What's the point of negative ASCII values?
int a = '«'; //a = -85 but as in ASCII table '<<' should be 174
asked Jan 14, 2011 at 11:11
6 Answers
There are no negative ASCII values. ASCII includes definitions for 128 characters. Their indexes are all positive (or zero!).
You're seeing this negative value because the character is from an Extended ASCII set and is too large to fit into the char literal. The value therefore overflows into the bit of your char (signed on your system, apparently) that defines negativeness.
The workaround is to write the value directly:
unsigned char a = 0xAE; // «
I've written it in hexadecimal notation for convention and because I think it looks prettier than 174. :)
answered Jan 14, 2011 at 11:17
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2@R Of course there is. It's a somewhat-colloquial term describing a few standards, but they all share the properties that are relevant in this question and this answer. en.wikipedia.org/wiki/Extended_ASCII Jan 14, 2011 at 17:27
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1Someone should delete the wiki entry. The values associated with 'EXTENDED ASCII' as you call it, vary by platform. Hence they are not standard. Look up the phrase 'CHARACTER SET', and observe that some platforms include ASCII in their character set. Jan 15, 2011 at 2:43
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1@EvilTeach: Luckily, that's exactly what the Wikipedia page says. "The term extended ASCII (or high ASCII) describes eight-bit or larger character encodings that include the standard seven-bit ASCII characters as well as others. The use of the term is sometimes criticized, because it can be mistakenly interpreted that the ASCII standard has been updated to include more than 128 characters or that the term unambiguously identifies a single encoding, both of which are untrue." Nov 12, 2012 at 21:10
This is an artefact of your compiler's char type being a signed integer type, and int being a wider signed integer type, and thus the character constant is considered a negative number and is sign-extended to the wider integer type.
There is not much sense in it, it just happens. The C standard allows for compiler implementations to choose whether they consider char to be signed or unsigned. Some compilers even have compile time switches to change the default. If you want to make sure about the signedness of the char type, explicitly write signed char or unsigned char, respectively.
Use an unsigned char to be extended to an int to avoid the negative int value, or open a whole new Pandora's box and enjoy wchar.
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2No, it's because the character does not fit in the literal. The problem occurs before the
inteven comes into the picture. The literal ends up with the value -85 due to overflow, and then this value -85 is assigned to the int. (It's possible that this is what you meant, and I misunderstood you.) Jan 14, 2011 at 11:42 -
@Tomalak: it is just semantics whether unsigned 174 just happens to be signed -85 or whether there was an overflow. For me overflowing has more to do with calculations. In the end, the result is the same.– stefaanvJan 14, 2011 at 12:02
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@stefaanv: That's fine; it's not what I was contesting. Jan 14, 2011 at 12:06
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4"the character does not fit in the literal". That really makes no sense. Any narrow character fits into a
char. To make it not fit, you need multiple characters (int a = 'ab'; /* !! */). C does not require that characters have positive values. Hence, implementations are free to assign the value -85 to '«'– MSaltersJan 14, 2011 at 12:52
There is no such thing. ASCII is a table of characters, each character has an index, or a position, in the table. There are no "negative" indices.
Some compilers, though, consider char to be a signed integral data type, which is probably the reason for the confusion here.
If you print it as unsigned int, you will get the same bits interpreted as a unsigned (positive) value.
ASCII ranges 0..127, ANSI (also called 'extended ASCII') ranges 0..255.
ANSI range won't fit in a signed char (the default type for characters in most compilers).
Most compilers have an option like 'char' Type is Unsigned (GCC).
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3Signed char is not "the default type for characters" at all. The signedness of an unqualified
chartype is completely implementation-specified. Character literals have typechar. His system just happens to use a signed implementation forchar(as do the majority of popular systems, I believe). Jan 14, 2011 at 11:40 -
(This is contrary to
int, which is explicitly, always, the same assigned int.) Jan 14, 2011 at 11:40 -
I will clarify this. I meant 'default in most compilers', not specification.– jv42Jan 14, 2011 at 12:11
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1Fun fact: Regardless of your implementations signedness of
char,charis a different type from bothsigned charandunsigned char.– etarionJan 14, 2011 at 12:21 -
@jv42: OK, then that is largely correct.
charon most implementations that you find on popular commodity hardware nowadays is a signed type. Jan 14, 2011 at 17:29
I had this artifact. When you use char as symbols you have no problem. But when you use it as integer (with isalpha(), etc.) and the ASCII code is greater then 127, then the 'char' interpret as 'signed char' and isalpha() return an exception. When I need use the 'char' as integer I cast the 'char' to unsigned:
- isalpha((unsigned char)my_char);
@n0rd: koi8 codepage uses ascii from 128 to 255 and other national codepages: http://www.asciitable.com/
In a character representation, you have 8 bits (1 byte) allotted.
Out of this, the first bit is used to represent sign. In the case of unsigned character, it uses all 8 bits to represent a number allowing 0 to 255 where
128-255 are called extended ASCII.
Due to the representation in the memory as I have described, we have -1 having the same value as 255, char(-2)==char(254)
a = -85is incorrect. It should bea = -82. This is because the range of the extended ASCII table is 0 - 255 inclusive. That's a total of 256 possible values. For both a positive value and a negative value to be the same symbol (in this case<<) they have to be 256 values apart for the symbol to repeat itself.