I still haven't found a reason why the lowest signed negative number doesn't have an equivalent signed positive number? I mean in a 3 digit binary number for simplicity 100 is 4? but we can't have a positive 4 in signed format because we can't. It overflows. So how do we know two's complement 1000 is 4 1000 0000 is 128 and so on? We have no original positive number

One way to think about it is that signed, two's complement format works by assigning each bit a power of two, then flipping the sign of the last power of two. Let's look at 4, for example, which is represented as 100. This means that the value is
If we want to get the positive version of this value, we'd have to negate it to get
Notice that this value is equal to
In other words, the normal binary representation of this value is 100. However, we're in trouble here, because we're using a signed two's complement representation, which means that we have specifically reserved the 4's bit as the sign bit. Consequently, when we try to interpret the bit pattern 100 as a signed, threebit, two's complement value, it comes back out identically to what we started with. The shortage of bits is what's hurting here. More generally, given n bits, of which the first is the sign bit in a two's complement representation, trying to compute 1000...00 will give back the same value, because the bit needed to store the large positive value has the special meaning assigned to it. So why do this at all? The reason for this is that if you have only n bits, you cannot store the values 2^{n  1} through 2^{n  1}, because there are 2^{n} + 1 different numbers here and only 2^n different bit patterns. Excluding the largest positive number thus makes it possible to hold all the different numbers in the bit pattern specified. But why drop the high value and not the low value? This is in order to preserve binary compatibility with unsigned integers. In an unsigned integer, the values 0 through 2^{n1}  1 are all encoded using the standard basetwo representation. Consequently, for unsigned and signed integers to agree at all, the unsigned integers are designed so that they are bitforbit equivalent with the first 2^{n  1} unsigned integers, which range from 0 to 2^{n  1}  1, inclusive. After this, the unsigned values need the most significant bit to encode numbers, but the signed values are using this as the sign bit. Hope this helps! 


Compiler usually take advantage of the fact that integer overflow is undefined behavior in C to perform some optimizations. Relying on signed integer overflows that wrap is unsafe. A well known example of compiler optimization is the following
most of the compilers today ( 


A. There is an even number of possibilities to ndigit binary number, so we can't represent the same range for positive and negative numbers. B. We want that every number that begin with 1 will be negative, and every number begin with 0 will be nonegative. (not the opposite, because we want same represent to positive and zero in signed and unsinged. Because of that, 0 is in the half of the positives, so them have one place less. 


The missing digit is 


The alternative to two's complement has such a property, it's known as one's complement. One's complement works by simply inverting all the bits in the number itself. But what about the bit representation Instead, we use two's complement, which is similar to one's complement, but after inverting the bits, we add one. So if we know that A different way of looking at it is "if the highest bit is set, then the number is negative". That means that the positive range is Lets assume we're dealing with a 3bit signed number in two's complement. That'd give us the following table:
You can see that there's the same quantity of positive numbers as negative numbers, it's just that the negative numbers don't start from 0 like the positive set does. 


Because you have to count 0. The integer range [4,1] (or, equivalently 4,3,2 and 1) contains 4 numbers and the rest of the range [0,3] (or, equivalently 0, 1, 2 and 3) contains 4 numbers, for a total of 8, and 3 digit binary numbers have 2 to the power of 3 (=8) possible combinations. Think of it this way. Any integer range of the form [n,+n] necessarily has an odd size (2*n+1 integers). Whatever integer binary representation you use will have a different number of negative and positive numbers because the number of combinations is always even (powers of 2). 


Your mistake is thinking that we need a two's complement representation of the positive number in order to compute the two's complement representation of the negative number. The process for finding the two's complement of a negative number is: Start out with the normal, nontwo's complement representation of the absolute value of the number to be represented. So for 4, take the nontwo's complement representation of 4, 100. Flip all the bits: 100 > 011 (or ...11111011 with the ones continuing indefinitely to the left). Add one: 011 > 100 (or ...11111100) Now truncate to the number of bits you're using (this eliminates the carry bit or the infinite string of 1s). As a result, 100 is the 3bit, two's complement representation of 4. To go the other way, take the two's complement representation (100) flip the bits (011) and add one (100) you now have the nontwo's complement representation of 4. 1*2^2 + 0*2^1 + 0*2^0 = 4. Therefore we know that representation we started off with, 100, is the 3bit, two's complement representation of 4. 

