# Understand the following line

I read this code in a library which is used to display a bitmap (.bmp) to an LCD.
I do really hard in understanding what is happening at the following lines, and how it does happen.

Maybe someone can explain this to me.

``````uint16_t s, w, h;
uint8_t* buffer;   // does get malloc'd

s = *((uint16_t*)&buffer[0]);
w = *((uint16_t*)&buffer[18]);
h = *((uint16_t*)&buffer[22]);
``````

I guess it's not that hard for a real C programmer, but I am still learning, so I thought I just ask :)
As far as I understand this, it sticks somehow together two `uint8_t`variables to an `uint16_t`.

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In the code you've provided, `buffer` (which is an array of bytes) is read, and values are extracted into `s`, `w` and `h`.

The `(uint16_t*)&buffer[n]` syntax means that you're extracting the address of the nth byte of `buffer`, and casting it into a `uint16_t*`. The casting tells the compiler to look at this address as if points at a `uint16_t`, i.e. a pair of `uint8_t`s.
The additional `*` in the code dereferences the pointer, i.e. extracts the value from this address. Since the address now points at a `uint16_t`, a `uint16_t` value is extracted.

As a result:

1. `s` gets the value of the first `uint16_t`, i.e. bytes 0 and 1.
2. `w` gets the value of the tenth `uint16_t`, i.e. bytes 18 and 19.
3. `h` gets the value of the twelveth `uint16_t`, i.e. bytes 22 and 23.
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so if buffer[0] = 4; and buffer[1] = 2; s would be in this case 516? –  Tectu Jun 16 '12 at 12:13
That depends on which byte is treated as MSB. If the 0-th byte is MSB, then your number is 0x0402=1026. If the 1-st byte is MSB, then it is 0x0204=516. –  Eitan T Jun 16 '12 at 12:18
516 or 1026, depending of endianness of processor... –  Oleg Trakhman Jun 16 '12 at 12:20
thanks for your help, guys :) –  Tectu Jun 16 '12 at 12:21

The code:

• takes two bytes at positions 0 and 1 in the buffer, sticks them together into an unsigned 16-bit value, and stores the result in `s`;
• it does the same with bytes 18/19, storing the result in `w`;
• ditto for bytes 22/23 and `h`.

It is worth noting that the code uses the native endianness of the target platform to decide which of the two bytes represents the top 8 bits of the result, and which represents the bottom 8 bits.

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``````uint8_t* buffer; // pointer to 8 bit or simply one byte
``````

Buffer points to memory address of bytes -> |byte0|byte1|byte2|....

``````(uint16_t*)&buffer[0] // &buffer[0] is actually the same as buffer
``````

`(uint16_t*)&buffer[0]` equals `(uint16_t*)buffer`; it points to 16 bit or halfword

`(uint16_t*)buffer` points to memory: |byte0byte1 = halfword0|byte2byte3 = halfword1|....

``````w = *((uint16_t*)&buffer[18]);
``````

Takes memory address to byte 18 in buffer, then reinterpret this address to address of halfword then gets halfword on this address; it's simply w = byte18 and byte19 sticked together forming a halfword

``````h = *((uint16_t*)&buffer[22]);
``````

h = byte22 and byte 23 sticked together

UPD More detailed explanation:

`h = *((uint16_t*)&buffer[22])` =>

1) `buffer[22]` === 22nd uint8_t (a.k.a. byte) of buffer; let's call it byte22

2) `&buffer[22]` === &byte === address of byte22 in memory; it's of type uint8_t*, as same as buffer; letscall it byte22_address;

3) `(uint16_t*)&buffer[22]` = (uint16_t*)byte22_address; casts address of byte to address of (two bytes sticked together; address of halfword of the same address; let's call it halfword11_address;

4) `h = *((uint16_t*)&buffer[22])` === *halfword11_address; * operator takes value at address, that is 11th halfword or bytes 22 and 23 sticked together;

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