# Tag Info

258

Two's complement is a clever way of storing integers so that common math problems are very simple to implement. To understand, you have to think of the numbers in binary. It basically says, for zero, use all 0's. for positive integers, start counting up, with a maximum of 2(number of bits - 1)-1. for negative integers, do exactly the same thing, but ...

236

Assume for the sake of contradiction that there exists some x and some y (mod 2n) such that ~(x+y) == ~x + ~y By two's complement*, we know that, -x == ~x + 1 <==> -1 == ~x + x Noting this result, we have, ~(x+y) == ~x + ~y <==> ~(x+y) + (x+y) == ~x + ~y + (x+y) <==> ~(x+y) + (x+y) == (~x + x) + (~y + y) <==> ...

170

It's done so that addition doesn't need to have any special logic for dealing with negative numbers. Check out the article on Wikipedia. Say you have two numbers, 2 and -1. In your "intuitive" way of representing numbers, they would be 0010 and 1001, respectively (I'm sticking to 4 bits for size). In the two's complement way, they are 0010 and 1111. Now, ...

113

Two's Complement On the vast majority of computers, if x is an integer, then -x is represented as ~x + 1. Equivalently, ~x == -(x + 1). Making this substution in your equation gives: ~x + ~y == ~(x + y) -(x+1) + -(y+1) = -((x + y) + 1) -x - y - 2 = -x - y - 1 -2 = -1 which is a contradiction, so ~x + ~y == ~(x + y) is always false. That said, the ...

97

I wonder if it could be explained any better than the Wikipedia article. The basic problem that you are trying to solve with two's complement representation is the problem of storing negative integers. First consider an unsigned integer stored in 4 bits. You can have the following 0000 = 0 0001 = 1 0010 = 2 ... 1111 = 15 These are unsigned because there ...

69

Your program is invoking undefined behavior because of an overflow in the conversion from floating-point to integer. What you see is only the usual symptom on x86 processors. The float value nearest to 2147483584 is 231 exactly (the conversion from integer to floating-point usually rounds to the nearest, which can be up, and is up in this case. To be ...

60

Because two's complement bit-arithmetic makes it so Cribbed from the wikipedia page and expanded: Most Significant Bit 6 5 4 3 2 1 0 Value 0 0 0 0 0 0 1 1 3 0 0 0 0 0 0 1 0 2 0 0 0 0 0 0 0 1 1 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 -1 1 1 ...

59

Oddly, the reason this works with -1 is exactly the same as the reason that this works with zeros: in two's complement binary representation, -1 has 1s in all its bits, regardless of the size of the integer, so filling in a region with bytes filled with all 1s produces a region of -1 signed ints, longs, and shorts on two's complement hardware. On hardware ...

52

Like most explanations I've seen, the ones above are clear about how to work with 2's complement, but don't really explain what they are mathematically. I'll try to do that, for integers at least, and I'll cover some background that's probably familiar first. Recall how it works for decimal:   2345 is a way of writing   2 × 103 + ...

41

You are actually quite close. In binary , not 0 should be 1 Yes, this is absolutely correct when we're talking about one bit. HOWEVER, an int whose value is 0 is actually 32 bits of all zeroes! ~ inverts all 32 zeroes to 32 ones. System.out.println(Integer.toBinaryString(~0)); // prints "11111111111111111111111111111111" This is the two's ...

39

The width used in format is always a minimum width. In this case, instead of using sub string operations I would suggest: String.format("%05X", decInt & 0xFFFFF);

33

Java integers are of 32 bits, and always signed. This means, the most significant bit (MSB) works as the sign bit. The integer represented by an int is nothing but the weighted sum of the bits. The weights are assigned as follows: Bit# Weight 31 -2^31 30 2^30 29 2^29 ... ... 2 2^2 1 2^1 0 2^0 Note that the ...

32

Consider only the rightmost bit of both x and y (IE. if x == 13 which is 1101 in base 2, we will only look at the last bit, a 1) Then there are four possible cases: x = 0, y = 0: LHS: ~0 + ~0 => 1 + 1 => 10 RHS: ~(0 + 0) => ~0 => 1 x = 0, y = 1: LHS: ~0 + ~1 => 1 + 0 => 1 RHS: ~(0 + 1) => ~1 => 0 x = 1, y = 0: I will leave this up to you ...

31

Lets start by summarizing Java primitive data types: byte: Byte data type is a 8-bit signed two's complement integer. Short: Short data type is a 16-bit signed two's complement integer. int: Int data type is a 32-bit signed two's complement integer. long: Long data type is a 64-bit signed two's complement integer. float: Float data type is a ...

30

DANGER: gnibbler's answer (currently the highest ranked) isn't correct. Sadly, I can't figure out how to add a comment to it. Two's compliment subtracts off (1<<bits) if the highest bit is 1. Taking 8 bits for example, this gives a range of 127 to -128. A function for two's compliment of an int... def twos_comp(val, bits): """compute the 2's ...

30

ISO C (C99), section 6.2.6.2/2, states that an implementation must choose one of three different representations for integral data types, two's complement, one's complement or sign/magnitude (although it's incredibly likely that the two's complement implementations far outweigh the others). In all those representations, positive numbers are identical, the ...

27

If the number of bits is n ~x = (2^n - 1) - x ~y = (2^n - 1) - y ~x + ~y = (2^n - 1) +(2^n - 1) - x - y => (2^n + (2^n - 1) - x - y ) - 1 => modulo: (2^n - 1) - x - y - 1. Now, ~(x + y) = (2^n - 1) - (x + y) = (2^n - 1) - x - y. Hence, they'll always be unequal, with a difference of 1.

27

Hint: x + ~x = -1 (mod 2n) Assuming the goal of the question is testing your math (rather than your read-the-C-specifications skills), this should get you to the answer.

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Because the integer overflows. When it overflows, the next value is Integer.MIN_VALUE. Relevant JLS If an integer addition overflows, then the result is the low-order bits of the mathematical sum as represented in some sufficiently large two's-complement format. If overflow occurs, then the sign of the result is not the same as the sign of the ...

20

1.How do computers represent negative numbers? Take the positive value, invert all bits and add one. 2.Why do computers represent negative numbers this way? It makes easy to add 7 in -7 and came up with a zero. The bit operations are fast. How does it make it easy? Take the 7 and -7 example. If you represent 7 as 00000111, to find -7 invert ...

18

Why is the range of unsigned byte is from -128 to 127? It's not. An unsigned byte (assuming 8-bit) is from 0 to 255. The range of a signed byte using 2's complement is from -128 to 127, directly from the definition of 2's complement: 01111111 = +127 01111110 = +126 01111101 = +125 ... 00000001 = +1 00000000 = 0 11111111 = -1 ... 10000010 = -126 ...

18

Addition and subtraction are the same, as is the low-half of a multiply. A full multiply, however, is not. Simple example: In 32-bit twos-complement, -1 has the same representation as the unsigned quantity 2**32 - 1. However: -1 * -1 = +1 (2**32 - 1) * (2**32 - 1) = (2**64 - 2**33 + 1) (Note that the low 32-bits of both results are the same; that's ...

16

Question 1: "Is it a convention of negative binary numbers to have the most significant bit indicate the sign?" There are multiple ways to represent negative numbers in binary. The most common is the two's-complement representation that you're learning about. In that system, yes, the highest-order bit will indicate the sign of the number (if 0 is ...

16

The integer storage gets overflowed and that does not throw any exception: The built-in integer operators do not indicate overflow or underflow in any way. The only numeric operators that can throw an exception (§11) are the integer divide operator / (§15.17.2) and the integer remainder operator % (§15.17.3), which throw an ArithmeticException if ...

16

Wikipedia says it all: The two's-complement system has the advantage of not requiring that the addition and subtraction circuitry examine the signs of the operands to determine whether to add or subtract. This property makes the system both simpler to implement and capable of easily handling higher precision arithmetic. Also, zero has only a single ...

15

Bytes are signed in Java. In binary 0x00 is 0, 0x01 is 1 and so on but all 1s (ie 0xFF) is -1, oxFE is -2 and so on. See Two's complement, which is the binary encoding mechanism used.

14

You just have to check the low order bits of the constant -1 with something like -1 & 3. This evaluates to for sign and magnitude, for one's complement and for two's complement. This should even be possible to do in a preprocessor expression inside #if #else constructs.

13

BitConverter can easily convert the two bytes in a two-byte integer value: // assumes byte[] Item = someObject.GetBytes(): short num = BitConverter.ToInt16(Item, 4); // makes a short // out of Item[4] and Item[5]

13

It's not built in, but if you want unusual length numbers then you could use the bitstring module. >>> from bitstring import Bits >>> a = Bits(bin='111111111111') >>> a.int -1 The same object can equivalently be created in several ways, including >>> b = Bits(int=-1, length=12) It just behaves like a string of bits ...

13

This seems to trick java into converting the number without forcing a positive result: Integer.valueOf("FFFF",16).shortValue(); // evaluates to -1 (short) Of course this sort of thing only works for 8, 16, 32, and 64-bit 2's complement: Short.valueOf("FF",16).byteValue(); // -1 (byte) Integer.valueOf("FFFF",16).shortValue(); // -1 (short) ...

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