I'm working with embedded C for the first time. Although my C is rusty, I can read the code but I don't really have a grasp on why certain lines are the way the are. For example, I want to know if a variable is true or false and send it back to another application. Rather than setting the variable to 1 or 0, the original implementor chose 0xFF.

Is he trying to set it to an address space? or else why set a boolean variable to be 255?


0xFF sets all the bits in a char.

The original implementer probably decided that the standard 0 and 1 wasn't good enough and decided that if all bits off is false then all bits on is true.

That works because in C any value other than 0 is true. Though this will set all bytes in a char, it will also work for any other variable type, since any one bit being set in a variable makes it true.

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    0xFF sets all the bits in a char. What it does to an integer is implementation/size/signed dependent – Steve Fallows Oct 13 '08 at 14:15
  • That's true, my mistake. – QuantumPete Oct 13 '08 at 14:49
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    As an aside, it's also the reason VB uses the value -1 for true values, and 0 for false values. -1 is all 1's in 2's compliment. – Kibbee Oct 13 '08 at 18:42
  • @Steve: even to a char it is implementation dependant (eg. if CHAR_BIT != 8). – Alexandre C. Jul 28 '11 at 14:16
  • "Probably decided ... wasn't good enough" sounds like wild speculation to me. – Olof Forshell Oct 27 '12 at 14:57

If you are in desperate need of memory, you might want to store 8 booleans in one byte (or 32 in a long, or whatever)

This can easily be done by using a flag mask:

  // FLAGMASK = ..1<<n for n in 0..7...
  FLAGMASK = 0x10;    // e.g. n=4

  flags &= ~FLAGMASK; // clear bit
  flags |= FLAGMASK;  // set bit
  flags ^= FLAGMASK;  // flip bit
  flags = (flags & ~FLAGMASK) | (booleanFunction() & FLAGMASK); // clear, then maybe set

this only works when booleanFunction() returns 0 (all bits clear) or -1 (all bits set).

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    Is this an answer to the original question? – Olof Forshell Oct 27 '12 at 6:53

0xFF is the hex representation of ~0 (i.e. 11111111)

In, for example, VB and Access, -1 is used as True.


These young guys, what do they know?

In one of the original embedded languages - PL/M (-51 yes as in 8051, -85, -86, -286, -386) - there was no difference between logical operators (!, &&, || in C) and bitwise (~, &, |, ^). Instead PL/M has NOT, AND, OR and XOR taking care of both categories. Are we better off with two categories? I'm not so sure. I miss the logical ^^ operator (xor) in C, though. Still, I guess it would be possible to construct programs in C without having to involve the logical category.

In PL/M False is defined as 0. Booleans are usually represented in byte variables. True is defined as NOT False which will give you 0ffh (PL/M-ese for C's 0xff).

To see how the conversion of the status flag carry took place defore being stored in a byte (boolean wasn't available as a type) variable, PL/M could use the assembly instruction "sbb al,al" before storing. If carry was set al would contain 0ff, if it wasn't it would contain 0h. If the opposite value was required, PL/M would insert a "cmc" before the sbb or append a "not al" after (actually xor - one or the other).

So the 0xff for TRUE is a direct compatibility port from PL/M. Necessary? Probably not, unless you're unsure of your skills (in C) AND playing it super safe.

As I would have.

PL/M-80 (used for the 8080, 8085 and Z80) did not have support for integers or floats, and I suspect it was the same for PL/M-51. PL/M-86 (used for the 8086, 8088, 80188 and 80186) added integers, single precision floating point, segment:offset pointers and the standard memory models small, medium, compact and large. For those so inclined there were special directives to create do-it-yourself hybrid memory models. Microsoft's huge memory model was equivalent to intel's large. MS also sported tiny, small, compact, medium and large models.


Often in embedded systems there is one programmer who writes all the code and his/her idiosyncrasies are throughout the source. Many embedded programmers were HW engineers and had to get a system running as best they could. There was no requirement nor concept of "portability". Another consideration in embedded systems is the compiler is specific for the CPU HW. Refer to the ISA for this CPU and check all uses of the "boolean".

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    Uninformed speculation. – Olof Forshell Oct 27 '12 at 6:55

As others have said, it's setting all the bits to 1. And since this is embedded C, you might be storing this into a register where each bit is important for something, so you want to set them all to 1. I know I did similar when writing in assembler.

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    Is this an answer to the original question? – Olof Forshell Oct 27 '12 at 6:56
  • Yes it is. Did you miss the bit where I answered both what the assignment does and one reason why you might want to do that? – Paul Tomblin Oct 27 '12 at 11:54
  • The question was why someone would use 0xff instead of 0x01 to denote TRUE in C. The question was not why someone used the eight bits in a byte as eight separate T/F fields. – Olof Forshell Oct 27 '12 at 14:51
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    As opposed to your complete history of PL/M? Do you really think PL/M is relevant here? Maybe instead of slagging off everybody else's answer, you could devote yourself to improving yours. You could start by removing the 3/4 of it that's off topic and boring. – Paul Tomblin Oct 27 '12 at 15:05
  • The 8051 was introduced in 1980 and PL/M in 1972. The only language alternative was assembly so decision-makers were rational and used PL/M unless assembly was absolutely neccessary. Since I need to spell it out: PL/M is the only language for the 8051 that uses 0xff for TRUE. When intel stopped supporting it the new high-level development language of choice was C. The fastest port was to use the existing PL/M logic including 0xff for TRUE. Is your "answer" to a question that wasn't asked more plausible? Yes, history is boring but knowledge of it is a real speculation-killer. – Olof Forshell Oct 27 '12 at 17:20

What's really important to know about this question is the type of "var". You say "boolean", but is that a C++/C99's bool, or is it (highly likely, being an embedded C app), something of a completely different type that's being used as a boolean?

  • Best answer apart from mine, without unfounded speculation :) – Olof Forshell Oct 27 '12 at 6:22

Also adding 1 to 0xff sets it to 0( assuming unsigned char) and the checking might have been in a loop with an increment to break.


Here's a likely reason: 0xff is the binary complement of 0. It may be that on your embedded architecture, storing 0xff into a variable is more efficient than storing, say, 1 which might require extra instructions or a constant stored in memory.

Or perhaps the most efficient way to check the "truth value" of a register in your architecture is with a "check bit set" instruction. With 0xff as the TRUE value, it doesn't matter which bit gets checked... they're all set.

The above is just speculation, of course, without knowing what kind of embedded processor you're using. 8-bit, 16-bit, 32-bit? PIC, AVR, ARM, x86???

(As others have pointed out, any integer value other than zero is considered TRUE for the purposes of boolean expressions in C.)

  • it's an 8051 chip – Dan Oct 13 '08 at 21:10
  • Well, there's nothing in the 8051 instruction set that would make it easier to set a register to 0xFF as opposed to 1. I'm stumped, maybe it's just the idiosyncratic habit of this particular coder, maybe it's an undocumented hack for some bit-manipulation trick used elsewhere, ...? – Dan Lenski Oct 13 '08 at 22:05
  • I'm inclined to believe it's the coder and not the hardware. I found out that this was his first embedded system, and he was let go for poor work. – Dan Oct 14 '08 at 16:16
  • Likely reason? Hardly. See my answer. – Olof Forshell Oct 26 '12 at 18:29

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