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Activated F2 and F3 IIR Filters for LFR_FILTERS tests....
Activated F2 and F3 IIR Filters for LFR_FILTERS tests. Improved Makefiles for LFR_FILTERS tests.

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TB.vhd
688 lines | 33.5 KiB | text/x-vhdl | VhdlLexer
------------------------------------------------------------------------------
-- This file is a part of the LPP VHDL IP LIBRARY
-- Copyright (C) 2009 - 2010, Laboratory of Plasmas Physic - CNRS
--
-- This program is free software; you can redistribute it and/or modify
-- it under the terms of the GNU General Public License as published by
-- the Free Software Foundation; either version 3 of the License, or
-- (at your option) any later version.
--
-- This program is distributed in the hope that it will be useful,
-- but WITHOUT ANY WARRANTY; without even the implied warranty of
-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
-- GNU General Public License for more details.
--
-- You should have received a copy of the GNU General Public License
-- along with this program; if not, write to the Free Software
-- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
-------------------------------------------------------------------------------
-- Author : Jean-christophe Pellion
-- Mail : jean-christophe.pellion@lpp.polytechnique.fr
-------------------------------------------------------------------------------
LIBRARY IEEE;
USE IEEE.STD_LOGIC_1164.ALL;
USE IEEE.NUMERIC_STD.ALL;
LIBRARY techmap;
USE techmap.gencomp.ALL;
LIBRARY lpp;
USE lpp.lpp_sim_pkg.ALL;
USE lpp.lpp_lfr_sim_pkg.ALL;
USE lpp.lpp_lfr_apbreg_pkg.ALL;
USE lpp.lpp_lfr_management_apbreg_pkg.ALL;
USE lpp.iir_filter.ALL;
USE lpp.FILTERcfg.ALL;
USE lpp.lpp_memory.ALL;
USE lpp.lpp_waveform_pkg.ALL;
USE lpp.lpp_dma_pkg.ALL;
USE lpp.lpp_top_lfr_pkg.ALL;
USE lpp.lpp_lfr_pkg.ALL;
USE lpp.general_purpose.ALL;
--LIBRARY lpp;
USE lpp.lpp_ad_conv.ALL;
--USE lpp.lpp_lfr_management_apbreg_pkg.ALL;
--USE lpp.lpp_lfr_apbreg_pkg.ALL;
--USE work.debug.ALL;
LIBRARY gaisler;
USE gaisler.libdcom.ALL;
USE gaisler.sim.ALL;
USE gaisler.memctrl.ALL;
USE gaisler.leon3.ALL;
USE gaisler.uart.ALL;
USE gaisler.misc.ALL;
USE gaisler.spacewire.ALL;
ENTITY TB IS
END TB;
ARCHITECTURE beh OF TB IS
CONSTANT sramfile : STRING := "prom.srec";
-- CONSTANT sramfile : STRING;
CONSTANT USE_ESA_MEMCTRL : INTEGER := 0;
COMPONENT LFR_EQM
GENERIC (
Mem_use : INTEGER;
USE_BOOTLOADER : INTEGER;
USE_ADCDRIVER : INTEGER;
tech : INTEGER;
tech_leon : INTEGER;
DEBUG_FORCE_DATA_DMA : INTEGER;
USE_DEBUG_VECTOR : INTEGER );
PORT (
clk50MHz : IN STD_ULOGIC;
clk49_152MHz : IN STD_ULOGIC;
reset : IN STD_ULOGIC;
--TAG1 : IN STD_ULOGIC;
--TAG3 : OUT STD_ULOGIC;
--TAG2 : IN STD_ULOGIC;
--TAG4 : OUT STD_ULOGIC;
TAG : INOUT STD_LOGIC_VECTOR(9 DOWNTO 1);
address : OUT STD_LOGIC_VECTOR(18 DOWNTO 0);
data : INOUT STD_LOGIC_VECTOR(31 DOWNTO 0);
nSRAM_MBE : INOUT STD_LOGIC;
nSRAM_E1 : OUT STD_LOGIC;
nSRAM_E2 : OUT STD_LOGIC;
nSRAM_W : OUT STD_LOGIC;
nSRAM_G : OUT STD_LOGIC;
nSRAM_BUSY : IN STD_LOGIC;
spw1_en : OUT STD_LOGIC;
spw1_din : IN STD_LOGIC;
spw1_sin : IN STD_LOGIC;
spw1_dout : OUT STD_LOGIC;
spw1_sout : OUT STD_LOGIC;
spw2_en : OUT STD_LOGIC;
spw2_din : IN STD_LOGIC;
spw2_sin : IN STD_LOGIC;
spw2_dout : OUT STD_LOGIC;
spw2_sout : OUT STD_LOGIC;
bias_fail_sw : OUT STD_LOGIC;
ADC_OEB_bar_CH : OUT STD_LOGIC_VECTOR(7 DOWNTO 0);
ADC_smpclk : OUT STD_LOGIC;
ADC_data : IN STD_LOGIC_VECTOR(13 DOWNTO 0);
DAC_SDO : OUT STD_LOGIC;
DAC_SCK : OUT STD_LOGIC;
DAC_SYNC : OUT STD_LOGIC;
DAC_CAL_EN : OUT STD_LOGIC;
HK_smpclk : OUT STD_LOGIC;
ADC_OEB_bar_HK : OUT STD_LOGIC;
HK_SEL : OUT STD_LOGIC_VECTOR(1 DOWNTO 0));
END COMPONENT;
SIGNAL clk50MHz : STD_ULOGIC := '0';
SIGNAL clk49_152MHz : STD_ULOGIC := '0';
SIGNAL reset : STD_ULOGIC;
SIGNAL TAG : STD_LOGIC_VECTOR(9 DOWNTO 1);
--SIGNAL TAG3 : STD_ULOGIC;
--SIGNAL TAG2 : STD_ULOGIC := '1';
--SIGNAL TAG4 : STD_ULOGIC;
SIGNAL address : STD_LOGIC_VECTOR(18 DOWNTO 0);
SIGNAL data : STD_LOGIC_VECTOR(31 DOWNTO 0);
SIGNAL data_ram : STD_LOGIC_VECTOR(31 DOWNTO 0);
SIGNAL nSRAM_MBE : STD_LOGIC;
SIGNAL nSRAM_E1 : STD_LOGIC;
SIGNAL nSRAM_E2 : STD_LOGIC;
SIGNAL nSRAM_W : STD_LOGIC;
SIGNAL nSRAM_G : STD_LOGIC;
SIGNAL nSRAM_BUSY : STD_LOGIC;
SIGNAL spw1_en : STD_LOGIC;
SIGNAL spw1_din : STD_LOGIC := '1';
SIGNAL spw1_sin : STD_LOGIC := '1';
SIGNAL spw1_dout : STD_LOGIC;
SIGNAL spw1_sout : STD_LOGIC;
SIGNAL spw2_en : STD_LOGIC;
SIGNAL spw2_din : STD_LOGIC := '1';
SIGNAL spw2_sin : STD_LOGIC := '1';
SIGNAL spw2_dout : STD_LOGIC;
SIGNAL spw2_sout : STD_LOGIC;
SIGNAL bias_fail_sw : STD_LOGIC;
SIGNAL ADC_OEB_bar_CH : STD_LOGIC_VECTOR(7 DOWNTO 0);
SIGNAL ADC_OEB_bar_CH_s : STD_LOGIC_VECTOR(8 DOWNTO 0);
SIGNAL ADC_smpclk : STD_LOGIC;
SIGNAL ADC_data : STD_LOGIC_VECTOR(13 DOWNTO 0);
SIGNAL ADC_data_s : STD_LOGIC_VECTOR(13 DOWNTO 0);
SIGNAL DAC_SDO : STD_LOGIC;
SIGNAL DAC_SCK : STD_LOGIC;
SIGNAL DAC_SYNC : STD_LOGIC;
SIGNAL DAC_CAL_EN : STD_LOGIC;
SIGNAL HK_smpclk : STD_LOGIC;
SIGNAL ADC_OEB_bar_HK : STD_LOGIC;
SIGNAL HK_SEL : STD_LOGIC_VECTOR(1 DOWNTO 0);
-- SIGNAL TAG8 : STD_LOGIC;
CONSTANT SCRUB_RATE_PERIOD : INTEGER := 1800/20;
CONSTANT SCRUB_PERIOD : INTEGER := 200/20;
CONSTANT SCRUB_BUSY_TO_SCRUB : INTEGER := 700/20;
CONSTANT SCRUB_SCRUB_TO_BUSY : INTEGER := 60/20;
SIGNAL counter_scrub_period : INTEGER;
--CONSTANT AHBADDR_APB : STD_LOGIC_VECTOR(11 DOWNTO 0) := X"800";
--CONSTANT AHBADDR_LFR_MANAGEMENT : STD_LOGIC_VECTOR(23 DOWNTO 0) := AHBADDR_APB & X"006";
--CONSTANT AHBADDR_LFR : STD_LOGIC_VECTOR(23 DOWNTO 0) := AHBADDR_APB & X"00F";
CONSTANT ADDR_BASE_DSU : STD_LOGIC_VECTOR(31 DOWNTO 24) := X"90";
CONSTANT ADDR_BASE_LFR : STD_LOGIC_VECTOR(31 DOWNTO 8) := X"80000F";
CONSTANT ADDR_BASE_LFR_2 : STD_LOGIC_VECTOR(31 DOWNTO 8) := X"80000E";
CONSTANT ADDR_BASE_TIME_MANAGMENT : STD_LOGIC_VECTOR(31 DOWNTO 8) := X"800006";
CONSTANT ADDR_BASE_GPIO : STD_LOGIC_VECTOR(31 DOWNTO 8) := X"80000B";
CONSTANT ADDR_BASE_ESA_MEMCTRL : STD_LOGIC_VECTOR(31 DOWNTO 8) := X"800000";
SIGNAL message_simu : STRING(1 TO 15) := "---------------";
SIGNAL data_message : STRING(1 TO 15) := "---------------";
SIGNAL data_read : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0');
SIGNAL TXD1 : STD_LOGIC;
SIGNAL RXD1 : STD_LOGIC;
-----------------------------------------------------------------------------
CONSTANT ADDR_BUFFER_WFP_F0_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40100000";
CONSTANT ADDR_BUFFER_WFP_F0_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40110000";
CONSTANT ADDR_BUFFER_WFP_F1_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40120000";
CONSTANT ADDR_BUFFER_WFP_F1_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40130000";
CONSTANT ADDR_BUFFER_WFP_F2_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40140000";
CONSTANT ADDR_BUFFER_WFP_F2_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40150000";
CONSTANT ADDR_BUFFER_WFP_F3_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40160000";
CONSTANT ADDR_BUFFER_WFP_F3_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40170000";
CONSTANT ADDR_BUFFER_MS_F0_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40180000";
CONSTANT ADDR_BUFFER_MS_F0_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"40190000";
CONSTANT ADDR_BUFFER_MS_F1_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"401A0000";
CONSTANT ADDR_BUFFER_MS_F1_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"401B0000";
CONSTANT ADDR_BUFFER_MS_F2_0 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"401C0000";
CONSTANT ADDR_BUFFER_MS_F2_1 : STD_LOGIC_VECTOR(31 DOWNTO 0) := X"401D0000";
TYPE sample_vector_16b IS ARRAY (NATURAL RANGE <> , NATURAL RANGE <>) OF STD_LOGIC_VECTOR(15 DOWNTO 0);
SIGNAL sample : sample_vector_16b(2 DOWNTO 0, 5 DOWNTO 0);
TYPE counter_vector IS ARRAY (NATURAL RANGE <>) OF INTEGER;
SIGNAL sample_counter : counter_vector( 2 DOWNTO 0);
SIGNAL data_pre_f0 : STD_LOGIC_VECTOR(31 DOWNTO 0);
SIGNAL data_pre_f1 : STD_LOGIC_VECTOR(31 DOWNTO 0);
SIGNAL data_pre_f2 : STD_LOGIC_VECTOR(31 DOWNTO 0);
SIGNAL error_wfp : STD_LOGIC_VECTOR(2 DOWNTO 0);
SIGNAL addr_pre_f0 : STD_LOGIC_VECTOR(13 DOWNTO 0);
SIGNAL addr_pre_f1 : STD_LOGIC_VECTOR(13 DOWNTO 0);
SIGNAL addr_pre_f2 : STD_LOGIC_VECTOR(13 DOWNTO 0);
SIGNAL error_wfp_addr : STD_LOGIC_VECTOR(2 DOWNTO 0);
-----------------------------------------------------------------------------
CONSTANT srambanks : INTEGER := 2;
CONSTANT sramwidth : INTEGER := 32;
CONSTANT sramdepth : INTEGER := 19;
SIGNAL ramsn : STD_LOGIC_VECTOR(srambanks-1 DOWNTO 0);
-----------------------------------------------------------------------------
BEGIN -- beh
LFR_EQM_1 : LFR_EQM
GENERIC MAP (
Mem_use => use_RAM,
USE_BOOTLOADER => 0,
USE_ADCDRIVER => 1,
tech => apa3e,
tech_leon => apa3e,
DEBUG_FORCE_DATA_DMA => 0,
USE_DEBUG_VECTOR => 0)
PORT MAP (
clk50MHz => clk50MHz, --IN --ok
clk49_152MHz => clk49_152MHz, --in --ok
reset => reset, --IN --ok
TAG => TAG,
--TAG1 => TAG1, --in
--TAG3 => TAG3, --out
--TAG2 => TAG2, --IN --ok
--TAG4 => TAG4, --out --ok
address => address, --out
data => data, --inout
nSRAM_MBE => nSRAM_MBE, --inout
nSRAM_E1 => nSRAM_E1, --out
nSRAM_E2 => nSRAM_E2, --out
nSRAM_W => nSRAM_W, --out
nSRAM_G => nSRAM_G, --out
nSRAM_BUSY => nSRAM_BUSY, --in
spw1_en => spw1_en, --out --ok
spw1_din => spw1_din, --in --ok
spw1_sin => spw1_sin, --in --ok
spw1_dout => spw1_dout, --out --ok
spw1_sout => spw1_sout, --out --ok
spw2_en => spw2_en, --out --ok
spw2_din => spw2_din, --in --ok
spw2_sin => spw2_sin, --in --ok
spw2_dout => spw2_dout, --out --ok
spw2_sout => spw2_sout, --out --ok
bias_fail_sw => bias_fail_sw, --OUT --ok
ADC_OEB_bar_CH => ADC_OEB_bar_CH, --out --ok
ADC_smpclk => ADC_smpclk, --out --ok
ADC_data => ADC_data, --IN --ok
DAC_SDO => DAC_SDO, --out --ok
DAC_SCK => DAC_SCK, --out --ok
DAC_SYNC => DAC_SYNC, --out --ok
DAC_CAL_EN => DAC_CAL_EN, --out --ok
HK_smpclk => HK_smpclk, --out --ok
ADC_OEB_bar_HK => ADC_OEB_bar_HK, --out --ok
HK_SEL => HK_SEL); --out --ok
-----------------------------------------------------------------------------
clk49_152MHz <= NOT clk49_152MHz AFTER 10173 ps; -- 49.152/2 MHz
clk50MHz <= NOT clk50MHz AFTER 10 ns; -- 50 MHz
-----------------------------------------------------------------------------
MODULE_RHF1401 : FOR I IN 0 TO 8 GENERATE
TestModule_RHF1401_1 : TestModule_RHF1401
GENERIC MAP (
freq => 2400,--24*(I*5+1),
amplitude => 4000,--8000/(I*5+1),
impulsion => 0)
PORT MAP (
ADC_smpclk => ADC_smpclk,
ADC_OEB_bar => ADC_OEB_bar_CH_s(I),
ADC_data => ADC_data_s);
--ADC_data_s <= "00" & X"190";
END GENERATE MODULE_RHF1401;
ADC_OEB_bar_CH_s <= TRANSPORT (ADC_OEB_bar_HK & ADC_OEB_bar_CH) AFTER 10 ns;
ADC_data <= TRANSPORT ADC_data_s AFTER 55 ns;
-----------------------------------------------------------------------------
PROCESS (clk50MHz, reset)
BEGIN -- PROCESS
IF reset = '0' THEN -- asynchronous reset (active low)
nSRAM_BUSY <= '1';
counter_scrub_period <= 0;
ELSIF clk50MHz'EVENT AND clk50MHz = '1' THEN -- rising clock edge
IF SCRUB_RATE_PERIOD + SCRUB_PERIOD < counter_scrub_period THEN
counter_scrub_period <= 0;
ELSE
counter_scrub_period <= counter_scrub_period + 1;
END IF;
IF counter_scrub_period < (SCRUB_RATE_PERIOD + SCRUB_PERIOD) - (SCRUB_PERIOD + SCRUB_BUSY_TO_SCRUB + SCRUB_SCRUB_TO_BUSY) THEN
nSRAM_BUSY <= '1';
ELSE
nSRAM_BUSY <= '0';
END IF;
END IF;
END PROCESS;
-----------------------------------------------------------------------------
-- TB
-----------------------------------------------------------------------------
TAG(1) <= TXD1;
TAG(2) <= '1';
RXD1 <= TAG(3);
PROCESS
CONSTANT txp : TIME := 320 ns;
VARIABLE data_read_v : STD_LOGIC_VECTOR(31 DOWNTO 0);
BEGIN -- PROCESS
TXD1 <= '1';
reset <= '0';
WAIT FOR 500 ns;
reset <= '1';
WAIT FOR 100 us;
message_simu <= "0 - UART init ";
UART_INIT(TXD1, txp);
---------------------------------------------------------------------------
-- LAUNCH leon 3 software
---------------------------------------------------------------------------
message_simu <= "2- GO Leon3....";
-- bool dsu3plugin::configureTarget() ---------------------------------------------------------------------------------------------------------------------------
--Force a debug break
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"0" & "00", X"0000002f"); --WriteRegs(uIntlist()<<,(unsigned int)DSUBASEADDRESS);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"2" & "00", X"0000ffff"); --WriteRegs(uIntlist()<<0x0000ffff,(unsigned int)DSUBASEADDRESS+0x20);
--Clear time tag counter
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"0" & "10", X"00000000"); --WriteRegs(uIntlist()<<0,(unsigned int)DSUBASEADDRESS+0x8);
--Clear ASR registers
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"4" & "00", X"00000000"); --WriteRegs(uIntlist()<<0<<0<<0,(unsigned int)DSUBASEADDRESS+0x400040);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"4" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"4" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"2" & "01", X"00000002"); --WriteRegs(uIntlist()<<0x2,(unsigned int)DSUBASEADDRESS+0x400024);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "00", X"00000000"); --WriteRegs(uIntlist()<<0<<0<<0<<0<<0<<0<<0<<0,(unsigned int)DSUBASEADDRESS+0x400060);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"7" & "00", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"7" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"7" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"7" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"4" & "10", X"00000000"); --WriteRegs(uIntlist()<<0,(unsigned int)DSUBASEADDRESS+0x48);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"4" & "11", X"00000000"); --WriteRegs(uIntlist()<<0,(unsigned int)DSUBASEADDRESS+0x000004C);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"4" & "00", X"00000000"); --WriteRegs(uIntlist()<<0,(unsigned int)DSUBASEADDRESS+0x400040);
IF USE_ESA_MEMCTRL = 1 THEN
UART_WRITE(TXD1, txp, ADDR_BASE_ESA_MEMCTRL & "000000", X"000002FF"); --WriteRegs(uIntlist()<<0x2FF<<0xE60<<0,(unsigned int)MCTRLBASEADDRESS);
UART_WRITE(TXD1, txp, ADDR_BASE_ESA_MEMCTRL & "000001", X"00000E60");
UART_WRITE(TXD1, txp, ADDR_BASE_ESA_MEMCTRL & "000010", X"00000000");
END IF;
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "00", X"00000000"); --WriteRegs(uIntlist()<<0<<0<<0<<0,(unsigned int)DSUBASEADDRESS+0x400060);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"6" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"2" & "01", X"0000ffff"); --WriteRegs(uIntlist()<<0x0000FFFF,(unsigned int)DSUBASEADDRESS+0x24);
--memSet(DSUBASEADDRESS+0x300000,0,1567);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"0" & "00", X"00000000"); --WriteRegs(uIntlist()<<0<<0xF30000E0<<0x00000002<<0x40000000<<0x40000000<<0x40000004<<0x1000000,(unsigned int)DSUBASEADDRESS+0x400000);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"0" & "01", X"F30000E0");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"0" & "10", X"00000002");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"0" & "11", X"40000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"1" & "00", X"40000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"1" & "01", X"40000004");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"1" & "10", X"10000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"2" & "00", X"00000000"); --WriteRegs(uIntlist()<<0<<0<<0<<0<<0<<0<<0x403ffff0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0<<0,(unsigned int)DSUBASEADDRESS+0x300020);
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"2" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"2" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"2" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"3" & "00", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"3" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"3" & "10", X"403ffff0");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"3" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"4" & "00", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"4" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"4" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"4" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"5" & "00", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"5" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"5" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"5" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"6" & "00", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"6" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"6" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"6" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"7" & "00", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"7" & "01", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"7" & "10", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"3000" & X"7" & "11", X"00000000");
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"0" & "00", X"000002EF"); --WriteRegs(uIntlist()<<0x000002EF,(unsigned int)DSUBASEADDRESS);
--//Disable interrupts
--unsigned int APBIRQCTRLRBASEADD = (unsigned int)SocExplorerEngine::self()->getEnumDeviceBaseAddress(this,1,0x0d,0);
--if(APBIRQCTRLRBASEADD == (unsigned int)-1)
-- return false;
--WriteRegs(uIntlist()<<0x00000000,APBIRQCTRLRBASEADD+0x040);
--WriteRegs(uIntlist()<<0xFFFE0000,APBIRQCTRLRBASEADD+0x080);
--WriteRegs(uIntlist()<<0<<0,APBIRQCTRLRBASEADD);
-- //Set up timer
--unsigned int APBTIMERBASEADD = (unsigned int)SocExplorerEngine::self()->getEnumDeviceBaseAddress(this,1,0x11,0);
--if(APBTIMERBASEADD == (unsigned int)-1)
-- return false;
--WriteRegs(uIntlist()<<0xffffffff,APBTIMERBASEADD+0x014);
--WriteRegs(uIntlist()<<0x00000018,APBTIMERBASEADD+0x04);
--WriteRegs(uIntlist()<<0x00000007,APBTIMERBASEADD+0x018);
---------------------------------------------------------------------------
--bool dsu3plugin::setCacheEnable(bool enabled)
--unsigned int DSUBASEADDRESS = SocExplorerEngine::self()->getEnumDeviceBaseAddress(this,0x01 , 0x004,0);
--if(DSUBASEADDRESS == (unsigned int)-1) DSUBASEADDRESS = 0x90000000;
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"4000" & X"2" & "01", X"00000002"); --WriteRegs(uIntlist()<<2,DSUBASEADDRESS+0x400024);
UART_READ(TXD1, RXD1, txp, ADDR_BASE_DSU & X"7000" & X"0" & "00", data_read_v);--unsigned int reg = ReadReg(DSUBASEADDRESS+0x700000);
data_read <= data_read_v;
--if(enabled){
UART_WRITE(TXD1, txp, ADDR_BASE_DSU & X"7000" & X"0" & "00" , data_read_v OR X"0001000F"); --WriteRegs(uIntlist()<<(0x0001000F|reg),DSUBASEADDRESS+0x700000);
UART_WRITE(TXD1, txp, ADDR_BASE_DSU & X"7000" & X"0" & "00" , data_read_v OR X"0061000F"); --WriteRegs(uIntlist()<<(0x0061000F|reg),DSUBASEADDRESS+0x700000);
--}else{
--WriteRegs(uIntlist()<<((!0x0001000F)&reg),DSUBASEADDRESS+0x700000);
--WriteRegs(uIntlist()<<(0x00600000|reg),DSUBASEADDRESS+0x700000);
--}
-- void dsu3plugin::run() ---------------------------------------------------------------------------------------------------------------------------------------
UART_WRITE(TXD1 , txp, ADDR_BASE_DSU & X"0000" & X"2" & "00", X"00000000"); --WriteRegs(uIntlist()<<0,DSUBASEADDRESS+0x020);
---------------------------------------------------------------------------
--message_simu <= "1 - UART test ";
--UART_WRITE(TXD1, txp, ADDR_BASE_GPIO & "000010", X"0000FFFF");
--UART_WRITE(TXD1, txp, ADDR_BASE_GPIO & "000001", X"00000A0A");
--UART_WRITE(TXD1, txp, ADDR_BASE_GPIO & "000001", X"00000B0B");
--UART_READ(TXD1, RXD1, txp, ADDR_BASE_GPIO & "000001", data_read_v);
--data_read <= data_read_v;
--data_message <= "GPIO_data_write";
-- UNSET the LFR reset
message_simu <= "2 - LFR UNRESET";
UNRESET_LFR(TXD1, txp, ADDR_BASE_TIME_MANAGMENT);
--
message_simu <= "3 - LFR CONFIG ";
LAUNCH_SPECTRAL_MATRIX(TXD1, RXD1, txp, ADDR_BASE_LFR,
ADDR_BUFFER_MS_F0_0,
ADDR_BUFFER_MS_F0_1,
ADDR_BUFFER_MS_F1_0,
ADDR_BUFFER_MS_F1_1,
ADDR_BUFFER_MS_F2_0,
ADDR_BUFFER_MS_F2_1);
LAUNCH_WAVEFORM_PICKER(TXD1, RXD1, txp,
LFR_MODE_SBM1,
X"7FFFFFFF", -- START DATE
"00000", --DATA_SHAPING ( 4 DOWNTO 0)
X"00012BFF", --DELTA_SNAPSHOT(31 DOWNTO 0)
X"0001280A", --DELTA_F0 (31 DOWNTO 0)
X"00000007", --DELTA_F0_2 (31 DOWNTO 0)
X"0001283F", --DELTA_F1 (31 DOWNTO 0)
X"000127FF", --DELTA_F2 (31 DOWNTO 0)
ADDR_BASE_LFR,
ADDR_BUFFER_WFP_F0_0,
ADDR_BUFFER_WFP_F0_1,
ADDR_BUFFER_WFP_F1_0,
ADDR_BUFFER_WFP_F1_1,
ADDR_BUFFER_WFP_F2_0,
ADDR_BUFFER_WFP_F2_1,
ADDR_BUFFER_WFP_F3_0,
ADDR_BUFFER_WFP_F3_1);
UART_WRITE(TXD1 , txp, ADDR_BASE_LFR & ADDR_LFR_WP_LENGTH, X"0000000F");
UART_WRITE(TXD1 , txp, ADDR_BASE_LFR & ADDR_LFR_WP_DATA_IN_BUFFER, X"00000050");
---------------------------------------------------------------------------
-- CONFIG LFR 2
---------------------------------------------------------------------------
--message_simu <= "3 - LFR2 CONFIG";
--LAUNCH_SPECTRAL_MATRIX(TXD1,RXD1,txp,ADDR_BASE_LFR_2,
-- X"40000000",
-- X"40001000",
-- X"40002000",
-- X"40003000",
-- X"40004000",
-- X"40005000");
--LAUNCH_WAVEFORM_PICKER(TXD1,RXD1,txp,
-- LFR_MODE_SBM1,
-- X"7FFFFFFF", -- START DATE
-- "00000",--DATA_SHAPING ( 4 DOWNTO 0)
-- X"00012BFF",--DELTA_SNAPSHOT(31 DOWNTO 0)
-- X"0001280A",--DELTA_F0 (31 DOWNTO 0)
-- X"00000007",--DELTA_F0_2 (31 DOWNTO 0)
-- X"0001283F",--DELTA_F1 (31 DOWNTO 0)
-- X"000127FF",--DELTA_F2 (31 DOWNTO 0)
-- ADDR_BASE_LFR_2,
-- X"40006000",
-- X"40007000",
-- X"40008000",
-- X"40009000",
-- X"4000A000",
-- X"4000B000",
-- X"4000C000",
-- X"4000D000");
--UART_WRITE(TXD1 ,txp,ADDR_BASE_LFR_2 & ADDR_LFR_WP_LENGTH, X"0000000F");
--UART_WRITE(TXD1 ,txp,ADDR_BASE_LFR_2 & ADDR_LFR_WP_DATA_IN_BUFFER, X"00000050");
---------------------------------------------------------------------------
---------------------------------------------------------------------------
UART_WRITE (TXD1 , txp, ADDR_BASE_LFR & X"5" & "10", X"FFFFFFFF");
message_simu <= "4 - GO GO GO !!";
data_message <= "---------------";
UART_WRITE (TXD1 , txp, ADDR_BASE_LFR & ADDR_LFR_WP_START_DATE, X"00000000");
-- UART_WRITE (TXD1 , txp, ADDR_BASE_LFR_2 & ADDR_LFR_WP_START_DATE, X"00000000");
data_read_v := (OTHERS => '1');
READ_STATUS : LOOP
data_message <= "---------------";
WAIT FOR 2 ms;
data_message <= "READ_STATUS_SM_";
--UART_READ(TXD1, RXD1, txp, ADDR_BASE_LFR & ADDR_LFR_SM_STATUS, data_read_v);
--data_message <= "--------------r";
--data_read <= data_read_v;
UART_WRITE(TXD1, txp, ADDR_BASE_LFR & ADDR_LFR_SM_STATUS, data_read_v);
data_message <= "READ_STATUS_WF_";
--UART_READ(TXD1, RXD1, txp, ADDR_BASE_LFR & ADDR_LFR_WP_STATUS, data_read_v);
--data_message <= "--------------r";
--data_read <= data_read_v;
UART_WRITE(TXD1, txp, ADDR_BASE_LFR & ADDR_LFR_WP_STATUS, data_read_v);
END LOOP READ_STATUS;
WAIT;
END PROCESS;
-----------------------------------------------------------------------------
PROCESS (nSRAM_W, reset)
BEGIN -- PROCESS
IF reset = '0' THEN -- asynchronous reset (active low)
data_pre_f0 <= X"00020001";
data_pre_f1 <= X"00020001";
data_pre_f2 <= X"00020001";
addr_pre_f0 <= (OTHERS => '0');
addr_pre_f1 <= (OTHERS => '0');
addr_pre_f2 <= (OTHERS => '0');
error_wfp <= "000";
error_wfp_addr <= "000";
sample_counter <= (0,0,0);
ELSIF nSRAM_W'EVENT AND nSRAM_W = '0' THEN -- rising clock edge
error_wfp <= "000";
error_wfp_addr <= "000";
-------------------------------------------------------------------------
IF address(18 DOWNTO 14) = ADDR_BUFFER_WFP_F0_0(20 DOWNTO 16) OR
address(18 DOWNTO 14) = ADDR_BUFFER_WFP_F0_1(20 DOWNTO 16) THEN
addr_pre_f0 <= address(13 DOWNTO 0);
IF to_integer(UNSIGNED(address(13 DOWNTO 0))) /= (to_integer(UNSIGNED(addr_pre_f0))+1) THEN
IF to_integer(UNSIGNED(address(13 DOWNTO 0))) /= 0 THEN
error_wfp_addr(0) <= '1';
END IF;
END IF;
data_pre_f0 <= data;
CASE data_pre_f0 IS
WHEN X"00200010" => IF data /= X"00080004" THEN error_wfp(0) <= '1'; END IF;
WHEN X"00080004" => IF data /= X"00020001" THEN error_wfp(0) <= '1'; END IF;
WHEN X"00020001" => IF data /= X"00200010" THEN error_wfp(0) <= '1'; END IF;
WHEN OTHERS => error_wfp(0) <= '1';
END CASE;
END IF;
-------------------------------------------------------------------------
IF address(18 DOWNTO 14) = ADDR_BUFFER_WFP_F1_0(20 DOWNTO 16) OR
address(18 DOWNTO 14) = ADDR_BUFFER_WFP_F1_1(20 DOWNTO 16) THEN
addr_pre_f1 <= address(13 DOWNTO 0);
IF to_integer(UNSIGNED(address(13 DOWNTO 0))) /= (to_integer(UNSIGNED(addr_pre_f1))+1) THEN
IF to_integer(UNSIGNED(address(13 DOWNTO 0))) /= 0 THEN
error_wfp_addr(1) <= '1';
END IF;
END IF;
data_pre_f1 <= data;
CASE data_pre_f1 IS
WHEN X"00200010" => IF data /= X"00080004" THEN error_wfp(1) <= '1'; END IF;
WHEN X"00080004" => IF data /= X"00020001" THEN error_wfp(1) <= '1'; END IF;
WHEN X"00020001" => IF data /= X"00200010" THEN error_wfp(1) <= '1'; END IF;
WHEN OTHERS => error_wfp(1) <= '1';
END CASE;
sample(1,0 + sample_counter(1)*2) <= data(31 DOWNTO 16);
sample(1,1 + sample_counter(1)*2) <= data(15 DOWNTO 0);
sample_counter(1) <= (sample_counter(1) + 1) MOD 3;
END IF;
-------------------------------------------------------------------------
IF address(18 DOWNTO 14) = ADDR_BUFFER_WFP_F2_0(20 DOWNTO 16) OR
address(18 DOWNTO 14) = ADDR_BUFFER_WFP_F2_1(20 DOWNTO 16) THEN
addr_pre_f2 <= address(13 DOWNTO 0);
IF to_integer(UNSIGNED(address(13 DOWNTO 0))) /= (to_integer(UNSIGNED(addr_pre_f2))+1) THEN
IF to_integer(UNSIGNED(address(13 DOWNTO 0))) /= 0 THEN
error_wfp_addr(2) <= '1';
END IF;
END IF;
data_pre_f2 <= data;
CASE data_pre_f2 IS
WHEN X"00200010" => IF data /= X"00080004" THEN error_wfp(2) <= '1'; END IF;
WHEN X"00080004" => IF data /= X"00020001" THEN error_wfp(2) <= '1'; END IF;
WHEN X"00020001" => IF data /= X"00200010" THEN error_wfp(2) <= '1'; END IF;
WHEN OTHERS => error_wfp(2) <= '1';
END CASE;
sample(2,0 + sample_counter(2)*2) <= data(31 DOWNTO 16);
sample(2,1 + sample_counter(2)*2) <= data(15 DOWNTO 0);
sample_counter(2) <= (sample_counter(2) + 1) MOD 3;
END IF;
END IF;
END PROCESS;
-----------------------------------------------------------------------------
ramsn(1 DOWNTO 0) <= nSRAM_E2 & nSRAM_E1;
data_ram <= TRANSPORT data AFTER 45 ns WHEN nSRAM_W = '0' ELSE (OTHERS => 'Z');
data <= TRANSPORT data_ram AFTER 45 ns WHEN nSRAM_W = '1' ELSE (OTHERS => 'Z');
sbanks : FOR k IN 0 TO srambanks-1 GENERATE
sram0 : FOR i IN 0 TO (sramwidth/8)-1 GENERATE
sr0 : sram
GENERIC MAP (
index => i,
abits => sramdepth,
fname => sramfile)
PORT MAP (
address,
data_ram(31-i*8 DOWNTO 24-i*8),
ramsn(k),
nSRAM_W,
nSRAM_G
);
END GENERATE;
END GENERATE;
END beh;