For the case where A and B are both integers, floating point types, or pointers:

## What does `while (a && b)`

do when `a`

and `b`

are both integers, floating point types, or pointers?

AKA: rules of `int`

egers or other numbers being cast to `bool`

s.

## Short answer

When `a`

and `b`

are both integers, floating point types, or pointers, writing `while (a && b)`

is equivalent to `while ((bool)a && (bool)b)`

, and whenever you cast an one of these types to a `bool`

, *zero is *`false`

and everything else is `true`

.

If `(bool)a`

is false (value zero), then it stops evaluating early, since certainly `a && b`

cannot be true if the first part of that test is false.

## When does "contextual conversion to bool" apply?

This concept applies to `if`

, `for`

, `while`

, and `do { } while`

blocks, not just `while`

. It applies to `!`

, `||`

, and `&&`

operators. The operands in such expressions are "said to be *contextually converted to bool*".

See here:

- @MSalters' comment. Thank you.
- https://en.cppreference.com/w/cpp/language/implicit_conversion and search for "contextually converted to bool". This source says that the "contextual conversion to bool" occurs for all of the following situations:
- the controlling expression of
`if`

, `while`

, `for`

- the operands of the built-in logical operators
`!`

, `&&`

and `||`

- the first operand of the conditional [ternary] operator
`? :`

- the predicate in a
`static_assert()`

declaration
- the expression in a
`noexcept`

specifier
- the expression in an
`explicit`

specifier (since C++20)

## Details

`while (a && b)`

is exactly equivalent to `while ((bool)a == true && (bool)b == true)`

, which is also exactly equivalent to `while (a != 0 && b != 0)`

or (same thing): `while (a != false && b != false)`

.

Those can be read as: "while integers, floating point types, or pointers a and b are both true when cast to bool", or as: "while integers, floating point types, or pointers a and b are both non-zero."

I think most people prefer the `while (a && b)`

form, however, since it's the shortest and still easy to read.

The key takeaway is:

These all mean and do the same thing:

```
int a = 2;
int b = 3;
// // or
// float a = 2.0;
// float b = 3.0;
// // or
// int* a = (int*)0x11223344UL;
// int* b = (int*)0xaabbccddUL;
// // etc.
// these are all **equivalent**!:
// 1. "true"-based forms
while (a && b) {}; // shortest and most-often used version
while ((bool)a && (bool)b) {}; // most-explicit and clear version
while ((bool)a == true && (bool)b == true) {};
while (((bool)a == true) && ((bool)b == true)) {};
// 2. "false"-based forms (these all are exactly equivalent to the "true"-based
// forms above)
while (a != 0 && b != 0) {};
while ((a != 0) && (b != 0)) {};
while (a != false && b != false) {};
// etc.
```

The following, however, are NOT the same as the examples above:

```
while (a == true && b == true) {};
while ((a == true) && (b == true)) {};
```

This is because `true`

is defined strictly as `1`

(and `false`

is defined strictly as `0`

). *Therefore, even though *`a == 1`

is **false** when `a`

is `2`

, `(bool)a == 1`

is **true** when `a`

is *any non-zero integer*, including `2`

.

_{Note: this answer has been completely rewritten and fixed for correctness, and moved to here from this now-deleted question here: What does while (a && b) do when a and b are both integers? [duplicate]. That question was deleted under the premise it was a duplicate of this question, hence why I moved my answer to here.}

`if (p && p->bar) { }`

. This is also safe.