I'm using LIS3DH as well, and after a few hours of reading and trying, I've finally figured it out. Though my code is for AVR microcontroller, the method is still the same.

The accelerometer presents its readings as a *left-justified* 16-bit values, divided to 2-byte registers for each axis: `OUT_X_L`

, `OUT_X_H`

, `OUT_Y_L`

, `OUT_Y_H`

, `OUT_Z_L`

, `OUT_Z_H`

. Left justification means: *all value bits are shifted to the left*. How many bits? That depends on your precision.

Suppose you use a 10-bit precision (the default), and you want to read X-axis value, then your `OUT_X_H`

and `OUT_X_L`

registers will look like this:

```
╔═════════╦═══════════╦═══════════╗
║ ║ OUT_X_H ║ OUT_X_L ║
╠═════════╬═══════════╬═══════════╣
║ Content ║ xxxx xxxx ║ xx00 0000 ║
╚═════════╩═══════════╩═══════════╝
```

x - is the value you want, and 0 is just a zero. Since the precision is 10-bit, the 6 less significant bits will always be zero-ed.

Why the heck someone would want to send data like that? The reason is simple - if you don't care about a precision, you can read only the high register and store it as an 8-bit integer (`int8_t`

). Thanks to the left-justification, more most significant bits are preserved and you lose only 2 bits from the low register. On the other hand, right-justification is easier to operate on, but you lose a lot of information if you don't read a whole 16-bit value.

Now, if you want to convert this value to a "normal" one (right-justified), you need to store it as a 16-bit integer (`int16_t`

). Computers hold signed integers as two's complement, so does LIS3DH, that means the value stored in this `int16_t`

variable will have a proper sign. The last operation you have to do, is to shift this value right by 6 (for 10-bit precision), and *voila*!

I've written two methods of conversion, one is based on a typical bit operations and the second is a pointer-casting suicide.

### Bit operations

```
int16_t x = out_x_h; // 1.
x <<= 8; // 1.
x |= out_x_l; // 2.
x >>= 6; // 3.
int16_t y = out_y_h;
y <<= 8;
y |= out_y_l;
y >>= 6;
int16_t z = out_z_h;
z <<= 8;
z |= out_z_l;
z >>= 6;
```

For each axis:

- Store a high register in the upper part of the 16-bit variable.
- Append a lower register. Now your variable contains a left-justified value.
- Shift whole variable by 6 to the right.

### Pointer-casting suicide

```
uint8_t x_a[2] = {out_x_l, out_x_h}; // 1.
int16_t x = (*(int16_t*) x_a) >> 6; // 2.
uint8_t y_a[2] = {out_y_l, out_y_h};
int16_t y = (*(int16_t*) y_a) >> 6;
uint8_t z_a[2] = {out_z_l, out_z_h};
int16_t z = (*(int16_t*) z_a) >> 6;
```

For each axis:

- Store registers in an array of bytes.
**Order of elements is valid only for little-endian architecture. For big-endian the high register should be first.**
- Cast
`uint8_t`

pointer to `int16_t`

pointer, so the pointer to the byte array is seen as a pointer to the one 16-bit integer, dereference it, and shift right by 6.