`unsigned`

integers have some strange properties and you should avoid them unless you have a good reason. Gaining 1 extra bit of positive size, or expressing a constraint that a value may not be negative, are **not** good reasons.

`unsigned`

integers implement arithmetic *modulo *`UINT_MAX+1`

. By contrast, operations on `signed`

integers represent the natural arithmetic that we are familiar with from school.

**Overflow semantics**

`unsigned`

has well defined overflow; `signed`

does not:

```
unsigned u = UINT_MAX;
u++; // u becomes 0
int i = INT_MAX;
i++; // undefined behaviour
```

This has the consequence that signed integer overflow can be caught during testing, while an unsigned overflow may silently do the wrong thing. So use `unsigned`

only if you are sure you want to legalize overflow.

If you have a constraint that a value may not be negative, then you need a way to detect and reject negative values; `int`

is perfect for this. An `unsigned`

will accept a negative value and silently overflow it into a positive value.

**Bit shift semantics**

Bit shift of `unsigned`

by an amount not greater than the number of bits in the data type is always well defined. Bit shift of `signed`

is undefined if it would cause a 1 in the sign bit to be shifted left, or implementation-defined if it would cause a 1 in the sign bit to be shifted right. So use `unsigned`

for some kinds of bit twiddling operations.

**Mixed sign operations**

The built-in arithmetic operations always operate on operands of the same type. If they are supplied operands of different types, the "usual arithmetic conversions" coerce them into the same type, sometimes with surprising results:

```
unsigned u = 42;
std::cout << (u * -1); // 4294967254
std::cout << std::boolalpha << (u >= -1); // false
```

**What's the difference?**

Subtracting an `unsigned`

from another `unsigned`

yields an `unsigned`

result, which means that the difference between `2`

and `1`

is `4294967295`

.

**Double the max value**

`int`

uses one bit to represent the sign of the value. `unsigned`

uses this bit as just another numerical bit. So typically, `int`

has 31 numerical bits and `unsigned`

has 32. This extra bit is often cited as a reason to use `unsigned`

. But if 31 bits are insufficient for a particular purpose, then most likely 32 bits will also be insufficient, and you should be considering 64 bits or more.

**Function overloading**

The implicit conversion from `int`

to `unsigned`

has the same rank as the conversion from `int`

to `double`

, so the following example is ill formed:

```
void f(unsigned);
void f(double);
f(42); // error: ambiguous call to overloaded function
```

**Interoperability**

Many APIs (including the standard library) use `unsigned`

types, often for misguided reasons. It is sensible to use `unsigned`

to avoid mixed-sign operations when interacting with these APIs.

**Appendix**

The quoted snippet includes the expression `0 <= grade <= 100`

. This will first evaluate `0 <= grade`

, which is always `true`

, because `grade`

can't be negative. Then it will evaluate `true <= 100`

, which is always `true`

, because `true`

is converted to the integer `1`

, and `1 <= 100`

is `true`

.

`unsigned`

here. – MikeMB Feb 24 '16 at 7:06`unsigned`

actually increases the required complexity of the code. To make this work,`cin >> astring`

and then parse the string into an unsigned datatype with`strtoul`

or`std::stoul`

.`strtoul`

would probably be preferable here because it can handle the exit condition without throwing an exception. – user4581301 Feb 24 '16 at 7:24`0 <= grade <= 100`

probably doesn't do what you expect. IIRC some compilers also warn about that kind of mistake, but I might be wrong here... – anderas Feb 24 '16 at 7:493more comments