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The XOR operation (^) inverts bit 0. So the expression effectively means: if bit 0 of x is 0, or any other bit of x is 1, then the expression is true. Conversely the expression is false if x = 1. So the test is the same as: if (x != 1) and is therefore (arguably) unnecessarily obfuscated.


You are actually doing this: var_dump(0b10 & (0b01 == 0)); var_dump(0b10 & (0b01 != 0)); Try: var_dump((0b10 & 0b01) == 0); var_dump((0b10 & 0b01) != 0);


^ is a XOR operation. 0x1 is 1 in hex format. x ^ 0x1 will invert the last bit of x. So, the condition (( 0 != ( x ^ 0x1 ) ) will be true if x is greater than 1 or if the last bit of x is 0. Which only leaves x==1 as a value at which the condition will be false. So it is equivalent to if (x != 1)


This can be done using SSE2 as follows: void ExpandSSE2(unsigned __int64 in, unsigned __int64 &outLo, unsigned __int64 &outHi) { __m128i const mask = _mm_set1_epi16((short)0xF00F); __m128i const mul0 = _mm_set1_epi16(0x0011); __m128i const mul1 = _mm_set1_epi16(0x1000); __m128i v; v = _mm_cvtsi64_si128(in); // move the 64-bit ...


This may seem as oversimplified explanation, but if someone would like to go through it slowly it is below: ^ is a bitwise XOR operator in c, c++ and c#. A bitwise XOR takes two bit patterns of equal length and performs the logical exclusive OR operation on each pair of corresponding bits. Exclusive OR is a logical operation that outputs true ...


Yes, it is true. It should be readily apparent that a necessary condition for y > x is that at least one bit position is set to 1 in y but 0 in x. As & cannot set a bit to 1 if the corresponding operand bits were not already 1, the result cannot be larger than the operands.


It is exclusive OR (XOR) operator. To understand how it works you can run this simple code std::cout << "0x0 ^ 0x0 = " << ( 0x0 ^ 0x0 ) << std::endl; std::cout << "0x0 ^ 0x1 = " << ( 0x0 ^ 0x1 ) << std::endl; std::cout << "0x1 ^ 0x0 = " << ( 0x1 ^ 0x0 ) << std::endl; std::cout << ...


I'm not sure what the most efficient way would be, but this is a little shorter: #include <stdio.h> int main() { unsigned x = 0x1234; x = (x << 8) | x; x = ((x & 0x00f000f0) << 4) | (x & 0x000f000f); x = (x << 4) | x; printf("0x1234 -> 0x%08x\n",x); return 0; } If you need to do this repeatedly and very ...


Use: ~0U >> 1 Suffix 'U' for unsigned shift behavior. so, confused that why not ~0 turns out to be 0xffffffff? See, what is 0 say in four bytes representation: BIT NUMBER 31 0 ▼ ▼ number bits 0000 0000 0000 0000 0000 0000 0000 0000 ▲ ...


It checks that x is actually not 0x1... xoring x with 0x1 will result in 0 only if x is 0x1 ... this is an old trick mostly used in assembly language


The ^ operator is bitwise xor. And 0x1 is the number 1, written as a hexadecimal constant. So, x ^ 0x1 evaluates to a new value that is the same as x, but with the least significant bit flipped. The code does nothing more than compare x with 1, in a very convoluted and obscure fashion.


and tests whether both expressions are logically True while & (when used with True/False values) tests if both are True. In Python, empty built-in objects are typically treated as logically False while non-empty built-ins are logically True. This facilitates the common use case where you want to do something if a list is empty and something else if the ...


Is there any way I can optimize the condition if (m == 0 || n == 0) (using bit operations)??? The answer is a resounding no for just about every platform, unless either m or n are extremely likely to be 0 and the arguments are not passed in registers: The compiler will produce optimal code if you ask for optimization, most likely something along the ...


You have a signed int, so numbers are in two's complement. This is what happens 00..01 = 1 00..10 = 2 [...] 01..00 = 1073741824 10..00 = -2147483648 // Highest bit to one means -01..11 - 1 = -(2^31) 00..00 = 0 You cannot reach INT_MAX, at most you will have 2^30. As pointed out in the comments, c++ standard does not enforce 2's complement, so this code ...


Here's another attempt, using eight operations: b = (((c & 0x0F0F) * 0x0101) & 0x00F000F) + (((c & 0xF0F0) * 0x1010) & 0xF000F00); b += b * 0x10; printf("%x\n",b); //Shows '0x11223344' *Note, this post originally contained quite different code, based on Interleave bits by Binary Magic Numbers from Sean Anderson's bithacks page. ...


Clear the relevant bits of *b and set them to the bits you want from a: *b = (*b & ~0xC) | ((a & 0x300) >> 6); // This is the 'not' of 00001100, in other words, 11110011 ~0xC; // This zeros the bits of *b that you do not want (b being a pointer) *b & ~0xC; // *b & 11110011 //This clears all of a except the bits that you want a & 0x300; // Shift the ...


You could use a 256-byte table for each byte of your 16-bit number, crafted so that your even/odd condition is satisfied. Hand-code the table entries (or use the algorithm you already have) to create the tables, and then the shuffling will be done at compile time. That would essentially be a translation table concept.


An alternative is: int myOpaqueColor = 0xffffffff; byte factor = 20;// 0-255; int color = ( factor << 24 ) | ( myOpaqueColor & 0x00ffffff ); Or using float: int myOpaqueColor = 0xffffffff; float factor = 0.7f;// 0-1; int color = ( (int) ( factor * 255.0f ) << 24 ) | ( myOpaqueColor & 0x00ffffff); You can change any channel by ...


|| and && uses short circuit evaluation From same article Short-circuit evaluation, minimal evaluation, or McCarthy evaluation denotes the semantics of some Boolean operators in some programming languages in which the second argument is only executed or evaluated if the first argument does not suffice to determine the value of the ...


In C or C++, you would typically define macros for bit masks and combine them as desired. /* widget.h */ #define WIDGET_FOO 0x00000001u #define WIDGET_BAR 0x00000002u /* widget_driver.c */ static uint32_t *widget_control_register = (uint32_t*)0x12346578; int widget_init (void) { *widget_control_register |= WIDGET_FOO; if (*widget_control_register ...


You want to shift by 6*4 = 24 bits, not just 6 bits. Each '0' in the hex printf represents 4 bits. unsigned int part_1b = part_1 >> 24; ^^


Before ~ is done static_cast<unsigned char>(0) is converted to int (integer promotion happens), so after ~ it becomes all-one bits int. This then is shifted and truncated to 8 bits in bitset.


ffs() from <strings.h> returns the position of the first bit set, where the bits are numbered starting at 1 for the least significant bit (and ffs(0) returns zero): unsigned a = 0x0D; unsigned b = 0x09; unsigned x = a ^ b; int pos = ffs(x) - 1; if (pos == -1) { // a and b are equal } else { // pos is the position of the first difference }


Since << promotes its arguments to unsigned int, you need to mask off the upper bits of the shift result: printf("%d\n", (((a << no) & 0xFF) | (a >> (8-no)))); Demo on ideone (prints 5).


Acutually, it's even easier than Tanmay suggests. It turns out that most of the pairs are redundant: (A^B)|(A^C)|(B^C) == (A^B)|(A^C) and (A^B)|(A^C)|(A^D)|(B^C)|(B^D)|(C^D) == (A^B)|(A^C)|(A^D), etc. So you can just XOR each element with the first, and OR the results: result = 0; for (i=1; i<N;i++){ result|=data[0]^data[i]; }


Under most implementations, that operator does an arithmetic shift for signed types, so it preserves the sign bit (which is the leftmost bit), in this case 1. As @Clifford correctly pointed out, the language standard leaves the implementation of >> up to the implementor. See the Wikipedia article for details.


One clarification: The operators &= and |= are NOT bitwise operators when evaluated on bools - they are logical operators, but they are the equivalent of x = x & y and x = x | y, which do not short circuit like && and || do. From MSDN: The & operator performs a bitwise logical AND operation on integral operands and logical AND on ...


XOR is a self-inverse - so you can just use: byteVar3 = byteVar.Merge(byteVar2); (I'm not sure that "merge" is a particularly good name here, mind you... you've just got an XOR operation. It's not even clear why you'd want a separate method for it.)


Like this, perhaps: bool result = x == y; unsigned int z = -result;

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