# Boolean true - positive 1 or negative 1?

I'm designing a language, and trying to decide whether `true` should be 0x01 or 0xFF. Obviously, all non-zero values will be converted to true, but I'm trying to decide on the exact internal representation.

What are the pros and cons for each choice?

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0 is false because the processor has a flag that is set when a register is set to zero.

No other flags are set on any other value (0x01, 0xff, etc) - but the zero flag is set to false when there's a non-zero value in the register.

So the answers here advocating defining 0 as false and anything else as true are correct.

If you want to "define" a default value for true, then 0x01 is better than most:

• It represents the same number in every bit length and signedness
• It only requires testing one bit if you want to know whether it's true, should the zero flag be unavailable, or costly to use
• No need to worry about sign extension during conversion to other types
• Logical and arithmetic expressions act the same on it
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"It only requires testing one bit if you want to know whether it's true, should the zero flag be unavailable, or costly to use". That seems wrong. If 0 is defined as false and 1 is just the default value, wouldn't you have to test every bit anyway? – Niki Apr 7 '09 at 20:35
Perhaps "default" is the wrong term. He's suggesting 1 as the SINGLE value for TRUE in this case, but also pointing out how "!= 0" has value. – Will Hartung Apr 7 '09 at 20:37
Niki, point taken - As Will indicates, I was suggesting that if you chose to enforce a "true" value, then you'd have to enforce it universally. – Adam Davis Apr 7 '09 at 21:03

It doesn't matter, as long as it satisfies the rules for the external representation.

I would take a hint from C here, where false is defined absolutely as 0, and true is defined as not false. This is an important distinction, when compared to an absolute value for true. Unless you have a type that only has two states, you have to account for all values within that value type, what is true, and what is false.

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this also makes the language implementation easier and probably more efficient. true == !false that is – Henry B Apr 7 '09 at 19:36
A fuzzy definition of true will bite you when you run into the misguided souls who write if(condition==true) ... – Mark Ransom Apr 7 '09 at 21:06
@Mark Ransom: It's not fuzzy at all. It is the set of everything that is not zero. That is a well-defined set. – casperOne Apr 8 '09 at 3:33
Fuzzy wasn't the right word; perhaps loose? If true isn't defined to be a single value, then comparing to "true" is asking for trouble, and there are people who have trouble understanding that. – Mark Ransom Apr 8 '09 at 19:37
@Mark Ransom: Which is why inherently comparing to true is a bad thing if the set of values that true and false can be represented in is more than two. .NET gets this right by explicitly creating a type for boolean values and limiting it to just TWO values. The same needs to be done here. – casperOne Apr 8 '09 at 19:41

Why are you choosing that non-zero values are true? In Ada true is TRUE and false is FALSE. There is no implicit type conversion to and from BOOLEAN.

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I agree. However Ada went a little overboard in my opinion. – fuzzy-waffle Apr 7 '09 at 19:43
Internally they have to end up being 1,0 or otherwise... I can't think of any processors that can represent true/false without resorting to at least a binary flag. :-) – Brian Knoblauch Apr 7 '09 at 19:44
In my experience implicit conversions almost always lead to hard to understand convoluted sections of code. Even explicit conversions can cause issue. True is TRUE, false is FALSE. These Boolean values are not numbers. – Jim C Apr 7 '09 at 19:56
@Jim C - The problem is that at some level they have to become numbers on our common architectures... – Brian Knoblauch Apr 8 '09 at 18:45
Yes but fixating on this or leaking this abstraction can be the wrong choice depending on the aim of the language. – fuzzy-waffle Apr 9 '09 at 21:39

Using -1 has one advantage in a weakly typed language -- if you mess up and use the bitwise `and` operator instead of the logical `and` operator, your condition will still evaluate correctly as long as one of the operands has been converted to the canonical boolean representation. This isn't true if the canonical representation is 1.

``````  0xffffffff & 0x00000010 == 0x00000010 (true)
0xffffffff && 0x00000010 == 0xffffffff (true)
``````

but

``````  0x00000001 & 0x00000010 == 0x00000000 (false)
0x00000001 && 0x00000010 == 0xffffffff (true)
``````
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Some would argue that the fact that it continues to work in a somewhat less predictable way in the presence of a programming error is not a selling point. – tylerl Apr 7 '09 at 20:41
Point taken, but in a weakly typed language you'd probably just get erroneous results the other way, without knowing it. Which do you prefer accidental correctness or intermittent, undetectable errors? Another reason to do TDD, I guess. – tvanfosson Apr 7 '09 at 20:48

IMO, if you want to stick with false=0x00, you should use 0x01. 0xFF is usually:

• a sign that some operation overflowed

or

• an error marker

And in both cases, it probably means false. Hence the *nix return value convention from executables, that true=0x00, and any non-zero value is false.

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+1 Good point - seeing a stack dump with 0xff as a parameter would tend to raise a red flag, and in this case would be a false positive for the programmer. – Not Sure Apr 7 '09 at 19:22
@Varkhan: It should be noted that VB went this way to define true as 0xFF and it was definitely more trouble than it was worth. Quite frankly, it's a horrible idea to define true in terms of an absolute value instead of a logic condition. – casperOne Apr 7 '09 at 19:37
@Varkhan: "that true=0x00, and any non-zero value is false" -- that's slightly inaccurate: A return value of 0 means "success", and other value are "error" codes. This is because there are many types of errors, but only one success. The fact that /bin/true returns 0 is an unfortunate side effect. – tylerl Apr 7 '09 at 20:38

0xff is an odd choice since it has an implicit assumption that 8 bits is your minimum storage unit. But it's not that uncommon to want to store boolean values more compactly than that.

Perhaps you want to rephrase by thinking about whether boolean operators produce something that is just one 0 or 1 bit (which works regardless of sign extension), or is all-zeroes or all-ones (and depends on sign extension of signed two's-complement quantities to maintain all-ones at any length).

I think your life is simpler with 0 and 1.

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The pros are none, and the cons are none, too. As long as you provide an automatic conversion from integer to boolean, it will be arbitrary, so it really doesn't matter which numbers you choose.

On the other hand, if you didn't allow this automatic conversion you'd have a pro: you wouldn't have some entirely arbitrary rule in your language. You wouldn't have `(7 - 4 - 3) == false`, or `3 * 4 + 17 == "Hello"`, or `"Hi mom!" == Complex(7, -2)`.

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-1 is longer to type than 1...

In the end it doesn't matter since 0 is false and anything else is true, and you will never compare to the exact representation of true.

Edit, for those down voting, please explain why. This answer is essentially the same as the one currently rated at +19. So that is 21 votes difference for what is the same basic answer.

If it is because of the -1 comment, it is true, the person who actually defines "true" (eg: the compiler writer) is going to have to use -1 instead of 1, assuming they chose to use an exact representation. -1 is going to take longer to type than 1, and the end result will be the same. The statement is silly, it was meant to be silly, because there is no real difference between the two (1 or -1).

If you are going to mark something down at least provide a rationale for it.

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Don't forget ~0. – Bill Lynch Apr 7 '09 at 19:29

I think the C method is the way to go. 0 means false, anything else means true. If you go with another mapping for true, then you are left with the problem of having indeterminate values - that are neither true nor false.

If this is language that you'll be compiling for a specific instruction set that has special support for a particular representation, then I'd let that guide you. But absent any additional information, for an 'standard' internal representation, I'd go with -1 (all 1's in binary). This value extends well to whatever size boolean you want (single bit, 8-bit, 16, etc), and if you break up a "TRUE" or a "FALSE" into a smaller "TRUE" or "FALSE", its still the same. (where if you broke a 16 bit TRUE=0x0001 you'd get a FALSE=0x00 and a TRUE=0x01).

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Design the language so that 0 is false and non-zero is true. There is no need to "convert" anything, and thinking "non-zero" instead of some specific value will help you write the code properly.

If you have built-in symbols like "True" then go ahead and pick a value, but always think "non-zero is true" instead of "0x01 is true".

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Whatever you do, once you select your values don't change them. In FORTH-77, true and false were defined as 1 and 0. Then, FORTH-83 redefined them as -1 and 0. There were a not few (well ok, only a few, this is FORTH we are talking about) problems caused by this.

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Yes, see, for example, Logical AND in Forth? – Peter Mortensen Mar 28 '13 at 14:24