Code: Alles auswählen
library ieee;
use ieee.std_logic_1164.all;
entity rslatch is
port (
r, s: in std_logic;
q: out std_logic
);
end;
architecture verhalten of rslatch is
signal q1, q2: std_logic;
signal init: std_logic;
begin
init <= '0' after 0 ns, '1' after 1 ns;
q1 <= '1' when (init='0') else
(q2 nor r);
q2 <= '0' when (init='0') else
(q1 nor s);
q <= q1;
end;
library ieee;
use ieee.std_logic_1164.all;
entity clockcontrolledrslatch is
port (
r, s: in std_logic;
c: in std_logic;
q: out std_logic
);
end;
architecture behaviour of clockcontrolledrslatch is
component rslatch
port (
r, s: in std_logic;
q: out std_logic
);
end component;
signal r1, s1: std_logic;
begin
rslatch1: rslatch PORT MAP (r=>r1, s=>s1, q=>q);
s1 <= (s and c);
r1 <= (r and c);
end;
library ieee;
use ieee.std_logic_1164.all;
entity dlatch is
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end;
architecture behaviour of dlatch is
component clockcontrolledrslatch
port (
r, s: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
signal r1, s1: std_logic;
begin
clockcontrolledrslatch1: clockcontrolledrslatch PORT MAP (r=>r1, s=>s1, q=>q, c=>c);
s1 <= not d;
r1 <= d;
end;
library ieee;
use ieee.std_logic_1164.all;
entity dmsflipflop is
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end;
architecture behaviour of dmsflipflop is
component dlatch
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
signal d1, d2: std_logic;
signal c1, c2: std_logic;
signal q1, q2: std_logic;
begin
dlatch1: dlatch PORT MAP (d=>d1, c=>c1, q=>q1);
dlatch2: dlatch PORT MAP (d=>d2, c=>c2, q=>q2);
c1 <= c;
c2 <= not c;
d1 <= d;
d2 <= q1;
q <= q2;
end;
library ieee;
use ieee.std_logic_1164.all;
entity flipfloptestbench is
port (
q: out std_logic
);
end;
architecture behaviour of flipfloptestbench is
component dmsflipflop
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
signal d, c: std_logic;
begin
dmsflipflop1: dmsflipflop PORT MAP (q=>q, d=>d, c=>c);
c <= '0' after 0 ns, '1' after 20 ns, '0' after 40 ns, '1' after 60 ns, '0' after 80 ns, '1' after 100 ns, '0' after 120 ns, '1' after 140 ns,
'0' after 160 ns, '1' after 180 ns, '0' after 200 ns, '1' after 220 ns, '0' after 240 ns,
'1' after 260 ns, '0' after 280 ns, '1' after 300 ns, '0' after 320 ns, '1' after 340 ns;
d <= '0' after 0 ns, '1' after 150 ns, '0' after 250 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
entity reg32 is
port (
we: in std_logic;
q: out std_logic_vector (31 downto 0);
d: in std_logic_vector (31 downto 0)
);
end;
architecture behaviour of reg32 is
component dmsflipflop
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
begin
l1:
for i in 0 to 31 generate
dmsflipflop1: dmsflipflop PORT MAP (q=>q(i), d=>d(i), c=>we);
end generate;
end;
library ieee;
use ieee.std_logic_1164.all;
entity reg32testbench is
port (
q: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of reg32testbench is
component reg32
port (
d: in std_logic_vector (31 downto 0);
we: in std_logic;
q: out std_logic_vector (31 downto 0)
);
end component;
signal d: std_logic_vector (31 downto 0);
signal we: std_logic;
begin
reg32a: reg32 PORT MAP (d=>d, q=>q, we=>we);
d(0) <= '1';
d(1) <= '0';
d(2) <= '1';
d(3) <= '0';
d(4) <= '1';
d(5) <= '0';
d(6) <= '1';
d(7) <= '0';
d(8) <= '1';
d(9) <= '1';
d(10) <= '0';
d(11) <= '1';
d(12) <= '0';
d(13) <= '1';
d(14) <= '0';
d(15) <= '1';
d(16) <= '0';
d(17) <= '1';
d(18) <= '0';
d(19) <= '1';
d(20) <= '0';
d(21) <= '1';
d(22) <= '0';
d(23) <= '1';
d(24) <= '0';
d(25) <= '1';
d(26) <= '0';
d(27) <= '1';
d(28) <= '0';
d(29) <= '1';
d(30) <= '0';
d(31) <= '1';
we <= '0' after 0 ns, '1' after 10 ns, '0' after 20 ns, '1' after 30 ns, '0' after 40 ns, '1' after 60 ns, '0' after 80 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
entity addressdecoder5to32 is
port (
a: in std_logic_vector (4 downto 0);
b: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of addressdecoder5to32 is
begin
-- 00000
b (0) <= not a (4) and not a (3) and not a (2) and not a (1) and not a (0);
-- 00001
b (1) <= not a (4) and not a (3) and not a (2) and not a (1) and a (0);
-- 00010
b (2) <= not a (4) and not a (3) and not a (2) and a (1) and not a (0);
-- 00011
b (3) <= not a (4) and not a (3) and not a (2) and a (1) and a (0);
-- 00100
b (4) <= not a (4) and not a (3) and a (2) and not a (1) and not a (0);
-- 00101
b (5) <= not a (4) and not a (3) and a (2) and not a (1) and a (0);
-- 00110
b (6) <= not a (4) and not a (3) and a (2) and a (1) and not a (0);
-- 00111
b (7) <= not a (4) and not a (3) and a (2) and a (1) and a (0);
-- 01000
b (8) <= not a (4) and a (3) and not a (2) and not a (1) and not a (0);
-- 01001
b (9) <= not a (4) and a (3) and not a (2) and not a (1) and a (0);
-- 01010
b (10) <= not a (4) and a (3) and not a (2) and a (1) and not a (0);
-- 01011
b (11) <= not a (4) and a (3) and not a (2) and a (1) and a (0);
-- 01100
b (12) <= not a (4) and a (3) and a (2) and not a (1) and not a (0);
-- 01101
b (13) <= not a (4) and a (3) and a (2) and not a (1) and a (0);
-- 01110
b (14) <= not a (4) and a (3) and a (2) and a (1) and not a (0);
-- 01111
b (15) <= not a (4) and a (3) and a (2) and a (1) and a (0);
-- 10000
b (16) <= a (4) and not a (3) and not a (2) and not a (1) and not a (0);
-- 10001
b (17) <= a (4) and not a (3) and not a (2) and not a (1) and a (0);
-- 10010
b (18) <= a (4) and not a (3) and not a (2) and a (1) and not a (0);
-- 10011
b (19) <= a (4) and not a (3) and not a (2) and a (1) and a (0);
-- 10100
b (20) <= a (4) and not a (3) and a (2) and not a (1) and not a (0);
-- 10101
b (21) <= a (4) and not a (3) and a (2) and not a (1) and a (0);
-- 10110
b (22) <= a (4) and not a (3) and a (2) and a (1) and not a (0);
-- 10111
b (23) <= a (4) and not a (3) and a (2) and a (1) and a (0);
-- 11000
b (24) <= a (4) and a (3) and not a (2) and not a (1) and not a (0);
-- 11001
b (25) <= a (4) and a (3) and not a (2) and not a (1) and a (0);
-- 11010
b (26) <= a (4) and a (3) and not a (2) and a (1) and not a (0);
-- 11011
b (27) <= a (4) and a (3) and not a (2) and a (1) and a (0);
-- 11100
b (28) <= a (4) and a (3) and a (2) and not a (1) and not a (0);
-- 11101
b (29) <= a (4) and a (3) and a (2) and not a (1) and a (0);
-- 11110
b (30) <= a (4) and a (3) and a (2) and a (1) and not a (0);
-- 11111
b (31) <= a (4) and a (3) and a (2) and a (1) and a (0);
end;
library ieee;
use ieee.std_logic_1164.all;
entity addressdecoder5to32testbench is
port (
q: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of addressdecoder5to32testbench is
component addressdecoder5to32
port (
a: in std_logic_vector (4 downto 0);
b: out std_logic_vector (31 downto 0)
);
end component;
signal d: std_logic_vector (4 downto 0);
begin
addressdecoder5to32a: addressdecoder5to32 PORT MAP (b=>q, a=>d);
d (0) <= '0' after 0 ns, '1' after 10 ns, '0' after 20 ns, '1' after 30 ns, '0' after 40 ns, '1' after 50 ns, '0' after 60 ns, '1' after 70 ns, '0' after 80 ns, '1' after 90 ns, '0' after 100 ns, '1' after 110 ns, '0' after 120 ns, '1' after 130 ns, '0' after 140 ns, '1' after 150 ns, '0' after 160 ns, '1' after 170 ns, '0' after 180 ns, '1' after 190 ns, '0' after 200 ns, '1' after 210 ns, '0' after 220 ns, '1' after 230 ns, '0' after 240 ns, '1' after 250 ns, '0' after 260 ns, '1' after 270 ns, '0' after 280 ns, '1' after 290 ns, '0' after 300 ns, '1' after 310 ns;
d (1) <= '0' after 0 ns, '1' after 20 ns, '0' after 40 ns, '1' after 60 ns, '0' after 80 ns, '1' after 100 ns, '0' after 120 ns, '1' after 140 ns, '0' after 160 ns, '1' after 180 ns, '0' after 200 ns, '1' after 220 ns, '0' after 240 ns, '1' after 260 ns, '0' after 280 ns, '1' after 300 ns, '0' after 320 ns, '1' after 340 ns;
d (2) <= '0' after 0 ns, '1' after 40 ns, '0' after 80 ns, '1' after 120 ns, '0' after 160 ns, '1' after 200 ns, '0' after 240 ns, '1' after 280 ns, '0' after 320 ns, '1' after 360 ns;
d (3) <= '0' after 0 ns, '1' after 80 ns, '0' after 160 ns, '1' after 240 ns, '0' after 320 ns, '1' after 400 ns;
d (4) <= '0' after 0 ns, '1' after 160 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
entity registerset32x32 is
port (
writereg: in std_logic_vector (4 downto 0);
readreg1: in std_logic_vector (4 downto 0);
readreg2: in std_logic_vector (4 downto 0);
readport1: out std_logic_vector (31 downto 0);
readport2: out std_logic_vector (31 downto 0);
writeport: in std_logic_vector (31 downto 0);
we: in std_logic
);
end;
architecture behaviour of registerset32x32 is
component reg32
port (
d: in std_logic_vector (31 downto 0);
we: in std_logic;
q: out std_logic_vector (31 downto 0)
);
end component;
component addressdecoder5to32
port (
a: in std_logic_vector (4 downto 0);
b: out std_logic_vector (31 downto 0)
);
end component;
signal writereg1: std_logic_vector (31 downto 0);
begin
addressdecoder5to32a: addressdecoder5to32 PORT MAP (a=>writereg, b=>writereg1);
l1:
for i in 0 to 31 generate
reg32a: reg32 PORT MAP (we=>writereg1(i),d=>writeport,q=>readport1); -- WARNING - WARNING
end generate;
end;
library ieee;
use ieee.std_logic_1164.all;
entity mux32x2_1 is
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end;
architecture behaviour of mux32x2_1 is
begin
l1:
for i in 0 to 31 generate
c (i) <= (a (i) and s) or (b (i) and not s);
end generate;
end;
library ieee;
use ieee.std_logic_1164.all;
entity mux32x2_1testbench is
port (
c: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of mux32x2_1testbench is
component mux32x2_1
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end component;
signal a: std_logic_vector (31 downto 0);
signal b: std_logic_vector (31 downto 0);
signal s: std_logic;
begin
m: mux32x2_1 PORT MAP (b=>b, a=>a, c=>c, s=>s);
a (0) <= '0';
a (1) <= '1';
a (2) <= '0';
a (3) <= '1';
a (4) <= '0';
a (31) <= '1';
a (5) <= '0';
a (6) <= '1';
a (7) <= '0';
a (8) <= '1';
a (9) <= '0';
a (10) <= '1';
a (11) <= '0';
a (12) <= '1';
a (13) <= '0';
a (14) <= '1';
a (15) <= '0';
a (16) <= '1';
a (17) <= '0';
a (18) <= '1';
a (19) <= '0';
a (20) <= '1';
a (21) <= '0';
a (22) <= '1';
a (23) <= '0';
a (24) <= '1';
a (25) <= '0';
a (26) <= '1';
a (27) <= '0';
a (28) <= '1';
a (29) <= '0';
a (30) <= '1';
b (0) <= '0';
b (1) <= '0';
b (2) <= '0';
b (3) <= '1';
b (4) <= '0';
b (31) <= '1';
b (5) <= '1';
b (6) <= '0';
b (7) <= '0';
b (8) <= '1';
b (9) <= '0';
b (10) <= '1';
b (11) <= '0';
b (12) <= '0';
b (13) <= '0';
b (14) <= '1';
b (15) <= '0';
b (16) <= '0';
b (17) <= '1';
b (18) <= '1';
b (19) <= '0';
b (20) <= '1';
b (21) <= '0';
b (22) <= '0';
b (23) <= '1';
b (24) <= '1';
b (25) <= '0';
b (26) <= '1';
b (27) <= '0';
b (28) <= '1';
b (29) <= '0';
b (30) <= '1';
s <= '0' after 0 ns, '1' after 10 ns, '0' after 20 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
Ich mache jetzt nicht weiter mit VHDL und Registersatz - erkläre aber, wie ich es mache. Ich mache es ohne Array
Bisher, habe ich ja einen MUX geschrieben, der ist 32x2:1, dann kommt 32x4:1 und so weiter. Ich kaskadiere die.
Das mache ich auch beim Registersatz. Jetzt könnte ich, 32 Register nehmen und die MUX kaskadieren
Mache ich aber nicht. Ich mache einen 2 Bit Registersatz. Um den 2 Bit Register, es gibt
1.) Lesedaten-1
2.) Lesedaten-2
3.) Schreibedaten
D.h. es gibt 2 Leseports und 1 Schreibport. Aber ich mache 2 Bit Register-Satz. Und um die mache ich MUX. Und darum wieder MUX
Das andere, damit fange ich jetzt an. Der Zilog Z80 ist doch relativ einfach an das EEPROM an zu schliessen
Ich habe nachgedacht. Er hat 16 Bit Addressleitung. Das ist zu viel zu verbinden.
Ich mache jetzt nicht weiter mit VHDL und Registersatz - erkläre aber, wie ich es mache. Ich mache es ohne Array
Bisher, habe ich ja einen MUX geschrieben, der ist 32x2:1, dann kommt 32x4:1 und so weiter. Ich kaskadiere die.
Das mache ich auch beim Registersatz. Jetzt könnte ich, 32 Register nehmen und die MUX kaskadieren
Mache ich aber nicht. Ich mache einen 2 Bit Registersatz. Um den 2 Bit Register, es gibt
1.) Lesedaten-1
2.) Lesedaten-2
3.) Schreibedaten
D.h. es gibt 2 Leseports und 1 Schreibport. Aber ich mache 2 Bit Register-Satz. Und um die mache ich MUX. Und darum wieder MUX
Das andere, damit fange ich jetzt an. Der Zilog Z80 ist doch relativ einfach an das EEPROM an zu schliessen
Ich habe nachgedacht. Er hat 16 Bit Addressleitung. Das ist zu viel zu verbinden.
Für eine Streifenrasterplatine. aber es zwingt mich ja niemand alles Addressbits zu verwenden. Die obersten vom EEPROM tue ich auf 'L' und die Addressbits oben vom Zilog Z80 verbinde ich nicht
Damit habe ich nur 10. Und zufälligerweise sind A0 bis A7, bei EEPROM und Zilog Z80 auf der richtigen Seite. Damit fange ich jetzt an.
viewtopic.php?t=188
Ein Flop könnte man vielleicht so erklären. Wenn ich einen FPGA habe, ich habe vor auf dem RAM und ROM zu realisieren. Als Speicher. Dann mache ich kein Array, mit Speicherstellen, sondern ich mache x-Leitung und y-Leitung, Zeilenleitung, Spaltenleitung und mache damit zu 100% einen Speicher.
Gut, wenn ich jetzt einen Speicher auf einem FPGA habe, wie viel passt drauf? So viel wie der FPGA Speicher hat. Aber das ist ja kein Speicherbaustein. Trotzdem kann ich das realisieren
Ebenso eine CPU - vielleicht könnte man Flop im Sinne dessen definieren, wie viel Speicher hat denn der FPGA? Flop ist Rechenleistung. Aber bezogen worauf. Ein FPGA hat zunächst keinen Prozessor. Wie gut ein Prozessor ist, hängt von der Anzahl der Bauteile ab.
Jetzt weiter den MIPS32, ich mache den Registersatz. Dann gehen wir ganz schnell zur Realisierung des MIPS32 vor und wie gesagt ich warte auf die Tastatur.
Mit den Flops bin ich mir aber nicht ganz sicher, es wäre aber eine Möglichkeit das aus zu drücken.
Jetzt mache ich das 32x32 Bit Registersatz - mit Kaskadierung.
Das war halt das Dumme und das was ich am Anfang gemacht habe, ich habe dann zwischendrin gemerkt, ich muss den Multiplexer, einfach kaskadieren. Dann bin ich dahinter gekommen, die Register auch. Jetzt hatte ich aber den Multiplexer, indem Fall, kein Demultiplexer, für das WE - an den Register, schon geschrieben, das muss ich neu machen.
Ich streiche jetzt einige Teile aus dem Quelltext. Nämlich die, wo ich den Multiplexer, für das Schreiberegister gemacht habe.
Nein, den lösche ich gar nicht, den brauche ich nachher, weil, ich habe ja noch 4 Multiplexer
Jetzt definiere ich erst mal den Registersatz mit zwei Registern. Einfach so, als wären das nur zwei Register.
Ich habe nach wie vor,
Code: Alles auswählen
read_data1,
read_data2
write_data
read_reg1
...
Code: Alles auswählen
-- dann habe ich das jetzt so weit definiert
entity regset2 is
port (
type asdasd is array (3 downto 0) of std_logic_vector;
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (4 downto 0);
read_reg2: in std_logic_vector (4 downto 0);
write_reg: in std_logic_vector (4 downto 0);
we: in std_logic
);
end;
Code: Alles auswählen
-- das ist denke ich falsch, weil, ich habe - read_reg... als 5 Bit deklariert, das ist ja bei zwei Registern nicht so. Ich kann erst Mal die Entities für alle Register aufschreiben.
weil, ich habe immer nur 1
Lesedaten-1/2
Und eine Auswahl. Das geht halt rein. Entsprechend, sind die als Component definiert, geht es halt in die eine oder andere
Also, ich definiere jetzt von der entity
2 Register Registersatz
4 Register Registersatz
8 ...
Code: Alles auswählen
-- das hat da nichts zu suchen
type asdasd is array (3 downto 0) of std_logic_vector;
Code: Alles auswählen
-- das sieht jetzt erst mal so aus
library ieee;
use ieee.std_logic_1164.all;
entity regset16 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (3 downto 0);
read_reg2: in std_logic_vector (3 downto 0);
write_reg: in std_logic_vector (3 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset32 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (4 downto 0);
read_reg2: in std_logic_vector (4 downto 0);
write_reg: in std_logic_vector (4 downto 0);
we: in std_logic
);
end;
Code: Alles auswählen
-- so jetzt habe ich das so gemacht
library ieee;
use ieee.std_logic_1164.all;
entity regset2 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector;
read_reg2: in std_logic_vector;
write_reg: in std_logic_vector;
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset4 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (1 downto 0);
read_reg2: in std_logic_vector (1 downto 0);
write_reg: in std_logic_vector (1 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset8 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (2 downto 0);
read_reg2: in std_logic_vector (2 downto 0);
write_reg: in std_logic_vector (2 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset16 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (3 downto 0);
read_reg2: in std_logic_vector (3 downto 0);
write_reg: in std_logic_vector (3 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset32 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (4 downto 0);
read_reg2: in std_logic_vector (4 downto 0);
write_reg: in std_logic_vector (4 downto 0);
we: in std_logic
);
end;
Zunächst vom 2x Register Registersatz
Wenn ich das habe, dann kommt das 4x Register Registersatz - und dann mache 2 Komponenten von 2x Register Registersatz und dann muss ich aussuchen, wird es an das eine geschickt oder das andere und das Bit wird mitübergeben, für das eine Register.
Code: Alles auswählen
-- ich glaube, das mache ich heute. Ich mache den Prozessor einfach vollständig fertig.
Code: Alles auswählen
-- jetzt sieht man das so weit.
entity regset2 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector;
read_reg2: in std_logic_vector;
write_reg: in std_logic_vector;
we: in std_logic
);
end;
architecture behaviour of regset2 is
component reg32
port (
we: in std_logic;
q: out std_logic_vector (31 downto 0);
d: in std_logic_vector (31 downto 0)
);
end component;
begin
reg1: reg32 PORT MAP ()
end;
Für das WE - wegen schreiberegister. Dafür brauche ich kein
32x2:1 MUX, weil hier reicht ein einfacher MUX 2x2:1
Gut, dann muss ich aber das WE - verbauen, das geht mit einem AND
Und das andere ist - dass ich jetzt oben im Quelltext gucken muss, ob ich den entsprechenden Registersatz habe.
Code: Alles auswählen
Ich habe hier schon den MUX - mit einer FOR Schleife gemacht
entity mux32x2_1 is
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end;
architecture behaviour of mux32x2_1 is
begin
l1:
for i in 0 to 31 generate
c (i) <= (a (i) and s) or (b (i) and not s);
end generate;
end;
Code: Alles auswählen
-- ich habe den 2 Bit Registersatz jetzt so definiert
library ieee;
use ieee.std_logic_1164.all;
entity regset2 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector;
read_reg2: in std_logic_vector;
write_reg: in std_logic_vector;
we: in std_logic
);
end;
architecture behaviour of regset2 is
component reg32
port (
we: in std_logic;
q: out std_logic_vector (31 downto 0);
d: in std_logic_vector (31 downto 0)
);
end component;
component mux32x2_1
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end component;
signal we1, we2: std_logic;
signal r_dat1: std_logic_vector (31 downto 0);
signal r_dat2: std_logic_vector (31 downto 0);
begin
reg1: reg32 PORT MAP (we=>we1, d=>write_data, q=>r_dat1);
reg2: reg32 PORT MAP (we=>we2, d=>write_data, q=>r_dat2);
m1: mux32x2_1 PORT MAP (a=>r_dat1, b=>r_dat2, c=>read_data1, s=>read_reg1);
m2: mux32x2_1 PORT MAP (a=>r_dat1, b=>r_dat2, c=>read_data2, s=>read_reg2);
we1 <= (write_reg and we);
we2 <= (not write_reg and we);
end;
Code: Alles auswählen
-- so wäre es jetzt richtig, jetzt brauche ich eine testbench.
Code: Alles auswählen
-- vorher rauche ich eine
OK, die Testbench wird wegen der 32 Bit jetzt schaurig. Aber gut, man muss.
Ich habe ja schon das 32 Bit Register gestestet, insofern stehen schon mal daten da. Dann kann ich das analysieren.
Da ist noch ein gravierender Fehler drin, ich mache für heute erst Mal pause, ich poste das jetzt, auch auf meiner Homepage. Dann lerne ich weiter.
Code: Alles auswählen
library ieee;
use ieee.std_logic_1164.all;
entity rslatch is
port (
r, s: in std_logic;
q: out std_logic
);
end;
architecture verhalten of rslatch is
signal q1, q2: std_logic;
signal init: std_logic;
begin
init <= '0' after 0 ns, '1' after 1 ns;
q1 <= '1' when (init='0') else
(q2 nor r);
q2 <= '0' when (init='0') else
(q1 nor s);
q <= q1;
end;
library ieee;
use ieee.std_logic_1164.all;
entity clockcontrolledrslatch is
port (
r, s: in std_logic;
c: in std_logic;
q: out std_logic
);
end;
architecture behaviour of clockcontrolledrslatch is
component rslatch
port (
r, s: in std_logic;
q: out std_logic
);
end component;
signal r1, s1: std_logic;
begin
rslatch1: rslatch PORT MAP (r=>r1, s=>s1, q=>q);
s1 <= (s and c);
r1 <= (r and c);
end;
library ieee;
use ieee.std_logic_1164.all;
entity dlatch is
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end;
architecture behaviour of dlatch is
component clockcontrolledrslatch
port (
r, s: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
signal r1, s1: std_logic;
begin
clockcontrolledrslatch1: clockcontrolledrslatch PORT MAP (r=>r1, s=>s1, q=>q, c=>c);
s1 <= not d;
r1 <= d;
end;
library ieee;
use ieee.std_logic_1164.all;
entity dmsflipflop is
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end;
architecture behaviour of dmsflipflop is
component dlatch
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
signal d1, d2: std_logic;
signal c1, c2: std_logic;
signal q1, q2: std_logic;
begin
dlatch1: dlatch PORT MAP (d=>d1, c=>c1, q=>q1);
dlatch2: dlatch PORT MAP (d=>d2, c=>c2, q=>q2);
c1 <= c;
c2 <= not c;
d1 <= d;
d2 <= q1;
q <= q2;
end;
library ieee;
use ieee.std_logic_1164.all;
entity flipfloptestbench is
port (
q: out std_logic
);
end;
architecture behaviour of flipfloptestbench is
component dmsflipflop
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
signal d, c: std_logic;
begin
dmsflipflop1: dmsflipflop PORT MAP (q=>q, d=>d, c=>c);
c <= '0' after 0 ns, '1' after 20 ns, '0' after 40 ns, '1' after 60 ns, '0' after 80 ns, '1' after 100 ns, '0' after 120 ns, '1' after 140 ns,
'0' after 160 ns, '1' after 180 ns, '0' after 200 ns, '1' after 220 ns, '0' after 240 ns,
'1' after 260 ns, '0' after 280 ns, '1' after 300 ns, '0' after 320 ns, '1' after 340 ns;
d <= '0' after 0 ns, '1' after 150 ns, '0' after 250 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
entity reg32 is
port (
we: in std_logic;
q: out std_logic_vector (31 downto 0);
d: in std_logic_vector (31 downto 0)
);
end;
architecture behaviour of reg32 is
component dmsflipflop
port (
d: in std_logic;
c: in std_logic;
q: out std_logic
);
end component;
begin
l1:
for i in 0 to 31 generate
dmsflipflop1: dmsflipflop PORT MAP (q=>q(i), d=>d(i), c=>we);
end generate;
end;
library ieee;
use ieee.std_logic_1164.all;
entity reg32testbench is
port (
q: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of reg32testbench is
component reg32
port (
d: in std_logic_vector (31 downto 0);
we: in std_logic;
q: out std_logic_vector (31 downto 0)
);
end component;
signal d: std_logic_vector (31 downto 0);
signal we: std_logic;
begin
reg32a: reg32 PORT MAP (d=>d, q=>q, we=>we);
d(0) <= '1';
d(1) <= '0';
d(2) <= '1';
d(3) <= '0';
d(4) <= '1';
d(5) <= '0';
d(6) <= '1';
d(7) <= '0';
d(8) <= '1';
d(9) <= '1';
d(10) <= '0';
d(11) <= '1';
d(12) <= '0';
d(13) <= '1';
d(14) <= '0';
d(15) <= '1';
d(16) <= '0';
d(17) <= '1';
d(18) <= '0';
d(19) <= '1';
d(20) <= '0';
d(21) <= '1';
d(22) <= '0';
d(23) <= '1';
d(24) <= '0';
d(25) <= '1';
d(26) <= '0';
d(27) <= '1';
d(28) <= '0';
d(29) <= '1';
d(30) <= '0';
d(31) <= '1';
we <= '0' after 0 ns, '1' after 10 ns, '0' after 20 ns, '1' after 30 ns, '0' after 40 ns, '1' after 60 ns, '0' after 80 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
entity mux32x2_1 is
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end;
architecture behaviour of mux32x2_1 is
begin
l1:
for i in 0 to 31 generate
c (i) <= (a (i) and s) or (b (i) and not s);
end generate;
end;
library ieee;
use ieee.std_logic_1164.all;
entity mux32x2_1testbench is
port (
c: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of mux32x2_1testbench is
component mux32x2_1
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end component;
signal a: std_logic_vector (31 downto 0);
signal b: std_logic_vector (31 downto 0);
signal s: std_logic;
begin
m: mux32x2_1 PORT MAP (b=>b, a=>a, c=>c, s=>s);
a (0) <= '0';
a (1) <= '1';
a (2) <= '0';
a (3) <= '1';
a (4) <= '0';
a (5) <= '0';
a (6) <= '1';
a (7) <= '0';
a (8) <= '1';
a (9) <= '0';
a (10) <= '1';
a (11) <= '0';
a (12) <= '1';
a (13) <= '0';
a (14) <= '1';
a (15) <= '0';
a (16) <= '1';
a (17) <= '0';
a (18) <= '1';
a (19) <= '0';
a (20) <= '1';
a (21) <= '0';
a (22) <= '1';
a (23) <= '0';
a (24) <= '1';
a (25) <= '0';
a (26) <= '1';
a (27) <= '0';
a (28) <= '1';
a (29) <= '0';
a (30) <= '1';
a (31) <= '1';
b (0) <= '0';
b (1) <= '0';
b (2) <= '0';
b (3) <= '1';
b (4) <= '0';
b (5) <= '1';
b (6) <= '0';
b (7) <= '0';
b (8) <= '1';
b (9) <= '0';
b (10) <= '1';
b (11) <= '0';
b (12) <= '0';
b (13) <= '0';
b (14) <= '1';
b (15) <= '0';
b (16) <= '0';
b (17) <= '1';
b (18) <= '1';
b (19) <= '0';
b (20) <= '1';
b (21) <= '0';
b (22) <= '0';
b (23) <= '1';
b (24) <= '1';
b (25) <= '0';
b (26) <= '1';
b (27) <= '0';
b (28) <= '1';
b (29) <= '0';
b (30) <= '1';
b (31) <= '1';
s <= '0' after 0 ns, '1' after 10 ns, '0' after 20 ns;
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset2 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic;
read_reg2: in std_logic;
write_reg: in std_logic;
we: in std_logic
);
end;
architecture behaviour of regset2 is
component reg32
port (
we: in std_logic;
q: out std_logic_vector (31 downto 0);
d: in std_logic_vector (31 downto 0)
);
end component;
component mux32x2_1
port (
b: in std_logic_vector (31 downto 0);
a: in std_logic_vector (31 downto 0);
c: out std_logic_vector (31 downto 0);
s: in std_logic
);
end component;
signal we1, we2: std_logic;
signal r_dat1: std_logic_vector (31 downto 0);
signal r_dat2: std_logic_vector (31 downto 0);
begin
reg1: reg32 PORT MAP (we=>we1, d=>write_data, q=>r_dat1);
reg2: reg32 PORT MAP (we=>we2, d=>write_data, q=>r_dat2);
m1: mux32x2_1 PORT MAP (a=>r_dat1, b=>r_dat2, c=>read_data1, s=>read_reg1);
m2: mux32x2_1 PORT MAP (a=>r_dat1, b=>r_dat2, c=>read_data2, s=>read_reg2);
we1 <= (write_reg and we);
we2 <= (not write_reg and we);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset2testbench is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0)
);
end;
architecture behaviour of regset2testbench is
component regset2
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic;
read_reg2: in std_logic;
write_reg: in std_logic;
we: in std_logic
);
end component;
signal write_data: std_logic_vector (31 downto 0);
signal read_reg1: std_logic;
signal read_reg2: std_logic;
signal write_reg: std_logic;
signal we: std_logic;
begin
rset1: regset2 PORT MAP (read_data1=>read_data1, read_data2=>read_data2, write_data=>write_data, read_reg1=>read_reg1, read_reg2=>read_reg2, write_reg=>write_reg, we=>we);
we <= '0' after 0 ns, '1' after 1 ns, '0' after 4 ns;
write_reg <= '0' after 0 ns;
read_reg1 <= '0' after 0 ns;
write_data (0) <= '0';
write_data (1) <= '1';
write_data (2) <= '0';
write_data (3) <= '1';
write_data (4) <= '0';
write_data (31) <= '1';
write_data (5) <= '0';
write_data (6) <= '1';
write_data (7) <= '0';
write_data (8) <= '1';
write_data (9) <= '0';
write_data (10) <= '1';
write_data (11) <= '0';
write_data (12) <= '1';
write_data (13) <= '0';
write_data (14) <= '1';
write_data (15) <= '0';
write_data (16) <= '1';
write_data (17) <= '0';
write_data (18) <= '1';
write_data (19) <= '0';
write_data (20) <= '1';
write_data (21) <= '0';
write_data (22) <= '1';
write_data (23) <= '0';
write_data (24) <= '1';
write_data (25) <= '0';
write_data (26) <= '1';
write_data (27) <= '0';
write_data (28) <= '1';
write_data (29) <= '0';
write_data (30) <= '1';
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset4 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (1 downto 0);
read_reg2: in std_logic_vector (1 downto 0);
write_reg: in std_logic_vector (1 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset8 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (2 downto 0);
read_reg2: in std_logic_vector (2 downto 0);
write_reg: in std_logic_vector (2 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset16 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (3 downto 0);
read_reg2: in std_logic_vector (3 downto 0);
write_reg: in std_logic_vector (3 downto 0);
we: in std_logic
);
end;
library ieee;
use ieee.std_logic_1164.all;
entity regset32 is
port (
read_data1: out std_logic_vector (31 downto 0);
read_data2: out std_logic_vector (31 downto 0);
write_data: in std_logic_vector (31 downto 0);
read_reg1: in std_logic_vector (4 downto 0);
read_reg2: in std_logic_vector (4 downto 0);
write_reg: in std_logic_vector (4 downto 0);
we: in std_logic
);
end;