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-- EMACS settings: -*- tab-width: 2; indent-tabs-mode: t -*-
-- vim: tabstop=2:shiftwidth=2:noexpandtab
-- kate: tab-width 2; replace-tabs off; indent-width 2;
--
-- =============================================================================
-- Authors: Patrick Lehmann
-- Thomas B. Preusser
--
-- Package: Simulation constants, functions and utilities.
--
-- Description:
-- ------------------------------------
-- TODO
--
-- License:
-- =============================================================================
-- Copyright 2007-2015 Technische Universitaet Dresden - Germany
-- Chair for VLSI-Design, Diagnostics and Architecture
--
-- Licensed under the Apache License, Version 2.0 (the "License");
-- you may not use this file except in compliance with the License.
-- You may obtain a copy of the License at
--
-- http://www.apache.org/licenses/LICENSE-2.0
--
-- Unless required by applicable law or agreed to in writing, software
-- distributed under the License is distributed on an "AS IS" BASIS,
-- WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
-- See the License for the specific language governing permissions and
-- limitations under the License.
-- =============================================================================
library IEEE;
use IEEE.STD_LOGIC_1164.all;
library PoC;
use PoC.vectors.all;
use PoC.strings.all;
use PoC.physical.all;
package simulation is
-- predefined constants to ease testvector concatenation
constant U8 : T_SLV_8 := (others => 'U');
constant U16 : T_SLV_16 := (others => 'U');
constant U24 : T_SLV_24 := (others => 'U');
constant U32 : T_SLV_32 := (others => 'U');
constant D8 : T_SLV_8 := (others => '-');
constant D16 : T_SLV_16 := (others => '-');
constant D24 : T_SLV_24 := (others => '-');
constant D32 : T_SLV_32 := (others => '-');
-- Testbench Status Management
-- ===========================================================================
-- VHDL'08: Provide a protected tSimStatus type that may be used for
-- other purposes as well. For compatibility with the VHDL'93
-- implementation, the plain procedure implementation is also
-- provided on top of a package private instance of this type.
type T_TB_STATUS is protected
-- The status is changed to failed. If a message is provided, it is
-- reported as an error.
procedure simFail(msg : in string := "");
-- If the passed condition has evaluated false, the status is marked
-- as failed. In this case, the optional message will be reported as
-- an error if provided.
procedure simAssert(cond : in boolean; msg : in string := "");
-- Prints the final status. Unless simFail() or simAssert() with a
-- false condition have been called before, a successful completion
-- will be indicated, a failure otherwise.
procedure simReport;
end protected;
type T_SIM_STATUS is protected
procedure stop;
impure function isStopped return BOOLEAN;
end protected;
-- The testbench is marked as failed. If a message is provided, it is
-- reported as an error.
procedure tbFail(msg : in string := "");
-- If the passed condition has evaluated false, the testbench is marked
-- as failed. In this case, the optional message will be reported as an
-- error if one was provided.
procedure tbAssert(cond : in boolean; msg : in string := "");
-- Prints out the overall testbench result as defined by the automated
-- testbench process. Unless tbFail() or tbAssert() with a false condition
-- have been called before, a successful completion will be reported, a
-- failure otherwise.
procedure tbPrintResult;
-- clock generation
-- ===========================================================================
subtype T_DutyCycle is REAL range 0.0 to 1.0;
procedure simStop;
impure function simIsStopped return BOOLEAN;
procedure simGenerateClock(signal Clock : out STD_LOGIC; constant Frequency : in FREQ; constant DutyCycle : T_DutyCycle := 0.5);
procedure simGenerateClock(signal Clock : out STD_LOGIC; constant Period : in TIME; constant DutyCycle : T_DutyCycle := 0.5);
-- waveform generation
-- ===========================================================================
type T_SIM_WAVEFORM_TUPLE_SL is record
Delay : TIME;
Value : STD_LOGIC;
end record;
type T_SIM_WAVEFORM_TUPLE_SLV_8 is record
Delay : TIME;
Value : T_SLV_8;
end record;
type T_SIM_WAVEFORM_TUPLE_SLV_16 is record
Delay : TIME;
Value : T_SLV_16;
end record;
type T_SIM_WAVEFORM_TUPLE_SLV_24 is record
Delay : TIME;
Value : T_SLV_24;
end record;
type T_SIM_WAVEFORM_TUPLE_SLV_32 is record
Delay : TIME;
Value : T_SLV_32;
end record;
type T_SIM_WAVEFORM_TUPLE_SLV_48 is record
Delay : TIME;
Value : T_SLV_48;
end record;
type T_SIM_WAVEFORM_TUPLE_SLV_64 is record
Delay : TIME;
Value : T_SLV_64;
end record;
type T_SIM_WAVEFORM_SL is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SL;
type T_SIM_WAVEFORM_SLV_8 is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SLV_8;
type T_SIM_WAVEFORM_SLV_16 is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SLV_16;
type T_SIM_WAVEFORM_SLV_24 is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SLV_24;
type T_SIM_WAVEFORM_SLV_32 is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SLV_32;
type T_SIM_WAVEFORM_SLV_48 is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SLV_48;
type T_SIM_WAVEFORM_SLV_64 is array(NATURAL range <>) of T_SIM_WAVEFORM_TUPLE_SLV_64;
procedure simGenerateWaveform(signal Wave : out BOOLEAN; Waveform: T_TIMEVEC; InitialValue : BOOLEAN);
procedure simGenerateWaveform(signal Wave : out STD_LOGIC; Waveform: T_TIMEVEC; InitialValue : STD_LOGIC := '0');
procedure simGenerateWaveform(signal Wave : out STD_LOGIC; Waveform: T_SIM_WAVEFORM_SL; InitialValue : STD_LOGIC := '0');
procedure simGenerateWaveform(signal Wave : out T_SLV_8; Waveform: T_SIM_WAVEFORM_SLV_8; InitialValue : T_SLV_8);
procedure simGenerateWaveform(signal Wave : out T_SLV_16; Waveform: T_SIM_WAVEFORM_SLV_16; InitialValue : T_SLV_16);
procedure simGenerateWaveform(signal Wave : out T_SLV_24; Waveform: T_SIM_WAVEFORM_SLV_24; InitialValue : T_SLV_24);
procedure simGenerateWaveform(signal Wave : out T_SLV_32; Waveform: T_SIM_WAVEFORM_SLV_32; InitialValue : T_SLV_32);
procedure simGenerateWaveform(signal Wave : out T_SLV_48; Waveform: T_SIM_WAVEFORM_SLV_48; InitialValue : T_SLV_48);
procedure simGenerateWaveform(signal Wave : out T_SLV_64; Waveform: T_SIM_WAVEFORM_SLV_64; InitialValue : T_SLV_64);
function simGenerateWaveform_Reset(constant Pause : TIME := 0 ns; ResetPulse : TIME := 10 ns) return T_TIMEVEC;
end;
use std.TextIO.all;
package body simulation is
-- Testbench Status Management
-- ===========================================================================
type T_TB_STATUS is protected body
-- Internal state variable to log a failure condition for final reporting.
-- Once de-asserted, this variable will never return to a value of true.
variable pass : boolean := true;
procedure simFail(msg : in string := "") is
begin
if msg'length > 0 then
report msg severity error;
end if;
pass := false;
end;
procedure simAssert(cond : in boolean; msg : in string := "") is
begin
if not cond then
simFail(msg);
end if;
end;
procedure simReport is
variable l : line;
begin
write(l, string'("SIMULATION RESULT = "));
if pass then
write(l, string'("PASSED"));
else
write(l, string'("FAILED"));
end if;
writeline(output, l);
end;
end protected body;
type T_SIM_STATUS is protected body
variable stopped : BOOLEAN := FALSE;
procedure stop is
begin
stopped := TRUE;
end procedure;
impure function isStopped return BOOLEAN is
begin
return stopped;
end function;
end protected body;
-- The default global tSimStatus object.
shared variable tbStatus : T_TB_STATUS;
shared variable simStatus : T_SIM_STATUS;
-- legacy procedures
-- ===========================================================================
procedure tbFail(msg : in string := "") is
begin
tbStatus.simFail(msg);
end;
procedure tbAssert(cond : in boolean; msg : in string := "") is
begin
tbStatus.simAssert(cond, msg);
end;
procedure tbPrintResult is
begin
tbStatus.simReport;
end procedure;
-- clock generation
-- ===========================================================================
procedure simStop is
begin
simStatus.stop;
end procedure;
impure function simIsStopped return BOOLEAN is
begin
return simStatus.isStopped;
end function;
procedure simGenerateClock(signal Clock : out STD_LOGIC; constant Frequency : in FREQ; constant DutyCycle : T_DutyCycle := 0.5) is
constant Period : TIME := to_time(Frequency);
begin
simGenerateClock(Clock, Period, DutyCycle);
end procedure;
procedure simGenerateClock(signal Clock : out STD_LOGIC; constant Period : in TIME; constant DutyCycle : T_DutyCycle := 0.5) is
constant TIME_HIGH : TIME := Period * DutyCycle;
constant TIME_LOW : TIME := Period - TIME_HIGH;
begin
Clock <= '0';
while (not simStatus.isStopped) loop
wait for TIME_LOW;
Clock <= '1';
wait for TIME_HIGH;
Clock <= '0';
end loop;
end procedure;
-- waveform generation
-- ===========================================================================
procedure simGenerateWaveform(signal Wave : out BOOLEAN; Waveform : T_TIMEVEC; InitialValue : BOOLEAN) is
variable State : BOOLEAN := InitialValue;
begin
Wave <= State;
for i in Waveform'range loop
wait for Waveform(i);
State := not State;
Wave <= State;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out STD_LOGIC; Waveform: T_TIMEVEC; InitialValue : STD_LOGIC := '0') is
variable State : STD_LOGIC := InitialValue;
begin
Wave <= State;
for i in Waveform'range loop
wait for Waveform(i);
State := not State;
Wave <= State;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out STD_LOGIC; Waveform: T_SIM_WAVEFORM_SL; InitialValue : STD_LOGIC := '0') is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out T_SLV_8; Waveform: T_SIM_WAVEFORM_SLV_8; InitialValue : T_SLV_8) is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out T_SLV_16; Waveform: T_SIM_WAVEFORM_SLV_16; InitialValue : T_SLV_16) is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out T_SLV_24; Waveform: T_SIM_WAVEFORM_SLV_24; InitialValue : T_SLV_24) is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out T_SLV_32; Waveform: T_SIM_WAVEFORM_SLV_32; InitialValue : T_SLV_32) is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out T_SLV_48; Waveform: T_SIM_WAVEFORM_SLV_48; InitialValue : T_SLV_48) is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
procedure simGenerateWaveform(signal Wave : out T_SLV_64; Waveform: T_SIM_WAVEFORM_SLV_64; InitialValue : T_SLV_64) is
begin
Wave <= InitialValue;
for i in Waveform'range loop
wait for Waveform(i).Delay;
Wave <= Waveform(i).Value;
end loop;
end procedure;
function simGenerateWaveform_Reset(constant Pause : TIME := 0 ns; ResetPulse : TIME := 10 ns) return T_TIMEVEC is
begin
return (0 => Pause, 1 => ResetPulse);
end function;
end package body;
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