## SETUP

I'm going to refer to this image I found on a thread on reddit:

So the pins correspond to the segments as follows:

**A**: 11

**B**: 12

**C**: 13

**D**: 15

**E**: 16

**F**: 18

**G**: 22

Now let's see what happens when we call `writeOneByte`

with the first value in the list named `dats`

, i.e **0x3f**.

The first line in the function is

```
GPIO.output(11, val & (0x01 << 0))
```

`val`

holds the value **0x3f** which is what was passed into the function. This value is equivalent to **0b00111111** in binary. Looking again at the diagram, we see that the letters **A**-**G** actually correspond to each bit, from the least significant (right most bit) to the second most significant bit. The most significant bit is reserved for the dot.

## BITWISE OPERATIONS

The `<<`

is the left-shift operator. The code `0x01 << 0`

means shift the number **0x01** *zero* bits to the left. Therefore, the operation leaves the number unchanged, and the result is still **0x01**, which is equivalent to **0b00000001**.

Next up is `&`

, the bitwise `AND`

operator. This performs a logical `AND`

operation on a bit-by-bit basis. It's easy to see in an example:

```
0b00111111
0b00000001
----------
0b00000001
```

Essentially what we are doing is checking the first (least significant) bit of the number in `val`

and checking to see whether the corresponding pin should have a `HIGH`

or a `LOW`

output. In this case, the value of the first bit is 1. After the `AND`

operation, the value passed to `GPIO.output`

for pin 11 (which corresponds to segment **A**), is **0b00000001**. This outputs a `HIGH`

value, because anything that is not all zeroes translates into a boolean true.

The process is repeated on the remaining lines of code:

```
GPIO.output(12, val & (0x01 << 1))
```

This time **0b00000001** is shifted 1 bit to the left, yielding **0b00000010**. We perform the bitwise `AND`

again:

```
0b00111111
0b00000010
----------
0b00000010
```

which is also a `HIGH`

output for pin 12, and thus segment B is on.

In fact, the only time we get a `LOW`

is with pin 7, in the last line:

```
GPIO.output(7, val & (0x01 << 7))
0b00111111
0b01000000
----------
0b00000000
```

As you can see in the diagram, the bits that drive the pins take on the appropriate values to yield the number `0`

in the given display arrangement.