# Bit Shifting, Masking or a Bit Field Struct?

I'm new to working with bits. I'm trying to work with an existing protocol, which can send three different types of messages.

Type 1 is a 16-bit structure:

``````struct digital
{
unsigned int type:2;
unsigned int highlow:1;
unsigned int sig1:5;
unsigned int :1;
unsigned int sig2:7;
};
``````

The first two bits (type, in my struct above) are always 1 0 . The third bit, highlow, determines whether the signal is on or off, and sig1 + sig2 together define the 12-bit index of the signal. This index is split across the two bytes by a 0, which is always in bit 7.

Type 2 is a 32-bit structure. It has a 2-bit type, a 10-bit index and a 16-bit value, interspersed with 0's at positions 27, 23, 15 & 7. A bit-field struct representation would like something like this:

``````struct analog
{
unsigned int type:2;
unsigned int val1:2;
unsigned int :1;
unsigned int sig1:3;
unsigned int :1;
unsigned int sig2:7;
unsigned int :1;
unsigned int val2:7;
unsigned int :1;
unsigned int val3:7;
};
``````

sig1 & sig2 together form the 10-bit index. val1 + val2 + val3 together form the 16-bit value of the signal at the 10-bit index.

If I understand how to work with the first two structs, I think I can figure out the third.

My question is, is there a way to assign a single value and have the program work out the bits that need to go into val1, val2 and val3?

I've read about bit shifting, bit-field structs and padding with 0's. The struct seems like the way to go, but I'm not sure how to implement it. None of the examples of bit-packing that I've seen have values that are split the way these are. Ultimately, I'd like to be able to create an analog struct, assign an index (i = 252) and a value (v = 32768) and be done with it.

If someone could suggest the appropriate method or provide a link to a similar sample, I'd greatly appreciate it. If it matters, this code will be incorporated into a larger Objective-C app.

Thanks.

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I'm not sure I get you.. when you say "val1 + val2 + val3 together" do you mean concatenation or plain addition? If it's concatenation, is your question simply about how to insert zeros at the appropriate places given the concatenated version? –  int3 Nov 25 '09 at 14:52
It's concatenation. Value is a 16-bit value, the bits of which need to be split over three "segments". So, val1 holds the 3 most significant bits of Value, followed by the 7 bits of val2, and then the 7 least significant bits of val3. So, the question is sort of about inserting 0's at the proper location, but, the signal index (which is non-0) also needs to be inserted in the middle of the Value, in the case of the Analog struct. Thanks. –  Brad Nov 25 '09 at 15:05

You shouldn't use C structure bitfields because the physical layout of bitfields is undefined. While you could figure out what your compiler is doing and get your layout to match the underlying data, the code may not work if you switch to a different compiler or even update your compiler.

I know it's a pain, but do the bit manipulation yourself.

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There are cases where using a bitfield to parse a message is perfectly reasonable. For instance in embedded apps where the program is tied closely to the DSP chip's capabilities, there is no reason to worry about portability, since an platform change would break everything. Figuring out how the compiler handles bitfields, and taking advantage of it allows you to write much cleaner code. –  AShelly Dec 3 '09 at 19:44
Maybe I'm missing something, but adding `__attribute__((packed));` after the closing brace on the struct should preserve ordering and size preventing the compiler from messing with your struct. –  Warpling Dec 7 '11 at 0:18

You don't have to do this, this is where the union keyword comes in - you can specify all the bits out at the same time, or by referring to the same bits with a different name, set them all at once.

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A union won't magically allow you to put zeros in your bit patterns.. –  int3 Nov 25 '09 at 18:08

You can do it with a series of shifts, `and`s, and `or`s. I have done the 10-bit index part for Type 2:

``````unsigned int i = 252;

analog a = (analog)(((i << 16) & 0x7f0000) | (i << 17) & 0x7000000);
``````

Essentially, what this code does is shift the 10 bits of interest in `int i` to the range 16 - 25, then it `and`s it with the bitmask `0x7f0000` to set bits 22 - 31 to zero. It also shifts another copy of the 10 bits to the range 17 - 26, then it `and`s it with the bitmask `0x7000000` to set bits 0 - 22 and 26 - 31 to zero. Then it `or`s the two values together to create your desired zero-separated value.

.. I'm not absolutely sure that I counted the bitmasks correctly, but I hope you've got the idea. Just shift, and-mask, and or-merge.

Edit: Method 2:

``````analog a;
a.sig1 = (i & 0x7f); // mask out bit 8 onwards
a.sig2 = ((i<<1) & 0x700); // shift left by one, then mask out bits 0-8
``````

On second thought method 2 is more readable, so you should probably use this.

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