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Given

int x=1,y=2,z;

Could you explain why the result for:

x && y || z 

is 1?

x && y = 1
x && y || z = 1
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11  
What the hell is the bounty for? Does the question really remain unsatisfactorily answered? –  Armen Tsirunyan Sep 19 '11 at 19:24
    
Whenever you are unsure whether the code really does what you intended it to do, use brackets. They make the code more readable. It is not "cool" to stuff everything you can into a single statement that can only be parsed when you know ever corner of the language. –  PlasmaHH Sep 19 '11 at 20:29
    
Re: "What the hell is the bounty for?" -- Often people offer a bounty on satisfactorily answered questions as a means to provide an additional reward to the answerer. That is explicitly allowed, though the person offering the bounty still has a waiting period before they can award it. –  Kevin Stricker Sep 20 '11 at 3:33
    
@mootinator: that may be, but I thought this wasn't the kind of question... :) –  Armen Tsirunyan Sep 20 '11 at 9:51
4  
@PaulPRO: Please stop offering bounties on questions for no apparent reason. –  Lightness Races in Orbit Sep 22 '11 at 13:10
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8 Answers

up vote 18 down vote accepted
+50
x && y || z 

is equivalent to

(x && y) || z

if x=1 and y=2 then x&&y is 1 && 2 which is true && true which is true.

true || z 

is always true. z isn't even evaluated

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x && y || z => (x && y) || z => 1 || z => 1

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(bool)1 = true
(bool)2 = true

Uninitialized int refers to data that was saved in memory, where it is placed on stack... and it rarely is 0x00000000, and even if it was, true || false = true.

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The && operator has higher precedence than the || operator. See, e.g., this operators precedence table, numbers 13 and 14.

Your example evaluates as (x && y) || z. Thanks to the short circuiting rule, z is never evaluated because the result of x && y is already true.

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+1 for mentioning short-circuiting. I think that's the key piece here. –  Cory Kendall Sep 26 '11 at 7:02
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You can think of x && y || z as equivalent to:

int func(int x, int y, int z) {
  if (x) {
    if (y) {
      return true;
    }
  }
  if (z) {
    return true;
  }
  return false;
}

Since both x and y are fixed to be non-zero values the first return statement is always hit.

On IA32, without optimisation x && y || z becomes:

        movl    $1, 28(%esp)        ; store 1 in x (on stack)
        movl    $2, 24(%esp)        ; store 2 in y (on stack)
        cmpl    $0, 28(%esp)        ; compare x to 0
        je      .L6                 ; if x is 0 jump to L6
        cmpl    $0, 24(%esp)        ; compare y to 0
        jne     .L7                 ; if y is 0 jump to L7
.L6:                                ; We only get to L6 if (x && y) was false
        cmpl    $0, 20(%esp)        ; compare z to 0
        je      .L8                 ; if z is 0 jump to L8
.L7:                                ; We get to this label if either (x && y) was true
                                    ; or z was true
        movl    $1, %eax            ; copy 1 into register eax, the result
        jmp     .L9                 ; jump unconditionally to L9
.L8:                                ; We only get here if both (x && y) and z are false
        movl    $0, %eax            ; copy 0 into register eax, the result
.L9:

And func becomes:

        cmpl    $0, 8(%ebp)        ; compare first argument (x) with 0
        je      .L2                ; jump to L2 if it is
        cmpl    $0, 12(%ebp)       ; compare second argument (y) with 0
        je      .L2                ; jump to L2 if it is
        movl    $1, %eax           ; store 1 for the return value (via register eax)
        jmp     .L3                ; jump to L3 (done, return to caller)
.L2:                               ; if we hit this label both x and y were false
        cmpl    $0, 16(%ebp)       ; compare third argument (z) with 0
        je      .L4                ; if it is 0 jump to L4
        movl    $1, %eax           ; store 1 in register eax, which is the return value
        jmp     .L3                ; jump to L3 (return to caller)
.L4:                               ; if we get here x, y and z were all 0
        movl    $0, %eax           ; store 0 in eax to return false
.L3:

With optimizations enabled func() looks even more like the expression (the return value only gets loaded from one place, although it's obscured by x86-isms), but the expression x && y || z basically disappears since the compiler is able to deduce its value at compile time.

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Because x && y is evaluated as (x != 0) && (y != 0), which is equivalent with 1 && 1 resulting 1. And 1 || 0 is 1, no matter what y value is.

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The && operator has higher precedence than the || operator

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There are 2 components here:

  1. Precedence
  2. Short-circuitry

If it helps you remember, in terms of mathematical operators, || can be replaced with the plus sign "+", which consists of 2 bars and as && can be replaced with a "." and has the multiplication's precedence over the "+" :-)

In C++ and C, when a boolean expression is being evaluated and the result can logically be inferred from a certain term, the following terms do not get evaluated: false && (expr2) is false AND expr2 does not get evaluated. true || (expr3) is true AND expr3 does not get evaluated.

I hope this helps =)

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