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      ------------------------------------------------------------------------------

      --  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.numeric_std.ALL;

      USE IEEE.std_logic_1164.ALL;

      LIBRARY grlib;

      USE grlib.amba.ALL;

      USE grlib.stdlib.ALL;

      LIBRARY techmap;

      USE techmap.gencomp.ALL;

      LIBRARY gaisler;

      USE gaisler.memctrl.ALL;

      USE gaisler.leon3.ALL;

      USE gaisler.uart.ALL;

      USE gaisler.misc.ALL;

      USE gaisler.spacewire.ALL;

      LIBRARY esa;

      USE esa.memoryctrl.ALL;

      LIBRARY lpp;

      USE lpp.lpp_memory.ALL;

      USE lpp.lpp_ad_conv.ALL;

      USE lpp.lpp_lfr_pkg.ALL;  -- contains lpp_lfr, not in the 206 rev of the VHD_Lib

      USE lpp.lpp_top_lfr_pkg.ALL;            -- contains top_wf_picker

      USE lpp.iir_filter.ALL;

      USE lpp.general_purpose.ALL;

      USE lpp.lpp_lfr_management.ALL;

      USE lpp.lpp_leon3_soc_pkg.ALL;

      ENTITY LFR_em IS

        PORT (

          clk100MHz    : IN STD_ULOGIC;

          clk49_152MHz : IN STD_ULOGIC;

          reset        : IN STD_ULOGIC;

          -- TAG --------------------------------------------------------------------

          TAG1           : IN    STD_ULOGIC;  -- DSU rx data   

          TAG3           : OUT   STD_ULOGIC;  -- DSU tx data  

          -- UART APB ---------------------------------------------------------------

          TAG2           : IN    STD_ULOGIC;  -- UART1 rx data 

          TAG4           : OUT   STD_ULOGIC;  -- UART1 tx data   

          -- RAM --------------------------------------------------------------------

          address        : OUT   STD_LOGIC_VECTOR(19 DOWNTO 0);

          data           : INOUT STD_LOGIC_VECTOR(31 DOWNTO 0);

          nSRAM_BE0      : OUT   STD_LOGIC;

          nSRAM_BE1      : OUT   STD_LOGIC;

          nSRAM_BE2      : OUT   STD_LOGIC;

          nSRAM_BE3      : OUT   STD_LOGIC;

          nSRAM_WE       : OUT   STD_LOGIC;

          nSRAM_CE       : OUT   STD_LOGIC;

          nSRAM_OE       : OUT   STD_LOGIC;

          -- SPW --------------------------------------------------------------------

          spw1_din       : IN    STD_LOGIC;

          spw1_sin       : IN    STD_LOGIC;

          spw1_dout      : OUT   STD_LOGIC;

          spw1_sout      : OUT   STD_LOGIC;

          spw2_din       : IN    STD_LOGIC;

          spw2_sin       : IN    STD_LOGIC;

          spw2_dout      : OUT   STD_LOGIC;

          spw2_sout      : OUT   STD_LOGIC;

          -- ADC --------------------------------------------------------------------

          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 --------------------------------------------------------------------

          DAC_SDO    : OUT STD_LOGIC;

          DAC_SCK    : OUT STD_LOGIC;

          DAC_SYNC   : OUT STD_LOGIC;

          DAC_CAL_EN : OUT STD_LOGIC;

          -- HK ---------------------------------------------------------------------

          HK_smpclk      : OUT   STD_LOGIC;

          ADC_OEB_bar_HK : OUT   STD_LOGIC;

          HK_SEL         : OUT   STD_LOGIC_VECTOR(1 DOWNTO 0);

          ---------------------------------------------------------------------------

          TAG8           : IN   STD_LOGIC;

          led            : OUT   STD_LOGIC_VECTOR(2 DOWNTO 0)

          );

      END LFR_em;

      ARCHITECTURE beh OF LFR_em IS

      --==========================================================================

      --  USE_IAP_MEMCTRL allow to use the srctrle-0ws on MINILFR board

      --  when enabled, chip enable polarity should be reversed and bank size also

      --  MINILFR      -> 1 bank of 4MBytes   -> SRBANKSZ=9

      --  LFR EQM & FM -> 2 banks of 2MBytes  -> SRBANKSZ=8

      --==========================================================================

        CONSTANT USE_IAP_MEMCTRL : integer := 1;

      --==========================================================================

        SIGNAL clk_50_s    : STD_LOGIC := '0';

        SIGNAL clk_25      : STD_LOGIC := '0';

        SIGNAL clk_24      : STD_LOGIC := '0';

        -----------------------------------------------------------------------------

        SIGNAL coarse_time : STD_LOGIC_VECTOR(31 DOWNTO 0);

        SIGNAL fine_time   : STD_LOGIC_VECTOR(15 DOWNTO 0);

        -- CONSTANTS

        CONSTANT CFG_PADTECH   : INTEGER := inferred;

        CONSTANT NB_APB_SLAVE  : INTEGER := 11;  -- 3 = grspw + waveform picker + time manager, 11 allows pindex = f

        CONSTANT NB_AHB_SLAVE  : INTEGER := 1;

        CONSTANT NB_AHB_MASTER : INTEGER := 2;   -- 2 = grspw + waveform picker

        SIGNAL apbi_ext   : apb_slv_in_type;

        SIGNAL apbo_ext   : soc_apb_slv_out_vector(NB_APB_SLAVE-1+5 DOWNTO 5)  := (OTHERS => apb_none);

        SIGNAL ahbi_s_ext : ahb_slv_in_type;

        SIGNAL ahbo_s_ext : soc_ahb_slv_out_vector(NB_AHB_SLAVE-1+3 DOWNTO 3)  := (OTHERS => ahbs_none);

        SIGNAL ahbi_m_ext : AHB_Mst_In_Type;

        SIGNAL ahbo_m_ext : soc_ahb_mst_out_vector(NB_AHB_MASTER-1+1 DOWNTO 1) := (OTHERS => ahbm_none);

      -- Spacewire signals

        SIGNAL dtmp        : STD_LOGIC_VECTOR(1 DOWNTO 0);

        SIGNAL stmp        : STD_LOGIC_VECTOR(1 DOWNTO 0);

        SIGNAL spw_rxclk   : STD_LOGIC_VECTOR(1 DOWNTO 0);

        SIGNAL spw_rxtxclk : STD_ULOGIC;

        SIGNAL spw_rxclkn  : STD_ULOGIC;

        SIGNAL spw_clk     : STD_LOGIC;

        SIGNAL swni        : grspw_in_type;

        SIGNAL swno        : grspw_out_type;

      --GPIO

        SIGNAL gpioi : gpio_in_type;

        SIGNAL gpioo : gpio_out_type;

      -- AD Converter ADS7886

        SIGNAL sample      : Samples14v(8 DOWNTO 0);

        SIGNAL sample_s    : Samples(8 DOWNTO 0);

        SIGNAL sample_val  : STD_LOGIC;

        SIGNAL  ADC_OEB_bar_CH_s : STD_LOGIC_VECTOR(8 DOWNTO 0);

        -----------------------------------------------------------------------------

        SIGNAL observation_reg : STD_LOGIC_VECTOR(31 DOWNTO 0);

        -----------------------------------------------------------------------------

        SIGNAL rstn_25 : STD_LOGIC;

        SIGNAL rstn_24 : STD_LOGIC;

        SIGNAL LFR_soft_rstn : STD_LOGIC;

        SIGNAL LFR_rstn      : STD_LOGIC;

        SIGNAL ADC_smpclk_s : STD_LOGIC;

        ----------------------------------------------------------------------------

        SIGNAL nSRAM_CE_s : STD_LOGIC_VECTOR(1 DOWNTO 0);

        SIGNAL nSRAM_READY : STD_LOGIC;

      BEGIN  -- beh

        -----------------------------------------------------------------------------

        -- CLK

        -----------------------------------------------------------------------------

        rst_domain25 : rstgen PORT MAP (reset, clk_25, '1', rstn_25, OPEN);

        rst_domain24 : rstgen PORT MAP (reset, clk_24, '1', rstn_24, OPEN);

        PROCESS(clk100MHz)

        BEGIN

          IF clk100MHz'EVENT AND clk100MHz = '1' THEN

            clk_50_s <= NOT clk_50_s;

          END IF;

        END PROCESS;

        PROCESS(clk_50_s)

        BEGIN

          IF clk_50_s'EVENT AND clk_50_s = '1' THEN

            clk_25 <= NOT clk_25;

          END IF;

        END PROCESS;

        PROCESS(clk49_152MHz)

        BEGIN

          IF clk49_152MHz'EVENT AND clk49_152MHz = '1' THEN

            clk_24 <= NOT clk_24;

          END IF;

        END PROCESS;

        -----------------------------------------------------------------------------

        PROCESS (clk_25, rstn_25)

        BEGIN  -- PROCESS

          IF rstn_25 = '0' THEN                  -- asynchronous reset (active low)

            led(0) <= '0';

            led(1) <= '0';

            led(2) <= '0';

          ELSIF clk_25'EVENT AND clk_25 = '1' THEN  -- rising clock edge

            led(0) <= '0';

            led(1) <= '1';

            led(2) <= '1';

          END IF;

        END PROCESS;

        --

        leon3_soc_1 : leon3_soc

          GENERIC MAP (

            fabtech         => apa3e,

            memtech         => apa3e,

            padtech         => inferred,

            clktech         => inferred,

            disas           => 0,

            dbguart         => 0,

            pclow           => 2,

            clk_freq        => 25000,

            IS_RADHARD      => 0,

            NB_CPU          => 1,

            ENABLE_FPU      => 1,

            FPU_NETLIST     => 0,

            ENABLE_DSU      => 1,

            ENABLE_AHB_UART => 1,

            ENABLE_APB_UART => 1,

            ENABLE_IRQMP    => 1,

            ENABLE_GPT      => 1,

            NB_AHB_MASTER   => NB_AHB_MASTER,

            NB_AHB_SLAVE    => NB_AHB_SLAVE,

            NB_APB_SLAVE    => NB_APB_SLAVE,

            ADDRESS_SIZE    => 20,

            USES_IAP_MEMCTRLR => USE_IAP_MEMCTRL,

            BYPASS_EDAC_MEMCTRLR => '0',

            SRBANKSZ          => 8)

          PORT MAP (

            clk    => clk_25,

            reset  => rstn_25,

            errorn => OPEN,

            ahbrxd => TAG1,

            ahbtxd => TAG3,

            urxd1  => TAG2,

            utxd1  => TAG4,

            address   => address,

            data      => data,

            nSRAM_BE0 => nSRAM_BE0,

            nSRAM_BE1 => nSRAM_BE1,

            nSRAM_BE2 => nSRAM_BE2,

            nSRAM_BE3 => nSRAM_BE3,

            nSRAM_WE  => nSRAM_WE,

            nSRAM_CE  => nSRAM_CE_s,

            nSRAM_OE  => nSRAM_OE,

            nSRAM_READY => nSRAM_READY,

            SRAM_MBE    => OPEN,

            apbi_ext   => apbi_ext,

            apbo_ext   => apbo_ext,

            ahbi_s_ext => ahbi_s_ext,

            ahbo_s_ext => ahbo_s_ext,

            ahbi_m_ext => ahbi_m_ext,

            ahbo_m_ext => ahbo_m_ext);

        PROCESS (clk_25, rstn_25)

        BEGIN  -- PROCESS

          IF rstn_25 = '0' THEN               -- asynchronous reset (active low)

            nSRAM_READY <= '1';

          ELSIF clk_25'event AND clk_25 = '1' THEN  -- rising clock edge

            nSRAM_READY <= '1';

            IF TAG8 = '1' THEN

              nSRAM_READY <= '0';

            END IF;

          END IF;

        END PROCESS;

        IAP:if USE_IAP_MEMCTRL = 1 GENERATE

          nSRAM_CE <= not nSRAM_CE_s(0);

        END GENERATE;

        NOIAP:if USE_IAP_MEMCTRL = 0 GENERATE

          nSRAM_CE <=  nSRAM_CE_s(0);

        END GENERATE;

      -------------------------------------------------------------------------------

      -- APB_LFR_TIME_MANAGEMENT ----------------------------------------------------

      -------------------------------------------------------------------------------

        apb_lfr_management_1 : apb_lfr_management

          GENERIC MAP (

            tech             => apa3e,

            pindex           => 6,

            paddr            => 6,

            pmask            => 16#fff#,

      --      FIRST_DIVISION   => 374,  -- ((49.152/2) /2^16) - 1  = 375 - 1 = 374

            NB_SECOND_DESYNC => 60)  -- 60 secondes of desynchronization before CoarseTime's MSB is Set

          PORT MAP (

            clk25MHz          => clk_25,

            resetn_25MHz      => rstn_25,      --      TODO

      --      clk24_576MHz      => clk_24,          -- 49.152MHz/2

      --      resetn_24_576MHz  => rstn_24,      --      TODO

            grspw_tick    => swno.tickout,

            apbi          => apbi_ext,

            apbo          => apbo_ext(6),

            HK_sample     => sample_s(8),

            HK_val        => sample_val,

            HK_sel        => HK_SEL, 

            DAC_SDO           => DAC_SDO,

            DAC_SCK            => DAC_SCK,

            DAC_SYNC          => DAC_SYNC,

            DAC_CAL_EN        => DAC_CAL_EN,     

            coarse_time   => coarse_time,

            fine_time     => fine_time,

            LFR_soft_rstn => LFR_soft_rstn

            );

      -----------------------------------------------------------------------

      ---  SpaceWire --------------------------------------------------------

      -----------------------------------------------------------------------

      --  SPW_EN <= '1';

        spw_clk     <= clk_50_s;

        spw_rxtxclk <= spw_clk;

        spw_rxclkn  <= NOT spw_rxtxclk;

        -- PADS for SPW1

        spw1_rxd_pad : inpad GENERIC MAP (tech => inferred)

          PORT MAP (spw1_din, dtmp(0));

        spw1_rxs_pad : inpad GENERIC MAP (tech => inferred)

          PORT MAP (spw1_sin, stmp(0));

        spw1_txd_pad : outpad GENERIC MAP (tech => inferred)

          PORT MAP (spw1_dout, swno.d(0));

        spw1_txs_pad : outpad GENERIC MAP (tech => inferred)

          PORT MAP (spw1_sout, swno.s(0));

        -- PADS FOR SPW2

        spw2_rxd_pad : inpad GENERIC MAP (tech => inferred)  -- bad naming of the MINI-LFR /!\

          PORT MAP (spw2_din, dtmp(1));

        spw2_rxs_pad : inpad GENERIC MAP (tech => inferred)  -- bad naming of the MINI-LFR /!\

          PORT MAP (spw2_sin, stmp(1));

        spw2_txd_pad : outpad GENERIC MAP (tech => inferred)

          PORT MAP (spw2_dout, swno.d(1));

        spw2_txs_pad : outpad GENERIC MAP (tech => inferred)

          PORT MAP (spw2_sout, swno.s(1));

        -- GRSPW PHY

        --spw1_input: if CFG_SPW_GRSPW = 1 generate

        spw_inputloop : FOR j IN 0 TO 1 GENERATE

          spw_phy0 : grspw_phy

            GENERIC MAP(

              tech         => apa3e,

              rxclkbuftype => 1,

              scantest     => 0)

            PORT MAP(

              rxrst    => swno.rxrst,

              di       => dtmp(j),

              si       => stmp(j),

              rxclko   => spw_rxclk(j),

              do       => swni.d(j),

              ndo      => swni.nd(j*5+4 DOWNTO j*5),

              dconnect => swni.dconnect(j*2+1 DOWNTO j*2));

        END GENERATE spw_inputloop;

        -- SPW core

        sw0 : grspwm GENERIC MAP(

          tech         => apa3e,

          hindex       => 1,

          pindex       => 5,

          paddr        => 5,

          pirq         => 11,

          sysfreq      => 25000,              -- CPU_FREQ

          rmap         => 1,

          rmapcrc      => 1,

          fifosize1    => 16,

          fifosize2    => 16,

          rxclkbuftype => 1,

          rxunaligned  => 0,

          rmapbufs     => 4,

          ft           => 0,

          netlist      => 0,

          ports        => 2,

          --dmachan => CFG_SPW_DMACHAN, -- not used byt the spw core 1

          memtech      => apa3e,

          destkey      => 2,

          spwcore      => 1

          --input_type => CFG_SPW_INPUT, -- not used byt the spw core 1

          --output_type => CFG_SPW_OUTPUT,  -- not used byt the spw core 1

          --rxtx_sameclk => CFG_SPW_RTSAME -- not used byt the spw core 1

          )

          PORT MAP(rstn_25, clk_25, spw_rxclk(0),

                   spw_rxclk(1), spw_rxtxclk, spw_rxtxclk,

                   ahbi_m_ext, ahbo_m_ext(1), apbi_ext, apbo_ext(5),

                   swni, swno);

        swni.tickin      <= '0';

        swni.rmapen      <= '1';

        swni.clkdiv10    <= "00000100";       -- 10 MHz / (4 + 1) = 10 MHz

        swni.tickinraw   <= '0';

        swni.timein      <= (OTHERS => '0');

        swni.dcrstval    <= (OTHERS => '0');

        swni.timerrstval <= (OTHERS => '0');

      -------------------------------------------------------------------------------

      -- LFR ------------------------------------------------------------------------

      -------------------------------------------------------------------------------

        LFR_rstn <= LFR_soft_rstn AND rstn_25;

        lpp_lfr_1 : lpp_lfr

          GENERIC MAP (

            Mem_use                => use_RAM,

            tech                   => inferred,

            nb_data_by_buffer_size => 32,

            --nb_word_by_buffer_size => 30,

            nb_snapshot_param_size => 32,

            delta_vector_size      => 32,

            delta_vector_size_f0_2 => 7,          -- log2(96)

            pindex                 => 15,

            paddr                  => 15,

            pmask                  => 16#fff#,

            pirq_ms                => 6,

            pirq_wfp               => 14,

            hindex                 => 2,

            top_lfr_version        => X"010153")  -- aa.bb.cc version

                                                  -- AA : BOARD NUMBER

                                                  --      0 => MINI_LFR

                                                  --      1 => EM

          PORT MAP (

            clk             => clk_25,

            rstn            => LFR_rstn,

            sample_B        => sample_s(2 DOWNTO 0),

            sample_E        => sample_s(7 DOWNTO 3),

            sample_val      => sample_val,

            apbi            => apbi_ext,

            apbo            => apbo_ext(15),

            ahbi            => ahbi_m_ext,

            ahbo            => ahbo_m_ext(2),

            coarse_time     => coarse_time,

            fine_time       => fine_time,

            data_shaping_BW => bias_fail_sw,

            debug_vector    => OPEN,

            debug_vector_ms => OPEN);     --,

        --observation_vector_0 => OPEN,

        --observation_vector_1 => OPEN,

        --observation_reg => observation_reg);

        all_sample : FOR I IN 7 DOWNTO 0 GENERATE

          sample_s(I) <= sample(I) & '0' & '0';

        END GENERATE all_sample;

        sample_s(8) <= sample(8)(13) & sample(8)(13) & sample(8);

        -----------------------------------------------------------------------------

        -- 

        -----------------------------------------------------------------------------

        top_ad_conv_RHF1401_withFilter_1 : top_ad_conv_RHF1401_withFilter

          GENERIC MAP (

            ChanelCount     => 9,

            ncycle_cnv_high => 12,

            ncycle_cnv      => 25,

            FILTER_ENABLED  => 16#FF#)

          PORT MAP (

            cnv_clk    => clk_24,

            cnv_rstn   => rstn_24,

            cnv        => ADC_smpclk_s,

            clk        => clk_25,

            rstn       => rstn_25,

            ADC_data   => ADC_data,

            ADC_nOE    => ADC_OEB_bar_CH_s,

            sample     => sample,

            sample_val => sample_val);    

        ADC_OEB_bar_CH <= ADC_OEB_bar_CH_s(7 DOWNTO 0);

        ADC_smpclk <= ADC_smpclk_s;

        HK_smpclk  <= ADC_smpclk_s;

      --  TAG8 <= ADC_smpclk_s;

        -----------------------------------------------------------------------------

        -- HK

        -----------------------------------------------------------------------------

        ADC_OEB_bar_HK <= ADC_OEB_bar_CH_s(8);

      END beh;

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				------------------------------------------------------------------------------
				-- 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.numeric_std.ALL;
				USE IEEE.std_logic_1164.ALL;
				LIBRARY grlib;
				USE grlib.amba.ALL;
				USE grlib.stdlib.ALL;
				LIBRARY techmap;
				USE techmap.gencomp.ALL;
				LIBRARY gaisler;
				USE gaisler.memctrl.ALL;
				USE gaisler.leon3.ALL;
				USE gaisler.uart.ALL;
				USE gaisler.misc.ALL;
				USE gaisler.spacewire.ALL;
				LIBRARY esa;
				USE esa.memoryctrl.ALL;
				LIBRARY lpp;
				USE lpp.lpp_memory.ALL;
				USE lpp.lpp_ad_conv.ALL;
				USE lpp.lpp_lfr_pkg.ALL; -- contains lpp_lfr, not in the 206 rev of the VHD_Lib
				USE lpp.lpp_top_lfr_pkg.ALL; -- contains top_wf_picker
				USE lpp.iir_filter.ALL;
				USE lpp.general_purpose.ALL;
				USE lpp.lpp_lfr_management.ALL;
				USE lpp.lpp_leon3_soc_pkg.ALL;

				ENTITY LFR_em IS

				PORT (
				clk100MHz : IN STD_ULOGIC;
				clk49_152MHz : IN STD_ULOGIC;
				reset : IN STD_ULOGIC;

				-- TAG --------------------------------------------------------------------
				TAG1 : IN STD_ULOGIC; -- DSU rx data
				TAG3 : OUT STD_ULOGIC; -- DSU tx data
				-- UART APB ---------------------------------------------------------------
				TAG2 : IN STD_ULOGIC; -- UART1 rx data
				TAG4 : OUT STD_ULOGIC; -- UART1 tx data
				-- RAM --------------------------------------------------------------------
				address : OUT STD_LOGIC_VECTOR(19 DOWNTO 0);
				data : INOUT STD_LOGIC_VECTOR(31 DOWNTO 0);
				nSRAM_BE0 : OUT STD_LOGIC;
				nSRAM_BE1 : OUT STD_LOGIC;
				nSRAM_BE2 : OUT STD_LOGIC;
				nSRAM_BE3 : OUT STD_LOGIC;
				nSRAM_WE : OUT STD_LOGIC;
				nSRAM_CE : OUT STD_LOGIC;
				nSRAM_OE : OUT STD_LOGIC;
				-- SPW --------------------------------------------------------------------
				spw1_din : IN STD_LOGIC;
				spw1_sin : IN STD_LOGIC;
				spw1_dout : OUT STD_LOGIC;
				spw1_sout : OUT STD_LOGIC;
				spw2_din : IN STD_LOGIC;
				spw2_sin : IN STD_LOGIC;
				spw2_dout : OUT STD_LOGIC;
				spw2_sout : OUT STD_LOGIC;
				-- ADC --------------------------------------------------------------------
				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 --------------------------------------------------------------------
				DAC_SDO : OUT STD_LOGIC;
				DAC_SCK : OUT STD_LOGIC;
				DAC_SYNC : OUT STD_LOGIC;
				DAC_CAL_EN : OUT STD_LOGIC;
				-- HK ---------------------------------------------------------------------
				HK_smpclk : OUT STD_LOGIC;
				ADC_OEB_bar_HK : OUT STD_LOGIC;
				HK_SEL : OUT STD_LOGIC_VECTOR(1 DOWNTO 0);
				---------------------------------------------------------------------------
				TAG8 : IN STD_LOGIC;
				led : OUT STD_LOGIC_VECTOR(2 DOWNTO 0)
				);

				END LFR_em;


				ARCHITECTURE beh OF LFR_em IS

				--==========================================================================
				-- USE_IAP_MEMCTRL allow to use the srctrle-0ws on MINILFR board
				-- when enabled, chip enable polarity should be reversed and bank size also
				-- MINILFR -> 1 bank of 4MBytes -> SRBANKSZ=9
				-- LFR EQM & FM -> 2 banks of 2MBytes -> SRBANKSZ=8
				--==========================================================================
				CONSTANT USE_IAP_MEMCTRL : integer := 1;
				--==========================================================================

				SIGNAL clk_50_s : STD_LOGIC := '0';
				SIGNAL clk_25 : STD_LOGIC := '0';
				SIGNAL clk_24 : STD_LOGIC := '0';
				-----------------------------------------------------------------------------
				SIGNAL coarse_time : STD_LOGIC_VECTOR(31 DOWNTO 0);
				SIGNAL fine_time : STD_LOGIC_VECTOR(15 DOWNTO 0);

				-- CONSTANTS
				CONSTANT CFG_PADTECH : INTEGER := inferred;
				CONSTANT NB_APB_SLAVE : INTEGER := 11; -- 3 = grspw + waveform picker + time manager, 11 allows pindex = f
				CONSTANT NB_AHB_SLAVE : INTEGER := 1;
				CONSTANT NB_AHB_MASTER : INTEGER := 2; -- 2 = grspw + waveform picker

				SIGNAL apbi_ext : apb_slv_in_type;
				SIGNAL apbo_ext : soc_apb_slv_out_vector(NB_APB_SLAVE-1+5 DOWNTO 5) := (OTHERS => apb_none);
				SIGNAL ahbi_s_ext : ahb_slv_in_type;
				SIGNAL ahbo_s_ext : soc_ahb_slv_out_vector(NB_AHB_SLAVE-1+3 DOWNTO 3) := (OTHERS => ahbs_none);
				SIGNAL ahbi_m_ext : AHB_Mst_In_Type;
				SIGNAL ahbo_m_ext : soc_ahb_mst_out_vector(NB_AHB_MASTER-1+1 DOWNTO 1) := (OTHERS => ahbm_none);

				-- Spacewire signals
				SIGNAL dtmp : STD_LOGIC_VECTOR(1 DOWNTO 0);
				SIGNAL stmp : STD_LOGIC_VECTOR(1 DOWNTO 0);
				SIGNAL spw_rxclk : STD_LOGIC_VECTOR(1 DOWNTO 0);
				SIGNAL spw_rxtxclk : STD_ULOGIC;
				SIGNAL spw_rxclkn : STD_ULOGIC;
				SIGNAL spw_clk : STD_LOGIC;
				SIGNAL swni : grspw_in_type;
				SIGNAL swno : grspw_out_type;

				--GPIO
				SIGNAL gpioi : gpio_in_type;
				SIGNAL gpioo : gpio_out_type;

				-- AD Converter ADS7886
				SIGNAL sample : Samples14v(8 DOWNTO 0);
				SIGNAL sample_s : Samples(8 DOWNTO 0);
				SIGNAL sample_val : STD_LOGIC;
				SIGNAL ADC_OEB_bar_CH_s : STD_LOGIC_VECTOR(8 DOWNTO 0);

				-----------------------------------------------------------------------------
				SIGNAL observation_reg : STD_LOGIC_VECTOR(31 DOWNTO 0);

				-----------------------------------------------------------------------------
				SIGNAL rstn_25 : STD_LOGIC;
				SIGNAL rstn_24 : STD_LOGIC;

				SIGNAL LFR_soft_rstn : STD_LOGIC;
				SIGNAL LFR_rstn : STD_LOGIC;

				SIGNAL ADC_smpclk_s : STD_LOGIC;
				----------------------------------------------------------------------------
				SIGNAL nSRAM_CE_s : STD_LOGIC_VECTOR(1 DOWNTO 0);
				SIGNAL nSRAM_READY : STD_LOGIC;

				BEGIN -- beh

				-----------------------------------------------------------------------------
				-- CLK
				-----------------------------------------------------------------------------
				rst_domain25 : rstgen PORT MAP (reset, clk_25, '1', rstn_25, OPEN);
				rst_domain24 : rstgen PORT MAP (reset, clk_24, '1', rstn_24, OPEN);

				PROCESS(clk100MHz)
				BEGIN
				IF clk100MHz'EVENT AND clk100MHz = '1' THEN
				clk_50_s <= NOT clk_50_s;
				END IF;
				END PROCESS;

				PROCESS(clk_50_s)
				BEGIN
				IF clk_50_s'EVENT AND clk_50_s = '1' THEN
				clk_25 <= NOT clk_25;
				END IF;
				END PROCESS;

				PROCESS(clk49_152MHz)
				BEGIN
				IF clk49_152MHz'EVENT AND clk49_152MHz = '1' THEN
				clk_24 <= NOT clk_24;
				END IF;
				END PROCESS;

				-----------------------------------------------------------------------------

				PROCESS (clk_25, rstn_25)
				BEGIN -- PROCESS
				IF rstn_25 = '0' THEN -- asynchronous reset (active low)
				led(0) <= '0';
				led(1) <= '0';
				led(2) <= '0';
				ELSIF clk_25'EVENT AND clk_25 = '1' THEN -- rising clock edge
				led(0) <= '0';
				led(1) <= '1';
				led(2) <= '1';
				END IF;
				END PROCESS;

				--
				leon3_soc_1 : leon3_soc
				GENERIC MAP (
				fabtech => apa3e,
				memtech => apa3e,
				padtech => inferred,
				clktech => inferred,
				disas => 0,
				dbguart => 0,
				pclow => 2,
				clk_freq => 25000,
				IS_RADHARD => 0,
				NB_CPU => 1,
				ENABLE_FPU => 1,
				FPU_NETLIST => 0,
				ENABLE_DSU => 1,
				ENABLE_AHB_UART => 1,
				ENABLE_APB_UART => 1,
				ENABLE_IRQMP => 1,
				ENABLE_GPT => 1,
				NB_AHB_MASTER => NB_AHB_MASTER,
				NB_AHB_SLAVE => NB_AHB_SLAVE,
				NB_APB_SLAVE => NB_APB_SLAVE,
				ADDRESS_SIZE => 20,
				USES_IAP_MEMCTRLR => USE_IAP_MEMCTRL,
				BYPASS_EDAC_MEMCTRLR => '0',
				SRBANKSZ => 8)
				PORT MAP (
				clk => clk_25,
				reset => rstn_25,
				errorn => OPEN,

				ahbrxd => TAG1,
				ahbtxd => TAG3,
				urxd1 => TAG2,
				utxd1 => TAG4,

				address => address,
				data => data,
				nSRAM_BE0 => nSRAM_BE0,
				nSRAM_BE1 => nSRAM_BE1,
				nSRAM_BE2 => nSRAM_BE2,
				nSRAM_BE3 => nSRAM_BE3,
				nSRAM_WE => nSRAM_WE,
				nSRAM_CE => nSRAM_CE_s,
				nSRAM_OE => nSRAM_OE,
				nSRAM_READY => nSRAM_READY,
				SRAM_MBE => OPEN,

				apbi_ext => apbi_ext,
				apbo_ext => apbo_ext,
				ahbi_s_ext => ahbi_s_ext,
				ahbo_s_ext => ahbo_s_ext,
				ahbi_m_ext => ahbi_m_ext,
				ahbo_m_ext => ahbo_m_ext);

				PROCESS (clk_25, rstn_25)
				BEGIN -- PROCESS
				IF rstn_25 = '0' THEN -- asynchronous reset (active low)
				nSRAM_READY <= '1';
				ELSIF clk_25'event AND clk_25 = '1' THEN -- rising clock edge
				nSRAM_READY <= '1';
				IF TAG8 = '1' THEN
				nSRAM_READY <= '0';
				END IF;
				END IF;
				END PROCESS;

				IAP:if USE_IAP_MEMCTRL = 1 GENERATE
				nSRAM_CE <= not nSRAM_CE_s(0);
				END GENERATE;

				NOIAP:if USE_IAP_MEMCTRL = 0 GENERATE
				nSRAM_CE <= nSRAM_CE_s(0);
				END GENERATE;

				-------------------------------------------------------------------------------
				-- APB_LFR_TIME_MANAGEMENT ----------------------------------------------------
				-------------------------------------------------------------------------------
				apb_lfr_management_1 : apb_lfr_management
				GENERIC MAP (
				tech => apa3e,
				pindex => 6,
				paddr => 6,
				pmask => 16#fff#,
				-- FIRST_DIVISION => 374, -- ((49.152/2) /2^16) - 1 = 375 - 1 = 374
				NB_SECOND_DESYNC => 60) -- 60 secondes of desynchronization before CoarseTime's MSB is Set
				PORT MAP (
				clk25MHz => clk_25,
				resetn_25MHz => rstn_25, -- TODO
				-- clk24_576MHz => clk_24, -- 49.152MHz/2
				-- resetn_24_576MHz => rstn_24, -- TODO

				grspw_tick => swno.tickout,
				apbi => apbi_ext,
				apbo => apbo_ext(6),

				HK_sample => sample_s(8),
				HK_val => sample_val,
				HK_sel => HK_SEL,

				DAC_SDO => DAC_SDO,
				DAC_SCK => DAC_SCK,
				DAC_SYNC => DAC_SYNC,
				DAC_CAL_EN => DAC_CAL_EN,

				coarse_time => coarse_time,
				fine_time => fine_time,
				LFR_soft_rstn => LFR_soft_rstn
				);

				-----------------------------------------------------------------------
				--- SpaceWire --------------------------------------------------------
				-----------------------------------------------------------------------

				-- SPW_EN <= '1';

				spw_clk <= clk_50_s;
				spw_rxtxclk <= spw_clk;
				spw_rxclkn <= NOT spw_rxtxclk;

				-- PADS for SPW1
				spw1_rxd_pad : inpad GENERIC MAP (tech => inferred)
				PORT MAP (spw1_din, dtmp(0));
				spw1_rxs_pad : inpad GENERIC MAP (tech => inferred)
				PORT MAP (spw1_sin, stmp(0));
				spw1_txd_pad : outpad GENERIC MAP (tech => inferred)
				PORT MAP (spw1_dout, swno.d(0));
				spw1_txs_pad : outpad GENERIC MAP (tech => inferred)
				PORT MAP (spw1_sout, swno.s(0));
				-- PADS FOR SPW2
				spw2_rxd_pad : inpad GENERIC MAP (tech => inferred) -- bad naming of the MINI-LFR /!\
				PORT MAP (spw2_din, dtmp(1));
				spw2_rxs_pad : inpad GENERIC MAP (tech => inferred) -- bad naming of the MINI-LFR /!\
				PORT MAP (spw2_sin, stmp(1));
				spw2_txd_pad : outpad GENERIC MAP (tech => inferred)
				PORT MAP (spw2_dout, swno.d(1));
				spw2_txs_pad : outpad GENERIC MAP (tech => inferred)
				PORT MAP (spw2_sout, swno.s(1));

				-- GRSPW PHY
				--spw1_input: if CFG_SPW_GRSPW = 1 generate
				spw_inputloop : FOR j IN 0 TO 1 GENERATE
				spw_phy0 : grspw_phy
				GENERIC MAP(
				tech => apa3e,
				rxclkbuftype => 1,
				scantest => 0)
				PORT MAP(
				rxrst => swno.rxrst,
				di => dtmp(j),
				si => stmp(j),
				rxclko => spw_rxclk(j),
				do => swni.d(j),
				ndo => swni.nd(j5+4 DOWNTO j5),
				dconnect => swni.dconnect(j2+1 DOWNTO j2));
				END GENERATE spw_inputloop;

				-- SPW core
				sw0 : grspwm GENERIC MAP(
				tech => apa3e,
				hindex => 1,
				pindex => 5,
				paddr => 5,
				pirq => 11,
				sysfreq => 25000, -- CPU_FREQ
				rmap => 1,
				rmapcrc => 1,
				fifosize1 => 16,
				fifosize2 => 16,
				rxclkbuftype => 1,
				rxunaligned => 0,
				rmapbufs => 4,
				ft => 0,
				netlist => 0,
				ports => 2,
				--dmachan => CFG_SPW_DMACHAN, -- not used byt the spw core 1
				memtech => apa3e,
				destkey => 2,
				spwcore => 1
				--input_type => CFG_SPW_INPUT, -- not used byt the spw core 1
				--output_type => CFG_SPW_OUTPUT, -- not used byt the spw core 1
				--rxtx_sameclk => CFG_SPW_RTSAME -- not used byt the spw core 1
				)
				PORT MAP(rstn_25, clk_25, spw_rxclk(0),
				spw_rxclk(1), spw_rxtxclk, spw_rxtxclk,
				ahbi_m_ext, ahbo_m_ext(1), apbi_ext, apbo_ext(5),
				swni, swno);

				swni.tickin <= '0';
				swni.rmapen <= '1';
				swni.clkdiv10 <= "00000100"; -- 10 MHz / (4 + 1) = 10 MHz
				swni.tickinraw <= '0';
				swni.timein <= (OTHERS => '0');
				swni.dcrstval <= (OTHERS => '0');
				swni.timerrstval <= (OTHERS => '0');

				-------------------------------------------------------------------------------
				-- LFR ------------------------------------------------------------------------
				-------------------------------------------------------------------------------
				LFR_rstn <= LFR_soft_rstn AND rstn_25;

				lpp_lfr_1 : lpp_lfr
				GENERIC MAP (
				Mem_use => use_RAM,
				tech => inferred,
				nb_data_by_buffer_size => 32,
				--nb_word_by_buffer_size => 30,
				nb_snapshot_param_size => 32,
				delta_vector_size => 32,
				delta_vector_size_f0_2 => 7, -- log2(96)
				pindex => 15,
				paddr => 15,
				pmask => 16#fff#,
				pirq_ms => 6,
				pirq_wfp => 14,
				hindex => 2,
				top_lfr_version => X"010153") -- aa.bb.cc version
				-- AA : BOARD NUMBER
				-- 0 => MINI_LFR
				-- 1 => EM
				PORT MAP (
				clk => clk_25,
				rstn => LFR_rstn,
				sample_B => sample_s(2 DOWNTO 0),
				sample_E => sample_s(7 DOWNTO 3),
				sample_val => sample_val,
				apbi => apbi_ext,
				apbo => apbo_ext(15),
				ahbi => ahbi_m_ext,
				ahbo => ahbo_m_ext(2),
				coarse_time => coarse_time,
				fine_time => fine_time,
				data_shaping_BW => bias_fail_sw,
				debug_vector => OPEN,
				debug_vector_ms => OPEN); --,
				--observation_vector_0 => OPEN,
				--observation_vector_1 => OPEN,
				--observation_reg => observation_reg);


				all_sample : FOR I IN 7 DOWNTO 0 GENERATE
				sample_s(I) <= sample(I) & '0' & '0';
				END GENERATE all_sample;
				sample_s(8) <= sample(8)(13) & sample(8)(13) & sample(8);

				-----------------------------------------------------------------------------
				--
				-----------------------------------------------------------------------------
				top_ad_conv_RHF1401_withFilter_1 : top_ad_conv_RHF1401_withFilter
				GENERIC MAP (
				ChanelCount => 9,
				ncycle_cnv_high => 12,
				ncycle_cnv => 25,
				FILTER_ENABLED => 16#FF#)
				PORT MAP (
				cnv_clk => clk_24,
				cnv_rstn => rstn_24,
				cnv => ADC_smpclk_s,
				clk => clk_25,
				rstn => rstn_25,
				ADC_data => ADC_data,
				ADC_nOE => ADC_OEB_bar_CH_s,
				sample => sample,
				sample_val => sample_val);

				ADC_OEB_bar_CH <= ADC_OEB_bar_CH_s(7 DOWNTO 0);

				ADC_smpclk <= ADC_smpclk_s;
				HK_smpclk <= ADC_smpclk_s;

				-- TAG8 <= ADC_smpclk_s;

				-----------------------------------------------------------------------------
				-- HK
				-----------------------------------------------------------------------------
				ADC_OEB_bar_HK <= ADC_OEB_bar_CH_s(8);

				END beh;