Essentially, my question is: "can this not be done any easier?"; and what 'this' is, follows below (code too):
I wanted to have a sort of a 'complement' counter function, implemented in VHDL, which would basically invert/complement/not the counter value in each step, giving slightly richer bit patterns for testing. Of course, I wanted this as synthesizable (so the counter value could be possibly assigned to pins) and portable code (i.e. implemented only IEEE libraries, no
STD_LOGIC_ARITH). I also don't want to by default treat all as unsigned (so I'd like to avoid
In brief, this counter could be described as: given initial value C, then values at each clock tick would be:
C[i+1] = not(C[i]) + ( ( C[i]<(Cmax/2) ) ? 0 : 1 )
... or given C is 16-bit wide (which will result with unsigned Cmax = 65535 and Cmax/2 = 32768), it could also be written as:
C[i+1] = 65535 - C[i] + ( ( C[i]<32768 ) ? 0 : 1 )
The trick here is that the counter should only increment once - if it increases for both complementary and 'normal' ranges, then no changes will happen (equation will 'oscillate' between two values).
So, given that the check C[i]<(Cmax/2) is basically the same as checking the most significant (15th) bit of C, I thought that I could easily implement something like this in VHDL using something like:
Y <= not(Y) + Y(15);
Boy, was I wrong about "easily" :)
First problem is that it is possible the above equation could end up at 65535+1, in which case the result will need 17 bits (i.e. overflow); in my case, I'd simply want to truncate/ignore any 'carry bits'.
This leads into the problem of what to use:
not()defined; but it doesn't have
integermay internally take up 32 bits, and as such bit width for them is not necesarilly specified; they support arithmetic
+, but no complement
- I tried
unsignedtoo, had some problems also (cannot remember which)
The 15th (MSB) bit can only be extracted when Y is
std_logic_vector, in which case, Y(15) is a single
std_logic - but then, it needs to be converted to
integer type, because otherwise addition
+ is not defined :|
So, my current solution (below) first has two copies of the counter register; one is
SIGNAL wCntReg : STD_LOGIC_VECTOR(15 DOWNTO 0); the other is
SIGNAL tmp_na : natural. Then:
- There are two clocks: one 'master' @ 50 MHz, the other is the 'counter' clock: the master 16-times frequency divided (3.125 MHz).
- The 'counter' clock should activate calculation of counter values on falling edge
- The calculation is performed via
naturalvariable (which copies from the
std_logiccan only be converted to
integerif its converted to
std_logic_vectorfirst (I was lucky to find the
vectorizefunction on the net).
The nastiest part here was how to feed back the
natural variable value, back to the
STD_LOGIC_VECTOR one; the only working command I could construct is:
wCntReg <= std_logic_vector(to_unsigned(natural'pos(tmp_na), wCntReg'length));
...; however, note that this command basically 'sets' the value, which will be 'effectuated' next time this same command runs. Thus, it cannot run in the 'counter' clock process - in the code below, I have it in the faster 'master' clock process.
Finally, the code below does work (goes through behavioral simulation in ISE WebPack) - but, I'd still like to know if there is a more straightforward way to solve this.
Thanks in advance for any answers, Cheers!
---------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.ALL; -- use IEEE.STD_LOGIC_ARITH.ALL; -- use IEEE.STD_LOGIC_UNSIGNED.ALL; use IEEE.NUMERIC_STD.ALL; ENTITY complement_count_test_tbw IS END complement_count_test_tbw; ARCHITECTURE testbench_arch OF complement_count_test_tbw IS -- http://www.ingenieurbuero-eschemann.de/downloads/ipicregs/example/vhdl/test/timer_regs_tb.vhd -- convert std_logic to std_logic_vector(0 downto 0) function vectorize(s: std_logic) return std_logic_vector is variable v: std_logic_vector(0 downto 0); begin v(0) := s; return v; end; -- DECLARE REGISTERS ========================== -- 'wires' SIGNAL wtCLK : std_logic := '0'; -- counter register: 16 bit SIGNAL wCntReg : STD_LOGIC_VECTOR(15 DOWNTO 0) := (others => 'Z'); -- temporary 'natural' copy of counter register -- http://www.velocityreviews.com/forums/t21700-std_logic_vector-to-unsigned-type-casting.html SIGNAL tmp_na : natural; -- clock parameters constant PERIODN : natural := 20; -- can be real := 20.0; constant PERIOD : time := PERIODN * 1 ns; constant DUTY_CYCLE : real := 0.5; constant OFFSET : time := 100 ns; -- freq divisor; with initial values constant fdiv : natural := 16; SIGNAL fdiv_cnt : natural := 1; SIGNAL wfdiv_CLK : std_logic := '0'; BEGIN -- initializations of connections: -- instances of components, and their wiring (port maps)... -- END instances of components, and their wiring (port maps)... -- PROCESSES (STATE MACHINES) CODE ========= -- clock process for generating CLK PROCESS BEGIN WAIT for OFFSET; CLOCK_LOOP : LOOP wtCLK <= '0'; -- MUST refresh counter reg here with value of tmp_na wCntReg <= std_logic_vector(to_unsigned(natural'pos(tmp_na), wCntReg'length)); WAIT FOR (PERIOD - (PERIOD * DUTY_CYCLE)); wtCLK <= '1'; WAIT FOR (PERIOD * DUTY_CYCLE); END LOOP CLOCK_LOOP; END PROCESS; -- freq divided clock freq_divisor: PROCESS(wtCLK) BEGIN IF rising_edge(wtCLK) THEN -- posedge IF fdiv_cnt = fdiv THEN -- reset fdiv_cnt <= 1 ; wfdiv_CLK <= not(wfdiv_CLK); ELSE fdiv_cnt <= fdiv_cnt + 1; END IF; END IF; END PROCESS freq_divisor; -- sim: count PROCESS BEGIN WAIT for 10 ns; tmp_na <= 125; WAIT for 10 ns; TESTCOUNT_LOOP: LOOP -- change counter on negedge of freq. divided clock WAIT until falling_edge(wfdiv_CLK); tmp_na <= to_integer(unsigned(not(wCntReg))) + to_integer(unsigned(vectorize(wCntReg(15)))); WAIT for 10 ns; END LOOP TESTCOUNT_LOOP; END PROCESS; -- END PROCESSES (STATE MACHINES) CODE ===== -- END IMPLEMENT ENGINE of 'CORE' =============== END testbench_arch; -- END ARCHITECTURE -----------------------------