# Behavioral to Structural Conversion Problems VHDL

I designed a primality testing for Rabin Miller algorithm in behavioral type. I used functions to create my modules. Unfortunately, when I tried to synthesize it by my Altera Kit via Quartus, I realized that function are not synthesize. Here I will write my whole program, and I really need you help to give me at least some hints to change it to structural as it is my senior design project. Here is my program:

`````` library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;

entity PrimeTest is
port( N: in integer;
Test1 : out std_logic);
end PrimeTest;

Architecture Behavior1 of PrimeTest is

function integer_binary (b1:std_logic_vector(31 downto 0)) return integer is
variable a: integer:=0;
variable i: integer;
begin
i:=0;

while (i<32) loop
if b1(i) = '1' then
a:=a+2**i;
end if;
i:=i+1;
end loop;
return a;
end integer_binary;

function integer_binary1 (b1:std_logic) return integer is
variable a: integer;

begin
if b1 = '1' then
a:= 1;
else
a:=0;
end if;
return a;
end integer_binary1;

function binary1 (int1:integer) return std_logic_vector is
variable int2: integer;
variable a:std_logic_vector(31 downto 0);
variable i: integer;

begin
int2:=int1;
i:=0;
while (i<32) loop
if (int2 mod 2 = 0) then
a(i):='0';
else
a(i):='1';
end if;
i:=i+1;
int2:=int2/2;
end loop;
return a;
end binary1;

function mul_mod (x1,y1,m1: std_logic_vector (31 downto 0)) return std_logic_vector is
variable p1: std_logic_vector (31 downto 0);
variable k: integer;
variable n: integer;
variable i: integer;
variable j: std_logic_vector (31 downto 0);
begin
n:=32;
i:=31;
p1:="00000000000000000000000000000000";
while(i>=0) loop

p1:=binary1((integer_binary(p1))*2);

j:=binary1((integer_binary(y1))*((integer_binary1 (x1(i)))));

p1:=binary1((integer_binary(p1))+((integer_binary (j))));

if (p1 >= m1) then
p1:=binary1(((integer_binary(p1))-(integer_binary (m1))));
end if;

if (p1 >= m1) then
p1:=binary1(((integer_binary(p1))-(integer_binary (m1))));
end if;
i:=i-1;

end loop;
return p1;
end mul_mod;

FUNCTION modexp3 (exp_m,exp_n: integer;
exp_e: std_logic_vector(31 downto 0)) return integer is
variable s:integer;
variable result: integer:=1;
begin
S := exp_m;

L1: for I in 0 to 31 loop

I2:    if (exp_e(I) = '1') then
result := integer_binary(mul_mod(binary1(result),binary1(s),binary1(exp_n)));
S := integer_binary(mul_mod(binary1(s),binary1(s),binary1(exp_n)));
else
S := integer_binary(mul_mod(binary1(s),binary1(s),binary1(exp_n)));
end if I2;

end loop L1 ;
return result;
end modexp3;

FUNCTION park1 (in_seed1,max1: integer) return integer is
variable hi:integer;
variable lo:integer;
variable out_seed:integer;
variable test:integer;
variable random1: integer;
variable rejected: integer;
variable a:integer:=16807;
variable m:integer:=2147483647;
variable q: integer:=127773;
variable r: integer:=2836;
variable seed:integer;

begin
seed:=in_seed1;

for en in 0 to 1 loop
if (en = 0) then
hi:=in_seed1 / q;
else
hi:=out_seed / q;
end if;

lo:=in_seed1 mod q;
test:=((a*lo) - (r*hi));

if test > 0 then
Out_seed:= test;

else
Out_seed:= test + m;

end if;
end loop;
random1:=out_seed mod max1;
if random1 = 0 then
seed:=(seed-1)**2;
random1:= park1(seed,max1);
end if;
return random1;
end park1;

-- Primality Test Function
Function IS_Prime(number: integer) return STD_Logic is
Variable d: integer;
Variable d_binary: std_logic_vector(31 downto 0);
Variable s_1: integer :=0;
Variable iteration: integer :=1;
Variable x: integer;
Variable a: integer;
variable two:std_logic_vector(31 downto 0):="00000000000000000000000000000010";
Variable fake: integer;

Begin
d:= number -1;
if ( number < 2) then
Return '0';
end if;
if ( number = 2) then
Return '1';
end if;
if ( number /= 2 and number mod 2 = 0) then
return '0';
end if;
while ( d mod 2 = 0 ) loop
d:=d/2;
s_1:=s_1+1;
end loop;
d_binary:=binary1(d);
ii_loop: for ii in 0 to iteration-1 loop
a:=park1((ii+(s_1*100000))+number,(number-2));
x:=modexp3 (a,number,d_binary);
z4: if ((x /= 1) and (x /= number -1)) then
R_LOOP:         for r in 0 to s_1-1 loop
fake:=0;
x:=modexp3(x,number,two);
z0: if (x = number -1) then
fake:=1;
exit R_LOOP when fake = 1;
end if z0;
z1: if (x = 1) then
return '0';
end if z1;
end loop R_LOOP;

z2: if (fake/=1) then
return '0';
end if z2;

end if z4;
end loop ii_loop;
return '1';
End IS_Prime;
Begin

Test1 <= IS_Prime(N);

end Behavior1;
``````

I am new to VHDL and this is really confusing me where I have no progress in my project. Please, I need that program to be in structural type (port mapping).

-
IMO, your problem is more fundamental. You're thinking and writing software, but to synthesize you need to write hardware. For example, a "while" loop in software will normally turn into a state machine in hardware. Given that Rabin Miller in software is common, you're pretty much asking somebody to do your project for you. – Jerry Coffin Feb 26 '14 at 16:34
No bro I am not doing that. My project is much heavier than that. It is an RSA cryptosystem. So, this is a small portion of my program, and I am sure if you help me, I will handle it. I just want to understand how to play with structural. Then I can do my own program and complete my project. Thank you ^_^ – user3300910 Feb 26 '14 at 16:42
Functions certainly are synthesisable by most synthesis tools, if they are written with hardware generation constraints in mind. One rule : avoid while loops; for loops with fixed bounds should be OK. – Brian Drummond Feb 26 '14 at 17:18
Great many thanks – user3300910 Feb 27 '14 at 9:59

You asked for some hints, so I'll just write some things that come to mind from looking at your code, hoping it will be helpful.

• There is no problem in using functions; they are a good way to organize your design. They are synthesizable, as long as the statements you use in the function body are synthesizable as well.
• Don't reinvent the wheel. Most of the functions you wrote are already predefined in the standard libraries. Do some research before implementing, and try to think whether it is a common subprogram, one that would be useful to most designers. If this is the case, there is probably a ready solution, especially if it involves type conversions or math.
• As Brian Drummond said, try to avoid `while` loops because they are harder for the compiler to guess the total number of iterations. `for` loops with constant limits are easier on the synthesizer. And forget about nested loops with variable ranges.
• Jerry Coffin is also right when he says that there may be some confusion between how you implement an algorithm in hardware vs. in software. Most of the times, drawing a hardware diagram before writing any code helps sort things out. Many times, it at least reveals that the designer does not have a very good idea of what it takes to implement the algorithm in hardware.
• You want to make the transition from software to hardware. A big part of it is to decide what you need to do instantly (within a single clock cycle), and what you want to do sequentially (spread over several clock cycles). So, suppose you have some behavioral (non-synthesizable) code that calculates something using a loop, and you want to make this calculation in hardware.
• If you need to calculate it in a syngle clock cycle, the compiler will have replicate the hardware for all loop iterations, which might be huge.
• If you can spread the calculation over several clock cycles, your best bet is to design a finite state machine (FSM) for this calculation. Again, draw a diagram before writing the code, this will help a lot in your case.

Hope this helps point you in the right direction.

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I really appreciate your help, but your assistance was not to convert my code to structural. I am required to handle it ): – user3300910 Feb 27 '14 at 10:12
Would you care to explain in more detail what you call "structural code"? If by structural you mean "code that uses nothing but component instantiations", then it really doesn't make much sense as a requirement, specially for a senior design project. Maybe the discussion should be about synthsizable vs. non-synthesizable code. – rick Feb 27 '14 at 14:50