Believe it or not, the issue is actually in your testbench. This has to do with how the VHDL simulation model works.
VHDL is usually used for synchronous hardware design -- that means, using flip-flops that sample on the rising edge and set outputs on the falling edge, so that there are no race conditions between reading and writing. But in VHDL this master/slave logic is not actually simulated using opposite clock edges.
Consider a process
process (clock) begin
if rising_edge(clock) then
a <= b;
At the start of a simulation timestep, if
clock has just risen, the
if will execute. Then the assignment
a <= b will be executed, and this will not immediately cause an assignment to take place, but schedule the assignment for the end of the timestep.
After all processes have been run, then all scheduled assignments take place. This means that no process will "see" the new value of
a until the next timestep.
Time a b Actions
Start of ts 1 '0' '1' a <= '1' is scheduled
End of ts 1 '1' '0' a <= '1' is executed
Start of ts 2 '1' '0' a <= '0' is scheduled
End of ts 2 '0' '1' a <= '0' is executed
So when you look on the waveform viewer, what you will see is
a apparently being set on the rising edge of the clock, and following
b delayed by one clock cycle; you don't see the intermediate scheduling of assignments that causes this to happen.
Of course, in real life, there is no "end of the timestep", and the actual changing of signal
a happens when the slave part of the flip-flop triggers, ie, on the negative edge. (Maybe it would have been less confusing for VHDL to just use the negative edge; but, oh well, this is how it works).
Here are two testbenches for your latch code:
In the first, if you look in the waveform viewer you will see exactly what you describe --
lwe appears to be delayed by 1 clock cycle -- but really, the delay is happening in the non-blocking assignment that sets
counter -- so when the rising edge happens,
we does not actually have its new value yet. And in the second, you see no such delay;
lwe is set exactly on the rising edge to the value of
we at that time.
For a related topic in Verilog, see Nonblocking Assignments in Verilog Synthesis, Coding Styles That Kill .