The Testbench
The testbench is a VHDL file wich is used by ISE Simulator to test a VHDL component.
ISE is a programming an simulation tool to develop XILINX FPGAs. This work suite include a programminng workspace, a compiler, simulator (ISIM) and much more.
When you program a new component, aou also want to test its behavior. But you always have an FPGA, so you can use a simulator. So that the simulator knows what input signals to simulate you need a so called tesbench.
A testbench lists the component you want to test e.g. abo. (You have written a vhdl file which behaves like ABO and this component is also called abo). And it instantiate this componant as a Unit Under Test (UUT). This component (uut) will be tested with the input and outputs you have specified later in a test process.
At first a testbench code example from ABO for better understanding.
--/*****************************************************************************/
--/* G E N E R A T E D V H D L C O D E */
--/*****************************************************************************/
--/* KIELER - Kiel Integrated Environment for Layout Eclipse RichClient */
--/* */
--/* http://www.informatik.uni-kiel.de/rtsys/kieler/ */
--/* Copyright 2013 by */
--/* + Christian-Albrechts-University of Kiel */
--/* + Department of Computer Science */
--/* + Real-Time and Embedded Systems Group */
--/* */
--/* This code is provided under the terms of the Eclipse Public License (EPL).*/
--/*****************************************************************************/
LIBRARY ieee;
USE ieee.std_logic_1164.ALL;
ENTITY abo_tb IS
END abo_tb;
ARCHITECTURE behavior OF abo_tb IS
COMPONENT abo
PORT(
tick : IN std_logic;
reset : IN std_logic;
--inputs
A: IN boolean;
B: IN boolean;
--outputs
O1 : OUT boolean;
O2 : OUT boolean;
A_out : OUT boolean;
B_out : OUT boolean
);
END COMPONENT;
--Inputs
signal A : boolean := false;
signal B : boolean := false;
--Outputs
signal O1 : boolean := false;
signal O2 : boolean := false;
signal A_out : boolean := false;
signal B_out : boolean := false;
--Control
signal reset : std_logic := '0';
signal tick : std_logic := '0';
constant tick_period : time := 100 ns;
BEGIN
uut: abo PORT MAP(
tick => tick,
reset => reset,
--Inputs
A => A,
B => B,
--Outputs
O1 => O1,
O2 => O2,
A_out => A_out,
B_out => B_out
);
tick_process: process
begin
tick <= '0';
wait for tick_period/2;
tick <= '1';
wait for tick_period/2;
end process;
-- Stimulus process
stim_proc: process
begin
wait for 1 ps;
--sim Process
--NEW TRACE
reset <= '1';
wait for tick_period;
reset <= '0';
-- tick 1
A <= true;
B <= false;
wait for tick_period;
assert( O1 = true )
report "1st trace: 1st tick: O1 should have been true"
severity ERROR;
assert( O2 = false )
report "1st trace: 1st tick: O2 should have been false"
severity ERROR;
assert( A_out = true )
report "1st trace: 1st tick: A_out should have been true"
severity ERROR;
assert( B_out = true )
report "1st trace: 1st tick: B_out should have been true"
severity ERROR;
-- tick 2
A <= false;
B <= false;
wait for tick_period;
assert( O1 = true )
report "1st trace: 2nd tick: O1 should have been true"
severity ERROR;
assert( O2 = false )
report "1st trace: 2nd tick: O2 should have been false"
severity ERROR;
assert( A_out = false )
report "1st trace: 2nd tick: A_out should have been false"
severity ERROR;
assert( B_out = false )
report "1st trace: 2nd tick: B_out should have been false"
severity ERROR;
-- tick 3
A <= false;
B <= true;
wait for tick_period;
assert( O1 = false )
report "1st trace: 3rd tick: O1 should have been false"
severity ERROR;
assert( O2 = true )
report "1st trace: 3rd tick: O2 should have been true"
severity ERROR;
assert( A_out = false )
report "1st trace: 3rd tick: A_out should have been false"
severity ERROR;
assert( B_out = true )
report "1st trace: 3rd tick: B_out should have been true"
severity ERROR;
--NEW TRACE
reset <= '1';
wait for tick_period;
reset <= '0';
-- tick 1
A <= false;
B <= false;
wait for tick_period;
assert( O1 = false )
report "2nd trace: 1st tick: O1 should have been false"
severity ERROR;
assert( O2 = false )
report "2nd trace: 1st tick: O2 should have been false"
severity ERROR;
assert( A_out = false )
report "2nd trace: 1st tick: A_out should have been false"
severity ERROR;
assert( B_out = false )
report "2nd trace: 1st tick: B_out should have been false"
severity ERROR;
-- tick 2
A <= true;
B <= false;
wait for tick_period;
assert( O1 = false )
report "2nd trace: 2nd tick: O1 should have been false"
severity ERROR;
assert( O2 = true )
report "2nd trace: 2nd tick: O2 should have been true"
severity ERROR;
assert( A_out = true )
report "2nd trace: 2nd tick: A_out should have been true"
severity ERROR;
assert( B_out = true )
report "2nd trace: 2nd tick: B_out should have been true"
severity ERROR;
wait;
end process;
END;
Explanation:
Line 23: ABO component declaration
Here the ABO component is declared, so the testbanch knows which component to test.
Line 38: declaration of local signals
Local signals are needed for internal communication and for interconnection between components and processes.
Line 55: instantiation of uut
Here ABO is instantiated
Line 69: tick process
The tick process simulates the tick. This signal is a kind of clock signal. Its cycle duration is set in variable tick_period.
Line 79: the simulation process
The main simulation process, here the input signals are set and the output signals are tested according to specifications in ESO file.
Technical View
Therefor the core ESO contains no information about input and output signals the proper SCL model is needed to generate the testbench.
The variable declaration must fit to the used variables in the ESO file, logically.
| SCL Model | Core ESO File | ESO File |
|---|---|---|
module ABO
input A : boolean;
input B : boolean;
output O1 : boolean = false;
output O2 : boolean = false;
output A_out : boolean;
output B_out : boolean;
{
fork
__WaitAB_HandleA_WaitA:
if A then
A_out = true;
B = true;
B_out = true;
O1 = true;
goto __WaitAB_HandleA_DoneA;
end;
pause;
goto __WaitAB_HandleA_WaitA;
__WaitAB_HandleA_DoneA:
par
__WaitAB_HandleB_WaitB:
pause;
if ! B then
goto __WaitAB_HandleB_WaitB;
end;
B_out = true;
O1 = true;
join;
O1 = false;
O2 = true;
}
| !reset ; %% A : true %% O1 : true %% A_out : true %% B_out : true ; %% O1 : true ; %% B : true %% O2 : true %% B_out : true ; !reset ; ; %% A : true %% O2 : true %% A_out : true %% B_out : true ; | !reset ; A % Output : O1 A_out B_out ; % Output : O1 ; B % Output : O2 B_out ; !reset ; % Output : ; A % Output : O2 A_out B_out ; |
SCL file is not realy correct, will be corrected as soon as possible
The lines 23 to 66 (testbench file) are generated from SCL model file. The model tells the transformation which input and output the abo component must have and the type of these variables (signals in VHDL). So the SCl file is loaded and the needed code is generated.
The simulation process (starts at line 79) is generated using the core ESO file. How the simulation process is generated will be schown at the follwing example:
| SCL | ESO trace | Testbench |
|---|---|---|
module test
input A ;
input B : boolean = false;
input B_value : integer = 0;
input C :boolean = false;
input C_value :boolean = false;
output D;
output E : boolean = false;
output E_value : integer = 5;
output F : boolean = false;
output F_value : boolean = false;
{
//pause;
}
| !reset; A C(false) %Output: D F(false) ;
for better unterstanding we use the normal ESO trace
| A <= true; B <= false; C <= true; C_value <= false; wait for tick_period; assert( D = true ) report "1st trace: 1st tick: D should have been true" severity ERROR; assert( E = false ) report "1st trace: 1st tick: E should have been false" severity ERROR; assert( F = true ) report "1st trace: 1st tick: F should have been true" severity ERROR; assert( F_value = false ) report "1st trace: 1st tick: F_value should have been false" severity ERROR; |
normally the core ESO is used, butSet inputs
Line 2 and 3 in the testbench are setting the inpute. All (!) inputs must be set!
- Pure signal which are present are set to the according value, e.g. A<=true;
- Valued signals which are present are set to thier according value e.g. C_value <= false; and set present B<=true;
- ABSENT values (not listed in ESO files inputs) mus be set absent
- pure singals (not listeg) e.g. K <= false
- valued signals e.g. B <= false, only the present value will be set, the valued signal is not touched
Wait for the tick to pass by
The code wait for tick_period; waits for one tick, so the Hardware can compute the output values.
Test Outputs
After the tick has passed by we must check if the hardware computes the correct outputs. This is done by assertions. Every (!) output must tested!
- Pure signals: Test the pure output signal according to the current ESO tick, if listed, e.g. assert( D = true ). If it is not specified in the trace test for absence,
- Valued signals: For valued signals that are specified in the current ESO tick test the present singal and the valued signal, e.g. assert( F = true ) and assert( F_value = false)
- Valued signals which are not listed in the current tick in the ESO file: test only the present flag for absence (We cannot say anything about absent valued signals)
If an assertion failed the corresponding error will be printed to a log file. The severity level tells the simulator to go on with the simulation altough an error acoored.
Overview
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