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[/] [z80soc/] [trunk/] [V0.7.2/] [DE1/] [vhdl/] [top_de1.vhd.bak] - Rev 46
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-------------------------------------------------------------------------------------------------
-- Z80SoC (Z80 System on Chip)
-- Ronivon Candido Costa
-- ronivon.costa@gmail.com
--
-- Version history:
-------------------
-- version 0.7.1
-- 2010 / 11 / 22
-- Change memory layout and increased Rom, using Megawizard plug in manager
-- Memory cores redefined
-- Fixed bug in the video.vhd
-- New rom demo in C (SDCC)
--
-- version 0.7
-- Release Date: 2010 / 02 / 17
-- version 0.6 for for Altera DE1
-- Release Date: 2008 / 05 / 21
--
-- Version 0.5 Beta for Altera DE1
-- Developer: Ronivon Candido Costa
-- Release Date: 2008 / 04 / 16
--
-- Based on the T80 core: http://www.opencores.org/projects.cgi/web/t80
-- This version developed and tested on: Altera DE1 Development Board
--
-- Peripherals configured (Using Ports):
--
-- 16 KB Internal ROM Read (0x0000h - 0x3FFFh)
-- 08 KB INTERNAL VRAM Write (0x4000h - 0x5FFFh)
-- 32 KB External SRAM Read/Write (0x8000h - 0xFFFFh)
-- 08 Green Leds Out (Port 0x01h)
-- 08 Red Leds Out (Port 0x02h)
-- 04 Seven Seg displays Out (Ports 0x11h and 0x10h)
-- 36 Pins GPIO0 In/Out (Ports 0xA0h, 0xA1h, 0xA2h, 0xA3h, 0xA4h, 0xC0h)
-- 36 Pins GPIO1 In/Out (Ports 0xB0h, 0xB1h, 0xB2h, 0xB3h, 0xB4h, 0xC1h)
-- 08 Switches In (Port 0x20h)
-- 04 Push buttons In (Port 0x30h)
-- 01 PS/2 keyboard In (Port 0x80h)
-- 01 Video write port In (Port 0x90h)
--
-- Revision history:
--
-- 2008/05/23 - Modified RAM layout to support new and future improvements
-- - Added port 0x90 to write a character to video.
-- - Cursor x,y automatically updated after writing to port 0x90
-- - Added port 0x91 for video cursor X
-- - Added port 0x92 for video cursor Y
-- - Updated ROM to demonstrate how to use these new resources
-- - Changed ROM to support 14 bit addresses (16 Kb)
--
-- 2008/05/12 - Added support for the Rotary Knob
-- - ROT_CENTER push button (Knob) reserved for RESET
-- - The four push buttons are now available for the user (Port 0x30)
--
-- 2008/05/11 - Fixed access to RAM and VRAM,
-- Released same ROM version for DE1 and S3E
--
-- 2008/05/01 - Added LCD support for Spartan 3E
--
-- 2008/04(21 - Release of Version 0.5-S3E-Beta for Diligent Spartan 3E
--
-- 2008/04/17 - Added Video support for 40x30 mode
--
-- 2008/04/16 - Release of Version 0.5-DE1-Beta for Altera DE1
--
-- TO-DO:
-- - Implement hardware control for the A/D and IO pins
-- - Monitor program to introduce Z80 Assmebly codes and run
-- - Serial communication, to download assembly code from PC
-- - Add hardware support for 80x40 Video out
-- - SD/MMC card interface to read/store data and programs
-------------------------------------------------------------------------------------------------
library IEEE;
use IEEE.std_logic_1164.all;
use IEEE.std_logic_arith.all;
use IEEE.std_logic_unsigned.all;
entity TOP_DE1 is
port(
-- Clocks
CLOCK_27, -- 27 MHz
CLOCK_50, -- 50 MHz
EXT_CLOCK : in std_logic; -- External Clock
-- Buttons and switches
KEY : in std_logic_vector(3 downto 0); -- Push buttons
SW : in std_logic_vector(9 downto 0); -- Switches
-- LED displays
HEX0, HEX1, HEX2, HEX3 -- 7-segment displays
: out std_logic_vector(6 downto 0);
LEDG : out std_logic_vector(7 downto 0); -- Green LEDs
LEDR : out std_logic_vector(9 downto 0); -- Red LEDs
-- RS-232 interface
UART_TXD : out std_logic; -- UART transmitter
UART_RXD : in std_logic; -- UART receiver
-- IRDA interface
-- IRDA_TXD : out std_logic; -- IRDA Transmitter
IRDA_RXD : in std_logic; -- IRDA Receiver
-- SDRAM
DRAM_DQ : inout std_logic_vector(15 downto 0); -- Data Bus
DRAM_ADDR : out std_logic_vector(11 downto 0); -- Address Bus
DRAM_LDQM, -- Low-byte Data Mask
DRAM_UDQM, -- High-byte Data Mask
DRAM_WE_N, -- Write Enable
DRAM_CAS_N, -- Column Address Strobe
DRAM_RAS_N, -- Row Address Strobe
DRAM_CS_N, -- Chip Select
DRAM_BA_0, -- Bank Address 0
DRAM_BA_1, -- Bank Address 0
DRAM_CLK, -- Clock
DRAM_CKE : out std_logic; -- Clock Enable
-- FLASH
FL_DQ : inout std_logic_vector(7 downto 0); -- Data bus
FL_ADDR : out std_logic_vector(21 downto 0); -- Address bus
FL_WE_N, -- Write Enable
FL_RST_N, -- Reset
FL_OE_N, -- Output Enable
FL_CE_N : out std_logic; -- Chip Enable
-- SRAM
SRAM_DQ : inout std_logic_vector(15 downto 0); -- Data bus 16 Bits
SRAM_ADDR : out std_logic_vector(17 downto 0); -- Address bus 18 Bits
SRAM_UB_N, -- High-byte Data Mask
SRAM_LB_N, -- Low-byte Data Mask
SRAM_WE_N, -- Write Enable
SRAM_CE_N, -- Chip Enable
SRAM_OE_N : out std_logic; -- Output Enable
-- SD card interface
SD_DAT : in std_logic; -- SD Card Data SD pin 7 "DAT 0/DataOut"
SD_DAT3 : out std_logic; -- SD Card Data 3 SD pin 1 "DAT 3/nCS"
SD_CMD : out std_logic; -- SD Card Command SD pin 2 "CMD/DataIn"
SD_CLK : out std_logic; -- SD Card Clock SD pin 5 "CLK"
-- USB JTAG link
TDI, -- CPLD -> FPGA (data in)
TCK, -- CPLD -> FPGA (clk)
TCS : in std_logic; -- CPLD -> FPGA (CS)
TDO : out std_logic; -- FPGA -> CPLD (data out)
-- I2C bus
I2C_SDAT : inout std_logic; -- I2C Data
I2C_SCLK : out std_logic; -- I2C Clock
-- PS/2 port
PS2_DAT, -- Data
PS2_CLK : inout std_logic; -- Clock
-- VGA output
VGA_HS, -- H_SYNC
VGA_VS : out std_logic; -- SYNC
VGA_R, -- Red[3:0]
VGA_G, -- Green[3:0]
VGA_B : out std_logic_vector(3 downto 0); -- Blue[3:0]
-- Audio CODEC
AUD_ADCLRCK : inout std_logic; -- ADC LR Clock
AUD_ADCDAT : in std_logic; -- ADC Data
AUD_DACLRCK : inout std_logic; -- DAC LR Clock
AUD_DACDAT : out std_logic; -- DAC Data
AUD_BCLK : inout std_logic; -- Bit-Stream Clock
AUD_XCK : out std_logic; -- Chip Clock
-- General-purpose I/O
GPIO_0, -- GPIO Connection 0
GPIO_1 : inout std_logic_vector(35 downto 0) -- GPIO Connection 1
);
end TOP_DE1;
architecture rtl of TOP_DE1 is
use work.z80soc_pack.all;
component T80se
generic(
Mode : integer := 0; -- 0 => Z80, 1 => Fast Z80, 2 => 8080, 3 => GB
T2Write : integer := 1; -- 0 => WR_n active in T3, /=0 => WR_n active in T2
IOWait : integer := 1 -- 0 => Single cycle I/O, 1 => Std I/O cycle
);
port(
RESET_n : in std_logic;
CLK_n : in std_logic;
CLKEN : in std_logic;
WAIT_n : in std_logic;
INT_n : in std_logic;
NMI_n : in std_logic;
BUSRQ_n : in std_logic;
M1_n : out std_logic;
MREQ_n : out std_logic;
IORQ_n : out std_logic;
RD_n : out std_logic;
WR_n : out std_logic;
RFSH_n : out std_logic;
HALT_n : out std_logic;
BUSAK_n : out std_logic;
A : out std_logic_vector(15 downto 0);
DI : in std_logic_vector(7 downto 0);
DO : out std_logic_vector(7 downto 0)
);
end component;
component rom
port (
clock : in std_logic;
address : in std_logic_vector(14 downto 0);
q : out std_logic_vector(7 downto 0));
end component;
component Clock_357Mhz
PORT (
clock_50Mhz : IN STD_LOGIC;
clock_357Mhz : OUT STD_LOGIC);
end component;
component clk_div
PORT
(
clock_25Mhz : IN STD_LOGIC;
clock_1MHz : OUT STD_LOGIC;
clock_100KHz : OUT STD_LOGIC;
clock_10KHz : OUT STD_LOGIC;
clock_1KHz : OUT STD_LOGIC;
clock_100Hz : OUT STD_LOGIC;
clock_10Hz : OUT STD_LOGIC;
clock_1Hz : OUT STD_LOGIC);
end component;
component decoder_7seg
port (
NUMBER : in std_logic_vector(3 downto 0);
HEX_DISP : out std_logic_vector(6 downto 0));
end component;
component ps2kbd
port (
keyboard_clk : inout std_logic;
keyboard_data : inout std_logic;
clock : in std_logic;
clkdelay : in std_logic;
reset : in std_logic;
read : in std_logic;
scan_ready : out std_logic;
ps2_ascii_code : out std_logic_vector(7 downto 0));
end component;
component vram3200x8
port
(
rdaddress : IN STD_LOGIC_VECTOR (12 DOWNTO 0);
wraddress : IN STD_LOGIC_VECTOR (12 DOWNTO 0);
rdclock : IN STD_LOGIC;
wrclock : IN STD_LOGIC;
data : IN STD_LOGIC_VECTOR (7 DOWNTO 0);
wren : IN STD_LOGIC;
q : OUT STD_LOGIC_VECTOR (7 DOWNTO 0)
);
end component;
component charram2k
port (
data : IN STD_LOGIC_VECTOR (7 DOWNTO 0);
rdaddress : IN STD_LOGIC_VECTOR (10 DOWNTO 0);
rdclock : IN STD_LOGIC ;
wraddress : IN STD_LOGIC_VECTOR (10 DOWNTO 0);
wrclock : IN STD_LOGIC;
wren : IN STD_LOGIC;
q : OUT STD_LOGIC_VECTOR (7 DOWNTO 0));
end component;
COMPONENT video
PORT (
CLOCK_25 : IN STD_LOGIC;
VRAM_DATA : IN STD_LOGIC_VECTOR(7 DOWNTO 0);
VRAM_ADDR : OUT STD_LOGIC_VECTOR(13 DOWNTO 0);
VRAM_CLOCK : OUT STD_LOGIC;
VRAM_WREN : OUT STD_LOGIC;
CRAM_DATA : IN STD_LOGIC_VECTOR(7 DOWNTO 0);
CRAM_ADDR : OUT STD_LOGIC_VECTOR(10 DOWNTO 0);
CRAM_WEB : OUT STD_LOGIC;
VGA_R,
VGA_G,
VGA_B : OUT STD_LOGIC_VECTOR(3 DOWNTO 0);
VGA_HS,
VGA_VS : OUT STD_LOGIC);
END COMPONENT;
COMPONENT video_PLL
PORT
(
inclk0 : IN STD_LOGIC := '0';
c0 : OUT STD_LOGIC
);
END COMPONENT;
signal MREQ_n : std_logic;
signal IORQ_n : std_logic;
signal RD_n : std_logic;
signal WR_n : std_logic;
signal MWr_n : std_logic;
signal Rst_n_s : std_logic;
signal Clk_Z80 : std_logic;
signal DI_CPU : std_logic_vector(7 downto 0);
signal DO_CPU : std_logic_vector(7 downto 0);
signal A : std_logic_vector(15 downto 0);
signal One : std_logic;
signal D_ROM : std_logic_vector(7 downto 0);
signal rom_data : std_logic_vector(7 downto 0);
signal rom_wren : std_logic;
signal clk25mhz : std_logic;
signal clk100hz : std_logic;
signal clk10hz : std_logic;
signal clk1hz : std_logic;
signal HEX_DISP0 : std_logic_vector(6 downto 0);
signal HEX_DISP1 : std_logic_vector(6 downto 0);
signal HEX_DISP2 : std_logic_vector(6 downto 0);
signal HEX_DISP3 : std_logic_vector(6 downto 0);
signal NUMBER0 : std_logic_vector(3 downto 0);
signal NUMBER1 : std_logic_vector(3 downto 0);
signal NUMBER2 : std_logic_vector(3 downto 0);
signal NUMBER3 : std_logic_vector(3 downto 0);
signal GPIO_0_buf_in : std_logic_vector(35 downto 0);
signal GPIO_1_buf_in : std_logic_vector(35 downto 0);
signal vram_addra : std_logic_vector(15 downto 0);
signal vram_addrb : std_logic_vector(13 downto 0);
signal vram_dina : std_logic_vector(7 downto 0);
signal vram_dinb : std_logic_vector(7 downto 0);
signal vram_douta : std_logic_vector(7 downto 0);
signal vram_doutb : std_logic_vector(7 downto 0);
signal vram_wea : std_logic;
signal vram_web : std_logic;
signal vram_clka : std_logic;
signal vram_clkb : std_logic;
-- signal vram_douta_reg : std_logic_vector(7 downto 0);
signal cram_addra : std_logic_vector(15 downto 0);
signal cram_addrb : std_logic_vector(15 downto 0);
signal cram_dina : std_logic_vector(7 downto 0);
signal cram_dinb : std_logic_vector(7 downto 0);
signal cram_douta : std_logic_vector(7 downto 0);
signal cram_doutb : std_logic_vector(7 downto 0);
signal cram_wea : std_logic;
signal cram_web : std_logic;
signal cram_clka : std_logic;
signal cram_clkb : std_logic;
-- PS/2 Keyboard
signal ps2_read : std_logic;
signal ps2_scan_ready : std_logic;
signal ps2_ascii_sig : std_logic_vector(7 downto 0);
signal ps2_ascii_reg1 : std_logic_vector(7 downto 0);
signal ps2_ascii_reg : std_logic_vector(7 downto 0);
signal Z80SOC_VERSION : std_logic_vector(2 downto 0); -- "000" = DE1, "001" = S3E
begin
Z80SOC_VERSION <= "000"; -- "000" = DE1, "001" = S3E
Rst_n_s <= not SW(9);
HEX0 <= HEX_DISP0;
HEX1 <= HEX_DISP1;
HEX2 <= HEX_DISP2;
HEX3 <= HEX_DISP3;
-- Write into VRAM
vram_addra <= A - x"4000";
vram_dina <= DO_CPU;
vram_wea <= '0' when (A >= x"4000" and A < x"5800" and Wr_n = '0' and MReq_n = '0') else
'1';
-- Write into char ram
cram_addra <= A - x"5800";
cram_dina <= DO_CPU;
cram_wea <= '0' when (A >= x"5800" and A < x"6000" and Wr_n = '0' and MReq_n = '0') else '1';
-- SRAM control signals
-- SRAM will store data for video, characters patterns and RAM (only on DE1 version)
-- Due to limitation in dual-port block rams on this platform
--
SRAM_CE_N <= '0';
SRAM_ADDR(15 downto 0) <= A - x"4000";
SRAM_DQ(7 downto 0) <= DO_CPU when (Wr_n = '0' and MREQ_n = '0' and A >= x"4000") else
(others => 'Z');
SRAM_WE_N <= '0' when (Wr_n = '0' and MREQ_n = '0' and A >= x"4000") else
'1';
SRAM_OE_N <= '0' when (Rd_n = '0' and MREQ_n = '0' and A >= x"4000") else
'Z';
-- Input to Z80
DI_CPU <= ("00000" & Z80SOC_VERSION) when (Rd_n = '0' and MREQ_n = '0' and A = x"52C0") else
D_ROM when (Rd_n = '0' and MREQ_n = '0' and IORQ_n = '1' and A < x"4000") else
SRAM_DQ(7 downto 0) when (Rd_n = '0' and MREQ_n = '0' and IORQ_n = '1' and A >= x"4000") else
SW(7 downto 0) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"20") else
("0000" & not KEY) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"30") else
GPIO_0(7 downto 0) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"A0") else
GPIO_0(15 downto 8) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"A1") else
GPIO_0(23 downto 16) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"A2") else
GPIO_0(31 downto 24) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"A3") else
("0000" & GPIO_0(35 downto 32)) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"A4") else
GPIO_1(7 downto 0) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"B0") else
GPIO_1(15 downto 8) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"B1") else
GPIO_1(23 downto 16) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"B2") else
GPIO_1(31 downto 24) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"B3") else
("0000" & GPIO_1(35 downto 32)) when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"B4") else
ps2_ascii_reg when (IORQ_n = '0' and MREQ_n = '1' and Rd_n = '0' and A(7 downto 0) = x"80") else
"ZZZZZZZZ";
-- Process to latch leds and hex displays
pinout_process: process(Clk_Z80)
variable NUMBER0_sig : std_logic_vector(3 downto 0);
variable NUMBER1_sig : std_logic_vector(3 downto 0);
variable NUMBER2_sig : std_logic_vector(3 downto 0);
variable NUMBER3_sig : std_logic_vector(3 downto 0);
variable LEDG_sig : std_logic_vector(7 downto 0);
variable LEDR_sig : std_logic_vector(9 downto 0);
variable GPIO_0_buf_out: std_logic_vector(35 downto 0);
variable GPIO_1_buf_out: std_logic_vector(35 downto 0);
begin
if Clk_Z80'event and Clk_Z80 = '1' then
if IORQ_n = '0' and MREQ_n = '1' and Wr_n = '0' then
-- LEDG
if A(7 downto 0) = x"01" then
LEDG_sig := DO_CPU;
-- LEDR
elsif A(7 downto 0) = x"02" then
LEDR_sig(7 downto 0) := DO_CPU;
-- HEX1 and HEX0
elsif A(7 downto 0) = x"10" then
NUMBER2_sig := DO_CPU(3 downto 0);
NUMBER3_sig := DO_CPU(7 downto 4);
-- HEX3 and HEX2
elsif A(7 downto 0) = x"11" then
NUMBER0_sig := DO_CPU(3 downto 0);
NUMBER1_sig := DO_CPU(7 downto 4);
-- GPIO_0
elsif A(7 downto 0) = x"A0" then
GPIO_0_buf_out(7 downto 0) := DO_CPU;
elsif A(7 downto 0) = x"A1" then
GPIO_0_buf_out(15 downto 8) := DO_CPU;
elsif A(7 downto 0) = x"A2" then
GPIO_0_buf_out(23 downto 16) := DO_CPU;
elsif A(7 downto 0) = x"A3" then
GPIO_0_buf_out(31 downto 24) := DO_CPU;
elsif A(7 downto 0) = x"A4" then
GPIO_0_buf_out(35 downto 32) := DO_CPU(3 downto 0);
-- GPIO_1
elsif A(7 downto 0) = x"B0" then
GPIO_1_buf_out(7 downto 0) := DO_CPU;
elsif A(7 downto 0) = x"B1" then
GPIO_1_buf_out(15 downto 8) := DO_CPU;
elsif A(7 downto 0) = x"B2" then
GPIO_1_buf_out(23 downto 16) := DO_CPU;
elsif A(7 downto 0) = x"B3" then
GPIO_1_buf_out(31 downto 24) := DO_CPU;
elsif A(7 downto 0) = x"B4" then
GPIO_1_buf_out(35 downto 32) := DO_CPU(3 downto 0);
elsif A(7 downto 0) = x"C0" then
GPIO_0 <= GPIO_0_buf_out;
elsif A(7 downto 0) = x"C1" then
GPIO_1 <= GPIO_1_buf_out;
end if;
end if;
end if;
-- Latches the signals
NUMBER0 <= NUMBER0_sig;
NUMBER1 <= NUMBER1_sig;
NUMBER2 <= NUMBER2_sig;
NUMBER3 <= NUMBER3_sig;
LEDR(7 downto 0) <= LEDR_sig(7 downto 0);
LEDG <= LEDG_sig;
end process;
-- the following three processes deals with different clock domain signals
ps2_process1: process(CLOCK_50)
begin
if CLOCK_50'event and CLOCK_50 = '1' then
if ps2_read = '1' then
if ps2_ascii_sig /= x"FF" then
ps2_read <= '0';
ps2_ascii_reg1 <= "00000000";
end if;
elsif ps2_scan_ready = '1' then
if ps2_ascii_sig = x"FF" then
ps2_read <= '1';
else
ps2_ascii_reg1 <= ps2_ascii_sig;
end if;
end if;
end if;
end process;
ps2_process2: process(Clk_Z80)
begin
if Clk_Z80'event and Clk_Z80 = '1' then
ps2_ascii_reg <= ps2_ascii_reg1;
end if;
end process;
One <= '1';
z80_inst: T80se
port map (
M1_n => open,
MREQ_n => MREQ_n,
IORQ_n => IORQ_n,
RD_n => Rd_n,
WR_n => Wr_n,
RFSH_n => open,
HALT_n => open,
WAIT_n => One,
INT_n => One,
NMI_n => One,
RESET_n => Rst_n_s,
BUSRQ_n => One,
BUSAK_n => open,
CLK_n => Clk_Z80,
CLKEN => One,
A => A,
DI => DI_CPU,
DO => DO_CPU
);
video_inst: video port map (
CLOCK_25 => clk25mhz,
VRAM_DATA => vram_doutb,
VRAM_ADDR => vram_addrb(13 downto 0),
VRAM_CLOCK => vram_clkb,
VRAM_WREN => vram_web,
CRAM_DATA => cram_doutb,
CRAM_ADDR => cram_addrb(10 downto 0),
CRAM_WEB => cram_web,
VGA_R => VGA_R,
VGA_G => VGA_G,
VGA_B => VGA_B,
VGA_HS => VGA_HS,
VGA_VS => VGA_VS
);
vram : vram3200x8
port map (
rdclock => vram_clkb,
wrclock => Clk_Z80,
wren => not vram_wea, -- inverted logic so code is similar to SRAM and S3E port
wraddress => vram_addra(12 downto 0),
rdaddress => vram_addrb(12 downto 0),
data => vram_dina,
q => vram_doutb
);
cram: charram2k
port map (
rdaddress => cram_addrb(10 downto 0),
wraddress => cram_addra(10 downto 0),
wrclock => Clk_Z80,
rdclock => vram_clkb,
data => cram_dina,
q => cram_doutb,
wren => NOT cram_wea
);
rom_inst: rom
port map (
clock => clk25mhz,
address => A(14 downto 0),
q => D_ROM
);
-- PLL below is used to generate the pixel clock frequency
-- Uses DE1 50Mhz clock for PLL's input clock
video_PLL_inst: video_PLL
port map (
inclk0 => CLOCK_50,
c0 => clk25mhz
);
clkdiv_inst: clk_div
port map (
clock_25Mhz => clk25mhz,
clock_1MHz => open,
clock_100KHz => open,
clock_10KHz => open,
clock_1KHz => open,
clock_100Hz => clk100hz,
clock_10Hz => clk10hz,
clock_1Hz => clk1hz
);
clock_z80_inst : Clock_357Mhz
port map (
clock_50Mhz => CLOCK_50,
clock_357Mhz => Clk_Z80
);
DISPHEX0 : decoder_7seg PORT MAP (
NUMBER => NUMBER0,
HEX_DISP => HEX_DISP0
);
DISPHEX1 : decoder_7seg PORT MAP (
NUMBER => NUMBER1,
HEX_DISP => HEX_DISP1
);
DISPHEX2 : decoder_7seg PORT MAP (
NUMBER => NUMBER2,
HEX_DISP => HEX_DISP2
);
DISPHEX3 : decoder_7seg PORT MAP (
NUMBER => NUMBER3,
HEX_DISP => HEX_DISP3
);
ps2_kbd_inst : ps2kbd PORT MAP (
keyboard_clk => PS2_CLK,
keyboard_data => PS2_DAT,
clock => CLOCK_50,
clkdelay => clk100hz,
reset => Rst_n_s,
read => ps2_read,
scan_ready => ps2_scan_ready,
ps2_ascii_code => ps2_ascii_sig
);
--
SRAM_DQ(15 downto 8) <= (others => 'Z');
SRAM_ADDR(17 downto 16) <= "00";
SRAM_UB_N <= '1';
SRAM_LB_N <= '0';
--
UART_TXD <= 'Z';
DRAM_ADDR <= (others => '0');
DRAM_LDQM <= '0';
DRAM_UDQM <= '0';
DRAM_WE_N <= '1';
DRAM_CAS_N <= '1';
DRAM_RAS_N <= '1';
DRAM_CS_N <= '1';
DRAM_BA_0 <= '0';
DRAM_BA_1 <= '0';
DRAM_CLK <= '0';
DRAM_CKE <= '0';
FL_ADDR <= (others => '0');
FL_WE_N <= '1';
FL_RST_N <= '0';
FL_OE_N <= '1';
FL_CE_N <= '1';
TDO <= '0';
I2C_SCLK <= '0';
AUD_DACDAT <= '0';
AUD_XCK <= '0';
-- Set all bidirectional ports to tri-state
DRAM_DQ <= (others => 'Z');
FL_DQ <= (others => 'Z');
I2C_SDAT <= 'Z';
AUD_ADCLRCK <= 'Z';
AUD_DACLRCK <= 'Z';
AUD_BCLK <= 'Z';
GPIO_0 <= (others => 'Z');
GPIO_1 <= (others => 'Z');
end;
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