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I see u8 u16 u32 u64 data types being used in kernel code. And I am wondering why is there need to use u8 or u16 or u32 or u64 and not unsigned int?

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    Because that will only map to one of your list. And you can't be sure which one.
    – Jongware
    Jun 17, 2015 at 15:51
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    I've mostly seen the standard typedefs uint8_t, uint16_t, et al. Jun 17, 2015 at 15:54
  • I have linux/types.h include
    – user966588
    Jun 17, 2015 at 15:56
  • what is the shorthand of signed 32?
    – Gábor
    Mar 19, 2022 at 13:20

3 Answers 3

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Often when working close to the hardware or when trying to control the size/format of a data structure you need to have precise control of the size of your integers.

As for u8 vs uint8_t, this is simply because Linux predated <stdint.h> being available in C, which is technically a C99-ism, but in my experience is available on most modern compilers even in their ANSI-C / C89 modes.

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    And u8 involves less typing :-)
    – TripeHound
    Jun 17, 2015 at 16:13
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    True... but it gets super annoying when you need to mix & match libraries and everyone tries to define their own known-wdith types so. You'll have U8, u8, uint8, BYTE, UINT8 and unt8_t all in the same file. You can even have potential conflicts that ends up generating warnings. Most commonly with the 32 and 64-bit types which may have multiple valid ways to typedef them on a given platform. For new code, please, please, please just stick with stdint.h types :). Jun 17, 2015 at 16:19
  • I am using u8 u16 etc in kernel space with linux/types.h. Is stdint.h for user space?
    – user966588
    Jun 17, 2015 at 17:09
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    You can use the standard names (uint8_t, etc) in kernel mode too. Typedefs for those are in linux/types.h as well. Jun 17, 2015 at 17:28
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    @BrianMcFarland as long as u8 etc are your own typedefs that you can guarantee are identical to the standard ones, you'll be fine though. As Gil Hamilton said, the kernel does this
    – o11c
    Jun 17, 2015 at 18:50
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Share what I learned about this question recently.

The reason why we need such explicitly sized type, such as u32, is that the normal C data types are not the same size on all architectures.

The following image shows that long integers and pointers feature a different size on various platforms.

enter image description here

In this way, u32 can guarantee that you get 4 bytes long integer.

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Adding my 10 cents to this answer:

u64 means an 'unsigned 64 bits' value, so, depending on the architecture where the code will run/be compiled, it must be defined differently in order to really be 64 bits long.

For instance, on a x86 machine, an unsigned long is 64 bits long, so u64 for that machine could be defined as follows:

typedef unsigned long u64;

The same applies for u32. On a x86 machine, unsigned int is 32 bits long, so u32 for that machine could be defined as follows:

typedef unsigned int u32;

You'll generally find the typedef declaration for these types on a types.h file which corresponds to the architecture you're compiling your source to.

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