Bitvis UVVM VHDL Verification Component Framework: Difference between revisions
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This exact function is already overloaded in the UVVM packages, so including this in our testbench would produce compilation errors. So, let's not include it, but view it as an example of how it's done. | |||
Let's say that it is probable that we'll want to change the number of interrupt sources that the controller can handle. We will then want to able to easily change vectors to the appropriate size. One way is to declare procedures that can trim and fit vectors. This way we can simply change a constant to change the number of sources. | Let's say that it is probable that we'll want to change the number of interrupt sources that the controller can handle. We will then want to able to easily change vectors to the appropriate size. One way is to declare procedures that can trim and fit vectors. This way we can simply change a constant to change the number of sources. |
Revision as of 15:48, 9 March 2021
This wiki page is heavily based on the Powerpoint-presentation found here.[1] The presentation can also be found in the uvvm_util folder.
Introduction
Bitvis UVVM VVC Framework is a complete framework for making VHDL testbenches for verification of FPGA and ASIC desing. You can download the complete code-base, examples and simulations scripts from the Bitvis github.
What's in the folders?
The download includes severals folders:
- bitvis_irqc - example VHDL design + testbench
- bitvis_uart - example VHDL design + testbench
- bitvis_vip_sbi - Verification IP(VIP) for simple bus interface(SBI)
- bitvis_vip_uart - VIP for UART TX and RX
- uvvm_util - UVVM utility library - sufficient for simple testbenches
- uvvm_vvc_framework - Framework for more advanced tutorials
IRQC
The provided example VHDL design is a simple interrupt controller with several internal registers, a bus interface and some input and output signals.
UVVM Utility Library - Testbench creation
Copy the folders bitvis_irqc, bitvis_vip_sbi and uvvm_util to another location before editing the files.
Generate TB entity with DUT instantiated
Our TB entity can in many cases be generated from several tools. Notepad++ (among other) supports plugins that enables copying an entity and pasting it as an instantiation, and also as a complete testbench template. However, we will change some of our signals so that they fit the VIP SBI BFM. The signals to and from the CPU will be converted to t_sbi_if record, which is a type that includes all the SBI signals (cs, addr, rd, wr, wdata, ready and rdata).
--Standard libraries library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; -- Library enabling control of the simulation from VHDL. Eg. std.env.stop library STD; use std.env.all; -- Obviously the UVVM library library uvvm_util; context uvvm_util.uvvm_util_context; -- We will use this library later when implementing the Bus Functional Model -- Includes among much else the record type t_sbi_if and many functions -- If other buses are used, you will have to change this library library bitvis_vip_sbi; use bitvis_vip_sbi.sbi_bfm_pkg.all; -- This file includes definitions of everything from registers to record types use work.irqc_pif_pkg.all; -- Test case entity entity irqc_tb is end entity; -- Test case architecture architecture func of irqc_tb is -- DSP interface and general control signals signal clk : std_logic := '0'; signal arst : std_logic := '0'; -- CPU interface -- t_sbi_if is from the verification IP SBI -- init_sbi_if_signals initialize the inputs to 0 and the outputs to Z signal sbi_if : t_sbi_if(addr(2 downto 0), wdata(7 downto 0), rdata(7 downto 0)) := init_sbi_if_signals(3, 8); -- Interrupt related signals signal irq_source : std_logic_vector(C_NUM_SOURCES-1 downto 0) := (others => '0'); signal irq2cpu : std_logic := '0'; signal irq2cpu_ack : std_logic := '0'; begin ----------------------------------------------------------------------------- -- Instantiate DUT ----------------------------------------------------------------------------- i_irqc: entity work.irqc port map ( -- DSP interface and general control signals clk => clk, arst => arst, -- CPU interface cs => sbi_if.cs, -- NOTICE THE SIGNALS ARE NOW SBI_IF addr => sbi_if.addr, wr => sbi_if.wena, rd => sbi_if.rena, din => sbi_if.wdata, dout => sbi_if.rdata, -- Interrupt related signals irq_source => irq_source, irq2cpu => irq2cpu, irq2cpu_ack => irq2cpu_ack ); end func;
Add support process for clock generation
We now have to add a support process that controls the clock. This has to allow enabling/disabling from the test sequencer. We add the following before "begin" in our architecture:
-- Added for clock generation signal clock_ena : boolean := false; constant C_CLK_PERIOD : time := 10 ns; procedure clock_gen( signal clock_signal : inout std_logic; signal clock_ena : in boolean; constant clock_period : in time ) is variable v_first_half_clk_period : time := C_CLK_PERIOD / 2; begin loop if not clock_ena then wait until clock_ena; end if; wait for v_first_half_clk_period; clock_signal <= not clock_signal; wait for (clock_period - v_first_half_clk_period); clock_signal <= not clock_signal; end loop; end;
Our clock can now be activated from the test sequencer (this will be added in the next step):
-- After begin in the architecture clock_gen(clk, clock_ena, C_CLK_PERIOD); -- Inside the test sequencer process clock_ena <= true;
Add test sequencer process
The next step is to add the test sequencer process. This process controls everything from initialization to termination of the simulation.
-- Set upt clock generator clock_gen(clk, clock_ena, C_CLK_PERIOD); ------------------------------------------------ -- PROCESS: p_main ------------------------------------------------ p_main : process -- The scope tells you where log messages originates - C_SCOPE tells us they originate from the default test sequencer scope constant C_SCOPE : string := C_TB_SCOPE_DEFAULT; -- This is where we will add some procedures later to simplify the tests begin --Print the configuration to the log report_global_ctrl(VOID); report_msg_id_panel(VOID); enable_log_msg(ALL_MESSAGES); --disable_log_msg --enable_log_msg(ID_LOG_HDR); log(ID_LOG_HDR, "Start Simulation of TB for IRQC", C_SCOPE); ------------------------------------------------------------ clock_ena <= true; -- to start clock generator ------------------------------------------------------------ -- End the simulation wait for 1000 ns; -- to allow some time for completion report_alert_counters(FINAL); -- Report final counters and print conclusion for simulation (Success/Fail) log(ID_LOG_HDR, "SIMULATION COMPLETED", C_SCOPE); --Finish the simulation std.env.stop; wait; -- to stop completely end process p_main;
Simulation
We now have the skeleton of the testbench, which we will develop further. But now, let's see if everything works. Bitvis have created simulation scripts for the IRQC example that compiles everything we need, from the source files of the VHDL design, to the testbench (if you called the file irqc_tb.vhd and placed it in the tb-folder) and the SBI BFM and the UVVM library. Open up QuestaSim/ModelSim. Change directory to the script folder:
cd ~/phys321/bitviswiki/bitvis_irqc/script do compile_and_sim_all.do
This will present our result in the transcript windows, but also write _Log.txt file which includes all the information we have asked for. We see that we get the results from the following code:
report_global_ctrl(VOID); report_msg_id_panel(VOID); enable_log_msg(ALL_MESSAGES); log(ID_LOG_HDR, "Start Simulation of TB for IRQC", C_SCOPE); report_alert_counters(FINAL); log(ID_LOG_HDR, "SIMULATION COMPLETED", C_SCOPE);
Commenting these out will result in an empty log.
Verbosity control
We want to able to control the amount of information in our logs, and the framework enables us to prioritize messages based on ID. This makes it easy to turn on or off the information we want. To turn on a specific ID
enable_log_msg(IDNAME);
Turn off:
disable_log_msg(IDNAME);
For writing a message to a certain log ID:
log(IDNAME, "MESSAGE HERE", C_SCOPE);
Remember that C_SCOPE just tells us that the message originated from the default scope and will look like "TB seq." in the log file.
Exampled IDs:
- ID_LOG_HDR, -- ONLY allowed in test sequencer, Log section headers
- ID_SEQUENCER, -- ONLY allowed in test sequencer, Normal log (not log headers)
- ID_BFM, -- Used inside a BFM (to log BFM access)
- ID_CLOCK_GEN, -- Used for logging when clock generators are enabled or disabled
- ALL_MESSAGES -- Applies to ALL message ID apart from ID_NEVER
You'll find all the different ID's in the UVVM Utility Library Quick Reference or defined in uvvm_util/adaptions_pkg.vhd. This also where C_TB_SCOPE_DEFAULT is defined.
Implement first tests
We want to check and verify that our testbench is up and running and to verify our first tests of the DUT. This means that we have to able to set all our signals passive, apply a reset signal and then check the default outputs of the DUT.
Instead of setting all our signals passive one-by-one in our test sequencer we declare a procedure in our p_main process(this is done before begin):
procedure set_inputs_passive( dummy : t_void) is --dummy variable is included only to allow calling the procedure with parenthesis for readability begin sbi_if.cs <= '0'; sbi_if.addr <= (others => '0'); sbi_if.wena <= '0'; sbi_if.rena <= '0'; sbi_if.wdata <= (others => '0'); irq_source <= (others => '0'); irq2cpu_ack <= '0'; log(ID_SEQUENCER_SUB, "All inputs set passive", C_SCOPE); end;
Note that the procedure declaration also includes a dummy variable parameter. This means that we will be able to call the procedure with the more readable:
set_inputs_passive(VOID);
Rather than:
set_inputs_passive;
which is more ambigious.
We may also would like to send pulses on different signals, f.ex. sending a pulse on our reset to see if it behaves like intended. We therefore can include a pulse procedure:
procedure pulse( signal target : inout std_logic_vector; constant pulse_value : in std_logic_vector; signal clock_signal : in std_logic; constant num_periods : in natural; constant msg : in string) is begin if num_periods > 0 then wait until falling_edge(clock_signal); target <= pulse_value; for i in 1 to num_periods loop wait until falling_edge(clock_signal); end loop; else target <= pulse_value; wait for 0 ns; -- Delta cycle only end if; target(target'range) <= (others => '0'); log(ID_SEQUENCER_SUB, "Pulsed to " & to_string(pulse_value, HEX, AS_IS, INCL_RADIX) & ". " & msg, C_SCOPE); end;
In the above example the test sequencer is required to inform the procedure of what value the pulse is to take. The call to the procedure would take the following form:
pulse(arst, 'Z', clk, 10, "Log message - Im pulsing the value 'Z'");
But a more specific overload can be created where pulse always takes value '1':
procedure pulse( signal target : inout std_logic; signal clock_signal : in std_logic; constant num_periods : in natural; constant msg : in string ) is begin if num_periods > 0 then wait until falling_edge(clock_signal); target <= '1'; for i in 1 to num_periods loop wait until falling_edge(clock_signal); end loop; else target <= '1'; wait for 0 ns; -- Delta cycle only end if; target <= '0'; log(ID_SEQUENCER_SUB, msg, C_SCOPE); end;
These procedures can now be called directly from our test sequence:
set_inputs_passive(VOID); pulse(arst, clk, 10, "pulsed reset-signal - active for 10T");
To check signal values we can use the built-in check function check_value():
check_value(irq2cpu, 'X', ERROR, "Interrupt to CPU must be default inactive", C_SCOPE);
The above call checks if the signal irq2cpu is 'X', and obviously fail if everything works correctly and gives the following message:
If we want we can change the number of errors logged before the simulation stops:
set_alert_stop_limit(ERROR, 3);
We now have all the tools needed for the first tests in our sequencer:
set_inputs_passive(VOID); pulse(arst, clk, 10, "Pulsed reset-signal - active for 10T"); check_value(C_NUM_SOURCES > 0, FAILURE, "Must be at least 1 interrupt source", C_SCOPE); check_value(C_NUM_SOURCES <= 8, TB_WARNING, "This TB is only checking IRQC with up to 8 interrupt sources", C_SCOPE); log(ID_LOG_HDR, "Check defaults on output ports", C_SCOPE); ------------------------------------------------------------ check_value(irq2cpu, '0', ERROR, "Interrupt to CPU must be default inactive", C_SCOPE); check_value(sbi_if.rdata, x"00", ERROR, "Register data bus output must be default passive");
This will give us the following log:
This information may only interesting initially and for debug, and can be turned on or off by use of ID.
Subprograms
Some of our testbench code will be repeated several times and the testbench may therefore benefit from creating several subprograms. Obvious examples for our IRQC is: - Register access - Signal checkers - Interrupt source pulsing? - Interrupt acknowledge pulsing? - (Report/log method) - (Alert-handling) - (reset, set_passive, ...)
We've already created and declared set_passive and pulse procedures, but we could f.ex create overloads for UVVM procedures:
-- Log overloads for simplification procedure log( msg : string) is begin log(ID_SEQUENCER, msg, C_SCOPE); end;
This exact function is already overloaded in the UVVM packages, so including this in our testbench would produce compilation errors. So, let's not include it, but view it as an example of how it's done.
Let's say that it is probable that we'll want to change the number of interrupt sources that the controller can handle. We will then want to able to easily change vectors to the appropriate size. One way is to declare procedures that can trim and fit vectors. This way we can simply change a constant to change the number of sources.
subtype t_irq_source is std_logic_vector(C_NUM_SOURCES-1 downto 0); -- Trim (cut) a given vector to fit the number of irq sources (i.e. pot. reduce width) function trim( constant source : std_logic_vector; constant num_bits : positive := C_NUM_SOURCES) return t_irq_source is variable v_result : std_logic_vector(source'length-1 downto 0) := source; begin return v_result(num_bits-1 downto 0); end; -- Fit a given vector to the number of irq sources by masking with zeros above irq width function fit( constant source : std_logic_vector; constant num_bits : positive := C_NUM_SOURCES) return std_logic_vector is variable v_result : std_logic_vector(source'length-1 downto 0) := (others => '0'); variable v_source : std_logic_vector(source'length-1 downto 0) := source; begin v_result(num_bits-1 downto 0) := v_source(num_bits-1 downto 0); return v_result; end;
All IRQC-dedicated subprograms should be declared locally, but more common (f.ex bus-specific) should be declared in common package that can be shared with other.
Register access
To access the IRQC's registers we need to go through the actual process of writing and reading data from them. Fortunately, Bitvis have already taken the responsibility of writing the BFM for the SBI. This doesn't mean that we doesn't have to understand what's going on, since we'll have to write our own BFM's for other buses that we use(Avalon, AXI, etc). January 2017 Bitvis announced that they released VVC for Avalon-MM and AXI4-lite. So we should investigate the BFM procedures. We want to check register values:
procedure sbi_check ( constant addr_value : in unsigned; constant data_exp : in std_logic_vector; constant msg : in string; signal clk : in std_logic; signal cs : inout std_logic; signal addr : inout unsigned; signal rd : inout std_logic; signal wr : inout std_logic; signal ready : in std_logic; signal rdata : in std_logic_vector; constant alert_level : in t_alert_level := error; constant scope : in string := C_SCOPE; constant msg_id_panel : in t_msg_id_panel := shared_msg_id_panel; constant config : in t_sbi_bfm_config := C_SBI_BFM_CONFIG_DEFAULT ) is constant proc_name : string := "sbi_check"; constant proc_call : string := "sbi_check(A:" & to_string(addr_value, HEX, AS_IS, INCL_RADIX) & ", " & to_string(data_exp, HEX, AS_IS, INCL_RADIX) & ")"; -- Normalize to the DUT addr/data widths variable v_normalised_addr : unsigned(addr'length-1 downto 0) := normalize_and_check(addr_value, addr, ALLOW_WIDER_NARROWER, "addr_value", "sbi_core_in.addr", msg); -- Helper variables variable v_data_value : std_logic_vector(rdata'length - 1 downto 0); variable v_check_ok : boolean; variable v_clk_cycles_waited : natural := 0; begin sbi_read(addr_value, v_data_value, msg, clk, cs, addr, rd, wr, ready, rdata, scope, msg_id_panel, config, proc_name); -- Compare values, but ignore any leading zero's if widths are different. -- Use ID_NEVER so that check_value method does not log when check is OK, -- log it here instead. v_check_ok := check_value(v_data_value, data_exp, alert_level, msg, scope, HEX_BIN_IF_INVALID, SKIP_LEADING_0, ID_NEVER, msg_id_panel, proc_call); if v_check_ok then log(config.id_for_bfm, proc_call & "=> OK, read data = " & to_string(v_data_value, HEX, SKIP_LEADING_0, INCL_RADIX) & ". " & msg, scope, msg_id_panel); end if; end procedure;
We see that sbi_check() calls sbi_read() before it checks if the read value is the expected value.
procedure sbi_read ( constant addr_value : in unsigned; variable data_value : out std_logic_vector; constant msg : in string; signal clk : in std_logic; signal cs : inout std_logic; signal addr : inout unsigned; signal rd : inout std_logic; signal wr : inout std_logic; signal ready : in std_logic; signal rdata : in std_logic_vector; constant scope : in string := C_SCOPE; constant msg_id_panel : in t_msg_id_panel := shared_msg_id_panel; constant config : in t_sbi_bfm_config := C_SBI_BFM_CONFIG_DEFAULT; constant proc_name : in string := "sbi_read" -- overwrite if called from other procedure like sbi_check ) is constant proc_call : string := "sbi_read(A:" & to_string(addr_value, HEX, AS_IS, INCL_RADIX) & ")"; -- Normalize to the DUT addr/data widths variable v_normalised_addr : unsigned(addr'length-1 downto 0) := normalize_and_check(addr_value, addr, ALLOW_WIDER_NARROWER, "addr_value", "sbi_core_in.addr", msg); variable v_data_value : std_logic_vector(data_value'range); variable v_clk_cycles_waited : natural := 0; begin wait_until_given_time_after_rising_edge(clk, config.clock_period/4); cs <= '1'; wr <= '0'; rd <= '1'; addr <= v_normalised_addr; wait for config.clock_period; while (config.use_ready_signal and ready = '0') loop if v_clk_cycles_waited = 0 then log(config.id_for_bfm_wait, proc_call & " waiting for response (sbi ready=0)" & msg, scope, msg_id_panel); end if; wait for config.clock_period; v_clk_cycles_waited := v_clk_cycles_waited + 1; check_value(v_clk_cycles_waited <= config.max_wait_cycles, config.max_wait_cycles_severity, ": Timeout while waiting for sbi ready", scope, ID_NEVER, msg_id_panel, proc_call); end loop; cs <= '0'; rd <= '0'; v_data_value := rdata; data_value := v_data_value; if proc_name = "sbi_read" then log(config.id_for_bfm, proc_call & "=> " & to_string(v_data_value, HEX, SKIP_LEADING_0, INCL_RADIX) & ". " & msg, scope, msg_id_panel); else -- Log will be handled by calling procedure (e.g. sbi_check) end if; end procedure;
We don't want to (and probably shouldnt) call the sbi_check and providing all the parameters each time. Some of this can be solved by the overloads with more standard parameters, and with our own check procedures declared locally in our testbench:
procedure check( constant addr_value : in natural; constant data_exp : in std_logic_vector; constant alert_level : in t_alert_level; constant msg : in string) is begin sbi_check(to_unsigned(addr_value, sbi_if.addr'length), data_exp, msg, clk, sbi_if, alert_level, C_SCOPE); end;
The write procedure is also very handy and should be understood:
procedure sbi_write ( constant addr_value : in unsigned; constant data_value : in std_logic_vector; constant msg : in string; signal clk : in std_logic; signal cs : inout std_logic; signal addr : inout unsigned; signal rd : inout std_logic; signal wr : inout std_logic; signal ready : in std_logic; signal wdata : inout std_logic_vector; constant scope : in string := C_SCOPE; constant msg_id_panel : in t_msg_id_panel := shared_msg_id_panel; constant config : in t_sbi_bfm_config := C_SBI_BFM_CONFIG_DEFAULT ) is constant proc_name : string := "sbi_write"; constant proc_call : string := "sbi_write(A:" & to_string(addr_value, HEX, AS_IS, INCL_RADIX) & ", " & to_string(data_value, HEX, AS_IS, INCL_RADIX) & ")"; -- Normalise to the DUT addr/data widths variable v_normalised_addr : unsigned(addr'length-1 downto 0) := normalize_and_check(addr_value, addr, ALLOW_WIDER_NARROWER, "addr_value", "sbi_core_in.addr", msg); variable v_normalised_data : std_logic_vector(wdata'length-1 downto 0) := normalize_and_check(data_value, wdata, ALLOW_NARROWER, "data_value", "sbi_core_in.wdata", msg); variable v_clk_cycles_waited : natural := 0; begin wait_until_given_time_after_rising_edge(clk, config.clock_period/4); cs <= '1'; wr <= '1'; rd <= '0'; addr <= v_normalised_addr; wdata <= v_normalised_data; wait for config.clock_period; while (config.use_ready_signal and ready = '0') loop if v_clk_cycles_waited = 0 then log(config.id_for_bfm_wait, proc_call & " waiting for response (sbi ready=0)" & msg, scope, msg_id_panel); end if; wait for config.clock_period; v_clk_cycles_waited := v_clk_cycles_waited + 1; check_value(v_clk_cycles_waited <= config.max_wait_cycles, config.max_wait_cycles_severity, ": Timeout while waiting for sbi ready", scope, ID_NEVER, msg_id_panel, proc_call); end loop; cs <= '0'; wr <= '0'; log(config.id_for_bfm, proc_call & " completed. " & msg, scope, msg_id_panel); end procedure;
We will create a local overload of this too:
procedure write( constant addr_value : in natural; constant data_value : in std_logic_vector; constant msg : in string) is begin sbi_write(to_unsigned(addr_value, sbi_if.addr'length), data_value, msg, clk, sbi_if, C_SCOPE); end;
We also need to set the sbi_if.ready signal high for this to work:
clock_generator(clk, clock_ena, C_CLK_PERIOD, "IRQC TB clock"); -- Insert this here by the clock generator sbi_if.ready <= '1'; -- always ready in the same clock cycle.
All this enables us to handle transactions at a high level. See Bitvis documentation for how to write your own BFM and what it should include(sanity checks, etc).
Checking register write and read
Now we're enabled to write to and read from the registers. The register addresses are defined in the IRQC package file irqc_pif_bkg.vhd. Notice that we also use the previously declared overloaded version of log() and fit().
log(ID_LOG_HDR, "Check register defaults and access (write + read)", C_SCOPE); ------------------------------------------------------------ log("\nChecking Register defaults"); check(C_ADDR_IRR, x"00", ERROR, "IRR default"); check(C_ADDR_IER, x"00", ERROR, "IER default"); check(C_ADDR_IPR, x"00", ERROR, "IPR default"); check(C_ADDR_IRQ2CPU_ALLOWED, x"00", ERROR, "IRQ2CPU_ALLOWED default"); log("\nChecking Register Write/Read"); write(C_ADDR_IER, fit(x"55"), "IER"); check(C_ADDR_IER, fit(x"55"), ERROR, "IER pure readback"); write(C_ADDR_IER, fit(x"AA"), "IER"); check(C_ADDR_IER, fit(x"AA"), ERROR, "IER pure readback"); write(C_ADDR_IER, fit(x"00"), "IER"); check(C_ADDR_IER, fit(x"00"), ERROR, "IER pure readback");
This check will give us a nice log if everything turns out ok:
However, if there's an error:
Further tests
Now that we've tested register read/write, we should test the trigger/clear mechanism. No further adding of procedures are necessary.
log(ID_LOG_HDR, "Check register trigger/clear mechanism", C_SCOPE); ------------------------------------------------------------ write(C_ADDR_ITR, fit(x"AA"), "ITR : Set interrupts"); check(C_ADDR_IRR, fit(x"AA"), ERROR, "IRR"); write(C_ADDR_ITR, fit(x"55"), "ITR : Set more interrupts"); check(C_ADDR_IRR, fit(x"FF"), ERROR, "IRR"); write(C_ADDR_ICR, fit(x"71"), "ICR : Clear interrupts"); check(C_ADDR_IRR, fit(x"8E"), ERROR, "IRR"); write(C_ADDR_ICR, fit(x"85"), "ICR : Clear interrupts"); check(C_ADDR_IRR, fit(x"0A"), ERROR, "IRR"); write(C_ADDR_ITR, fit(x"55"), "ITR : Set more interrupts"); check(C_ADDR_IRR, fit(x"5F"), ERROR, "IRR"); write(C_ADDR_ICR, fit(x"5F"), "ICR : Clear interrupts"); check(C_ADDR_IRR, fit(x"00"), ERROR, "IRR");
The UVVM Utility Library provides all necessary functions and procedures to do further tests. F.ex. we should send pulses on the irq_source signal to check if the design behaves correctly.
log(ID_LOG_HDR, "Check interrupt sources, IER, IPR and irq2cpu", C_SCOPE); ------------------------------------------------------------ log("\nChecking interrupts and IRR"); write(C_ADDR_ICR, fit(x"FF"), "ICR : Clear all interrupts"); pulse(irq_source, trim(x"AA"), clk, 1, "Pulse irq_source 1T"); check(C_ADDR_IRR, fit(x"AA"), ERROR, "IRR after irq pulses"); pulse(irq_source, trim(x"01"), clk, 1, "Add more interrupts"); check(C_ADDR_IRR, fit(x"AB"), ERROR, "IRR after irq pulses"); pulse(irq_source, trim(x"A1"), clk, 1, "Repeat same interrupts"); check(C_ADDR_IRR, fit(x"AB"), ERROR, "IRR after irq pulses"); pulse(irq_source, trim(x"54"), clk, 1, "Add remaining interrupts"); check(C_ADDR_IRR, fit(x"FF"), ERROR, "IRR after irq pulses"); write(C_ADDR_ICR, fit(x"AA"), "ICR : Clear half the interrupts"); pulse(irq_source, trim(x"A0"), clk, 1, "Add more interrupts"); check(C_ADDR_IRR, fit(x"F5"), ERROR, "IRR after irq pulses"); write(C_ADDR_ICR, fit(x"FF"), "ICR : Clear all interrupts"); check(C_ADDR_IRR, fit(x"00"), ERROR, "IRR after clearing all");
Check stable
Another test provided by UVVM is check_stable(). This function enables us to test if a signal is holding the same value for a minimum provided time. We must declare a variable that holds the time from which we want to test if the signal is stable:
v_time_stamp := now; -- time from which irq2cpu should be stable off until triggered
Later we're now able to test if the signal has been holding the same value the whole period:
check_stable(irq2cpu, (now - v_time_stamp), ERROR, "No spikes allowed on irq2cpu", C_SCOPE);
Remember to declare the variable in the process:
variable v_time_stamp : time := 0 ns;
Await value
To check if a signal gets the expected value within a specified time value we use await_vale(). The test below throws an error if irq2cpu doesn't obtain the value '1' within 0 ns(!). Therefore expected immediately:
await_value(irq2cpu, '1', 0 ns, C_CLK_PERIOD, ERROR, "Interrupt expected immediately", C_SCOPE);
Other useful functions
Check the UVVM Utility Library Quick Reference for syntax details.
await_change()
Expects and waits for a change on the given signal, inside a given time window.
check_value_in_range()
Throws an error of the signal value is outside the specified minimum and maximum values.
UVVM VVC
Guide coming....
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