. Then, when OR-ing in the characters from the array, be aware that they are promoted to an int, which, for a ...

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Use %x to view the consistent hex result. #include <stdio.h> void main() { unsigned int a = 10; printf("%x\n", a); a = ~a; printf("%x\n", a); return 0; } Output: a fffffff5

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use %u instead of %d because printf treats your variable according to %d or %u. u for

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%d is for signed decimal integer. Use %u to print an unsigned integer in decimal.

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The result of ~1010 is not 0101 but 11111111111111111111111111110101. All 32 bits of the value are reversed, not only the bits up to the highest set bit. As the 32nd bit is set in the result, it's negative.

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As a complement, I precise that if you are looking for efficiency there are some built-in hardware instructions to perform computations on bits (counting zeros: you can deduce how many 1-bit you have then) see this article as an example.

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A shorter and simpler way to find number of set bits in an int is following: int num_1_bits(unsigned int x) // or unsigned long x; or unsigned short x; { int bitcount = 0; while(x) { x &= (x - 1); ++bitcount; } return bitcount; } How does this work? For an unsigned number x, the sequence of bits in x - 1 will be the ...

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Counting the number of 1-bits is relatively straightforward; you iterate over all of the bits of your number and add to some accumulator the number of bits that are set: unsigned int X; unsigned int count; for (count = 0; X; X >>= 1) { count += X & 1; } How it works: Initialize count to 0 Start from the MSB (most significant bit) ...

0

Change this: float x = o.getX() + (std::pow(-1, i&1) * r1), y = o.getY() + (std::pow(-1, i&2) * r2), z = o.getZ() + (std::pow(-1, i&4) * r3); To this: float x = o.getX() + (std::pow(-1, (i ) & 1) * r1), // pow(-1, 0) == 1, pow(-1, 1) == -1 y = o.getY() + (std::pow(-1, (i >> 1) & 1) * r2), // pow(-1, 0) == ...

0

Here's another intuition that gives a clean and simple algorithm for solving the problem. An initial algorithm using O(n) space. For now, let's ignore the O(1) memory constraint. Suppose that you can use O(n) memory (if the matrix is m × n). That would make this problem a lot easier and we could use the following strategy: Create an boolean array ...

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In [184]: df = pd.DataFrame([1, 2, 3, 4, 5, 6, 7, 8], columns=['data']) In [185]: mask = 0b1100 In [186]: np.bitwise_and(df['data'], mask) Out[186]: 0 0 1 0 2 0 3 4 4 4 5 4 6 4 7 8 Name: data, dtype: int64 It even returns a Series -- pretty cool!

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In your case since you know only one bit is set, so it's enough to count trailing zeros. This can be done without a hardware instruction very quickly. Check out this answer, that's where the code below comes from (I'm not one to tamper with perfection... sometimes). unsigned v; // this is the number with one bit set unsigned r; // this becomes the ...

1

Here is a funny idea... If you know there is only 1 bit set, then why not use a switch? unsigned int get_log_two(unsigned int x) { switch(x) { case 1<<0: return 0; case 1<<1: return 1; case 1<<2: return 2; case 1<<3: return 3; case 1<<4: return 4; ...

1

The problem lies in the bitwise & inside your pow calls: In the y and z components, they always return 0 and 2 or 4, respectively. -1^2 = -1^4 = 1, which is why the sign of these components is always positive. You could try (i&2)!=0 or (i&2) >> 1 for the y component instead. The same goes for the z component.

2

Apart from ways previously said by others, such as BSF or CLZ instructions which strictly depend on the underlying ISA, there are some other ways such as: http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogObvious in fact here you could find a lot of 'bit twiddling hacks' there.

2

As a side-note, you should consider renaming function get_power_of_two to get_log_two. If you are calling this function very often, then you can initialize a relatively small look-up table. Using this table, you can check every input number, byte by byte, as follows: #include <limits.h> static unsigned int table[1<<CHAR_BIT]; void ...

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The efficiency of your algorithm is O(log x), whereas Dave's (which performs binary search on powers of two) is O(log log x). So his is asymptotically faster. The fastest approach, of course, is to use the BSF instruction.

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You can't do this easily/well with bitwise operators in java. The solution is to use a ByteBuffer. ByteBuffer byteBuffer = ByteBuffer.allocate(4); byteBuffer.put((byte)0); byteBuffer.put((byte)0); byteBuffer.put((byte)1); byteBuffer.put((byte)-14); byteBuffer.rewind(); int bodyLength = byteBuffer.getInt(); System.out.println(bodyLength); The above code ...

1

Remember a is byte. So when you do a << 8, won't it shift 8 positions right, effectively making it 0. It promotes the result to int. I would suggest to define a as int. Updated: int c = ((a << 8) | ~(~0 << 8) & b); will result in expected answer of 498

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If you shift everything in a byte 8 bits, you've shifted everything completely off. ORing with a completely zeroed out byte is the same as adding zero or multiplying by 1...

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Problem 1 You’re right on the money. I’d do an & and a >> so that you get either a nice 0 or 1. result = (z & 0x08) >> 3; However, this may not be strictly necessary. For example, if you’re trying to check whether the bit is set as part of an if conditional, you can exploit C’s definition of anything nonzero as true. if (z & ...

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To find out the value of the fifth bit, you don't care about the bottom bits so you can get rid of them: unsigned int answer = z >> 4; The fifth bit becomes the bottom bit, so you can strip it off with a bitwise-AND: answer = answer & 1; To find the number of 1-bits in a number you can apply stakSmashr's solution. You could optimise this ...

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Problem 1 looks right, except you should finish it by shifting the result right by 4 to get that bit after the mask. To implement the mask, you need to know what integer is represented by a single 5th bit. That number is incidentally 2^5 = 32. So you can just AND z with 32 and shift it right by 4. Problem 2: int answer = 0; while (z != 0){ //stop when ...

0

A method that can help modulo reduction of all integer values uses bit-slicing and popcount. mod3 = pop(x & 0x55555555) + pop(x & 0xaaaaaaaa) << 1; // <- one term is shared! mod5 = pop(x & 0x99999999) + pop(x & 0xaaaaaaaa) << 1 + pop(x & 0x44444444) << 2; mod7 = pop(x & 0x49249249) + pop(x & 0x92492492) ...

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