It is not "executed" sequentially as such - but the synthesizer interprets the code sequentially, and creates the hardware design to fit such an interpretation.
For instance, if you assign a value to a
signal twice during a clocked process, the first assignment is simply ignored, while the second takes effect (remember that a
signal is only assigned at the end of a
process statement, not immediately):
signal a : UNSIGNED(3 downto 0) := (others => '0');
a <= a - 1;
a <= a + 1;
The above process will always increment
a by 1. Similarly, if you have the second assignment inside an
if statement, the synthesizer will simply create two paths for
a - a decrement for when the
if statement is not fullfilled, and an increment for when it is.
If you use variables, the idea is the same - although intermediate values are used, as variables take on their new value immediately.
But it all boils down to that the synthesizer does all the "magic" of interpreting your
process in a sequential way, then generating hardware that does what you have described.
Your example basically describes a d-flip-flop (the Xilinx FPGA tools iirc distinguish latches and flip-flops in that flip-flops are edge-sensitive, and latches are level-sensitive), although in a different way than typically recommended.
You can basically write the same code as:
q <= d;
It will automatically keep its value in the other cases. This will be implemented as a flip-flop inside the FPGA. Most FPGAs consist of blocks of look-up tables and flip-flops, to which quite a lot of different hardware can be mapped. The above code will simply by-pass the look-up table, and just use the flip-flop of one of the blocks.
You can learn more about the internal workings by having a look at the datasheet for your particular FPGA. For Spartan3-series FPGAs for instance, have a look at page 24 of the Xilinx Spartan3 FPGA Family Data Sheet