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I have a 16 bit variable data, ie:

volatile uint16_t data;

I need to populate this value based on the contents of two 8 bit registers on an external sensor. These are accessed over I2C/TWI.

My TWI routine is async*, and has the signature:

bool twi_read_register(uint8_t sla, uint8_t reg, uint8_t *data, void (*callback)(void));

This reads the value of reg on sla into *data, then calls callback().

If I knew the uint16_t was arranged in memory as, say, MSB LSB, then I could do:

twi_read_register(SLA, REG_MSB, (uint8_t *)&data, NULL);
twi_read_register(SLA, REG_LSB, (uint8_t *)&data + 1, NULL);

However, I don't like baking endian dependence into my code. Is there a way to achieve this in an endian-independent way?

(side note: my actual workaround at the moment involves using a struct, ie:

typedef struct {
    uint8_t msb;
    uint8_t lsb;
} SensorReading;

but I'm curious if I could do it with a simple uint16_t)


(* by async I mean split-phase, ie *data will be set at some point in the future, at which point the callee will be notifed via the callback function if requested)

share|improve this question
Why do you want to constrain yourself to pointer access to the 16 bit value? Most would do this with shift and add or or operators. However if you really want to do it with pointers, you could use macros which detect and compensate for the endian-ness. – Chris Stratton Apr 15 '13 at 14:27
No you cant...reliably. Use a mask and shift if you want reliable and portable code. – dwelch Apr 15 '13 at 20:09
actually the mask and shift doesnt work either, does it? – dwelch Apr 15 '13 at 20:10
@ChrisStratton - Masking and shifting simply doesn't work with split-phase calls, hence the question. It's no good masking and shifting after the calls to read, when the read function hasn't actually set the value yet. – sapi Apr 15 '13 at 21:54
Read into temporary values, then combine by masking & shift when you are notified the read is done. Even with pointers, you can't use the value between the time when you request the read and when you are notified that both are done, since you could have inconsistent high and low bytes if you catch it partway done. – Chris Stratton Apr 15 '13 at 22:09
up vote 4 down vote accepted

Would the following not work?

uint8_t v1, v2;
twi_read_register(SLA, REG_MSB, &v1, NULL);
twi_read_register(SLA, REG_LSB, &v2, NULL);
data = ((uint16_t)v1<<8)|v2;

Or is data so volatile that the twi_read_register needs to write it. In that case I think you're stuck with endian dependent code.

As you pointed out below the data is indeed that volatile, because yet another device is reading it. So a memory mapped connection is established between two devices that may differ in endianness. This means you are stuck with endian dependent code.

You mention the struct as a workaround, but that is kind of a standard way of dealing with this.

typedef struct
{       uint8_t  msb, lsb;
} uint16_as_uint8_t;
typedef struct
{       uint8_t  lsb, msb;
} uint16_as_uint8_t;

On top of that you could put a union

{       uint16_as_uint8_t  as8;
        uint16_t           as16;

Note that the latter is in violation of the C89 standard as it is your clear intention to write one field of the union and read from another, which results in an unspecified value. From off C99 this is (fortunately) supported. In C89 one would use pointer conversions through (char*) to do this in a portable way.

Note that the above may to seem hide the endianness in a portable way, structure packing may also differ from target to target and it might still break on some target. For the above example this is unlikely, but there are some bizarre targets around. What I'm trying to say is that it is probably not possible to program portable on this device level and it might be better to accept that and strive to hide all the details in a compact target interface, so changing one header file for the target would be enough to support it. The remainder of the code then can look target independent.

share|improve this answer
Not sure why you're mentioning volatile, though. – Alexey Frunze Apr 15 '13 at 1:05
twi_read_register is asynchronous / split-phase, so v1 and v2 in your example won't be set until an indeterminate time in the future. data will have an undefined value. – sapi Apr 15 '13 at 1:06
I see. Then maybe you could do the combining into uint16_t once you know the values are ready. – Bryan Olivier Apr 15 '13 at 1:14
@AlexeyFrunze If data is really owned by some other device and it is out of control of the application when data is read, then we really need to pass its address to the twi device and we're stuck with endian dependent code. – Bryan Olivier Apr 15 '13 at 1:19
It's out of the application control, yes. I was wondering if there was some way to do it independent of endianness (I actually know the endianness of the target system, and it won't change, but I don't like writing code that depends on it, hence the struct workaround atm). – sapi Apr 15 '13 at 4:28

How about something like this?

uint16_t myValue = ...;
uint8_t LSB = (uint8_t)(myValue % 256);
uint8_t MSB = (uint8_t)(myValue / 256);
share|improve this answer
This is a common approach, though my reading of the question is that it poses the problem in the other direction, populating a 16-bit value from two 8-bit ones. – Chris Stratton Apr 15 '13 at 14:28
I don't see any difficulty with "myValue = MSB * 256 + LSB;" – Alexandre Vinçon Apr 16 '13 at 13:54
  volatile uint16_t data;  
  uint16_t v = 1;
  twi_read_register(SLA, REG_MSB, (uint8_t *)&data + *((uint8_t *)&v), NULL);
  twi_read_register(SLA, REG_LSB, (uint8_t *)&data + *((uint8_t *)&v + 1), NULL);
share|improve this answer

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